Number 4 - Jordan Journal of Biological Sciences

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a. Books: 

Spence AP. 1990. Basic Human Anatomy. Tedwood City, CA, U.S.A. 

b. Chapter in a book: 

Blaxter M. 1976. Social class and health inequalities. In: Carter C and Peel J, editors. Equalities and Inequalities 

in Health. London: Academic Press, pp. 369-80. 

c. Periodicals: 

Shao R and Barker SC. 2007. Mitochondrial genomes of parasitic arthropods: implications for studies of 

population genetics and evolution. Parasit. 134:153-167. 

d. Conferences and Meetings: 

Embabi NS. 1990. Environmental aspects of distribution of mangrove in the United Arab Emirates. Proceedings of 

the First ASWAS Conference. University of the United Arab Emirates. Al-Ain, United Arab Emirates. 

e. Theses and Dissertations: 

El-Labadi SN. 2002. Intestinal digenetic trematodes of some marine fishes from the Gulf of Aqaba (MSc thesis). 

Zarqa (Jordan): Hashemite University. 

f. In press articles: 

Elkarmi AZ and Ismail NS. 2006. Population structure and shell morphometrics of the gastropod Theodoxus macri 

(Neritidae: Prosobranchia) from Azraq Oasis, Jordan. Pak. J. Biol. Sci. In press. 

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JJBS 

Jordan Journal of Biological Sciences 

PAGES PAPERS 

133-140 

141 - 146 

147-152 

153- 164 

165- 174 

175-184 

185-192 

193-202 

Volume 3, Number 4, December 2010 

ISSN 1995-6673 

Probiotics and Traditional Fermented Foods: The Eternal Connection (Mini-Review) 

Adel M. Mahasneh* and Muna M. Abbas 

Effect of Selenium and its Compounds on Oxygen Uptake in Freshwater Fish Gambusia affinis 

after Exposure to Lethal Doses 

Rajashri. R Naik and Huchhappgoudar.S.Patil 

Curative Effect of Garlic on Alcoholic Liver Diseased Patients 

Sankaran Mirunalini, Vadivel Arulmozhi and Thangam Arulmozhi 

Seasonal Variation of Copepoda in Chabahar Bay-Gulf of Oman 

Neda Fazeli, Hamid Rezai Marnani, Saeed Sanjani, Rasool Zare, Simin Dehghan and Najme Jahani 

Nandrolone Decanoate Administration to Male Rats Induces Oxidative Stress, Seminiferous 

Tubules Abnormalities, and Sperm DNA Fragmentation 

Lubna H. Tahtamouni, Noor H. Mustafa, Iman M. Hassan, Iman M. Ahmad, Salem R. Yasin, Maher Y. 

Abdalla 

Impact of Magnetic Application on the Parameters Related to Growth of Chickpea (Cicer 

arietinum L.) 

Nawroz Abdul-Razzak Tahir and Hero Fatih Hama Karim 

In vitro Study of Adult Bone Marrow Mesenchymal Stem Cells Derived from Albino Rats and 

their Cardiomyogenic Differentiation 

Intissar N. Waheed, Intidhar M. Mnati and Abdul Hussain H.Kadhim 

Mycobiota Associated with Sugarcane (Saccharum officinarum L.) Cultivars in Iraq. 

Samir K. Abdullah and Yehya A. Saleh

JJBS 



ISSN 1995-6673 

Pages 133 - 140 

Probiotics and Traditional Fermented Foods: The Eternal 

Connection (Mini-Review) 

Adel M. Mahasneh* and Muna M. Abbas 

Department of Biological Sciences, University of Jordan, Amman 11942, Jordan 

Abstract ﺺﺨﻠﻤﻟا 

Interactions of probiotic bacteria with the host and the 

impact of this interaction continue to fascinate microbial 

biotechnologists. Highlights of these influences of 

bacteria on human systems have been obtained from 

comparisons using germ free and conventional 

experimental animals. Where applied, outcomes and 

therapeutic uses are involved.There is a need to diversify 

the sources of isolation of probiotic bacteria to include 

fermented traditional foods of different societies. This 

approach invites more comprehensive research on 

different models to prove probiotics efficacy in a very 

well-defined patient groups pertaining to varied 

geographical locations, different ethnic communities and 

cultural values. Such invitation, no doubt, is motivated 

by the pressing need to develop and design alternatives 

to drugs causing bacterial resistance and risky side 

effects as well as complimentary treatments for other 

non-microbial diseases. 

Keywords: Probiotics, Traditional foods, Microbiota, Host-probiotic interactions. 

1. Introduction * 

"Let food be thy medicine and medicine be thy food" as 

Hippocrates said, is the principle of today (Suvarna and 

Boby, 2005). Probiotics are one of the functional foods 

that link diet and health. Probiotics "For Life" are living, 

health-promoting microbial food ingredients that have a 

beneficial effect on humans (Chuayana et al., 2003). 

The concept of probiotics have been first proposed by 

Nobel Prize winner Russian scientist Elie Metchnikoff, 

who suggested that the long life of Bulgarian peasants 

resulted from their utilization of fermented milk products 

(Mercenier et al., 2002; Chuayana et al., 2003; Tannock, 

2003). Metchnikoff thought that when the fermented milk 

products were consumed, the fermenting Lactobacillus 

positively influenced the microflora of the gut, decreasing 

toxic microbial activities there (Mercenier et al., 2002; 

Chuayana et al., 2003). 

* Corresponding author. amahasneh@ju.edu.jo. 

لاز ﺎﻣو نﺎآ ﻚﻟذ ﺮﺛأو ﻞﺋﺎﻌﻟا ﻊﻣ ﺔﻳﺮﻴﺘﻜﺒﻟا ﺔﻳﻮﻴﺤﻟا تﺎﻨﺴﺤﻤﻟا ﻞﻋﺎﻔﺗ نإ 

ةﺰﻴﻤﻤﻟا رﺎﺛﻵا نإو ﺔﻘﻴﻗﺪﻟا ءﺎﻴﺣﻸﻟ ﺔﻳﻮﻴﺤﻟا تﺎﻴﻨﻘﺘﻟا ءﺎﻤﻠﻋ بﺎﺠﻋإ ﺮﻴﺜﻳ 

تﺎﻧاﻮﻴﺣ ﻰﻠﻋ ﺔﻧرﺎﻘﻣ تﺎﺳارد 

لﻼﺧ ﻦﻣ ﺎﻬﻘﻴﺛﻮﺗ ﻢﺗ ﺪﻗ ﺎﻳﺮﻴﺘﻜﺒﻟا ﻩﺬﻬﻟ 

لﺰﻋ ردﺎﺼﻣ ﻊﻳﻮﻨﺗ ةروﺮﻀﻟ تﺎﻧرﺎﻘﻤﻟا ﻩﺬه ﺞﺋﺎﺘﻧ ترﺎﺷأو . ﺔﻳﺮﺒﺨﻣ 

تﺎﻌﻤﺘﺠﻤﻟ ﺔﻳﺪﻴﻠﻘﺗ ةﺮﻤﺨﻣ ﺔﻳﺬﻏأ ﻞﻤﺸﺘﻟ ﺔﻳﺮﻴﺘﻜﺒﻟا ﺔﻳﻮﻴﺤﻟا تﺎﻨﺴﺤﻤﻟا ﻩﺬه 

جذﺎﻤﻧ ﻰﻠﻋ ﺔﻠﻣﺎﺷ تﺎﺳارﺪﻟ ﺔﺑرﺎﻘﻤﻟا ﻩﺬه يدﺆﺗ نأ ﻞﻣﺆﻤﻟا ﻦﻣو . ﺔﻨﻳﺎﺒﺘﻣ 

ةدﺪﺤﻤﻟا ﻰﺿﺮﻤﻟا تﺎﻋﻮﻤﺠﻣ ﻰﻠﻋ تﺎﻨﺴﺤﻤﻟا ﻩﺬه ﺔﻴﻟﺎﻌﻓ تﺎﺒﺛﻹ ﺔﻔﻠﺘﺨﻣ 

زﺰﻌﺘﻴﺳ ﻪﺟﻮﺘﻟا اﺬه نﺄﺑ ﻚﺷ ﻻو . ﺔﻳرﺎﻀﺤﻟا ﺎﻬﻤﻴﻗ ﻊﻣو ًﺎﻴﻗﺮﻋو ًﺎﻴﻧﺎﻜﻣ 

ﺔﻣوﺎﻘﻤﻟا رﻮﻬﻈﻟ يدﺆﺗ تارﺎﻘﻌﻟ ﻞﺋاﺪﺑ ﻢﻴﻤﺼﺗو ﺮﻳﻮﻄﺘﻟ ﺔﺳﺎﻤﻟا ﺔﺟﺎﺤﻟﺎﺑ 

ﻩﺬه نﻮﻜﺗ نأ ﻦﻜﻤﻳ ﺎﻤآ ﺔﻴﺒﻧﺎﺠﻟا ضاﺮﻋﻸﻟ ﺔﻓﺎﺿإ ﺎﻳﺮﻴﺘﻜﺒﻟا ﻲﻓ 

. ﺔﻳﺮﻴﺘﻜﺑ ﺮﻴﻏ ضاﺮﻣأ ﺔﺠﻟﺎﻌﻣ ﻲﻓ ﺔﻠﻤﻜﻣ ﺔﻳﺮﻴﺘﻜﺒﻟا تﺎﻨﺴﺤﻤﻟا 

© 2010 Jordan Journal of Biological Sciences. All rights reserved 

As a result of more investigations in the probiotic field, 

its concept has been expanded to include bacteria from 

intestinal origin beside those bacteria isolated from 

fermented dairy products (Zeng et al., 2010). And we 

believe now that traditionally fermented foods are the 

untapped source for a wide variety of beneficial probiotic 

microorganisms. 

Lactic acid bacteria (LAB) are the most common type 

of microorganisms used as probiotics. Strains of the genera 

Lactobacillus, Bifidobacterium (Yateem et al., 2008) and 

Enterococcus (Ljungh and Wadström, 2006) are the most 

widely used and commonly studied probiotic bacteria. The 

yeast Saccharomyces boulardii has also been studied as 

probiotics (Ljungh and Wadström, 2006). 

All of these microorganisms have been considered as 

probiotics according to several criteria such as their total 

beneficial effect on the host, being non-pathogenic 

(Suvarna and Boby, 2005), and their ability to survive 

transit through the gastrointestinal (GI) tract (Saito, 2004; 

Crittenden et al., 2005; Liong and Shah, 2005). 

Probiotic bacteria actions include: adherence and 

colonization of the host gut (Sanders, 2003), suppression 

of growth and invasion by pathogenic bacteria (Reid and

134 

© 2010 Jordan Journal of Biological Sciences. All rights reserved - Volume 3, Number 4 

Burton, 2002), production of antimicrobial substances such 

as bacteriocins (Nowroozi et al., 2004), improvement of 

intestinal barrier function, and stimulation of host 

immunity (Tannock, 2003). 

Evidence from in vitro systems, animal models and 

humans suggests that the therapeutic use of probiotics has 

been considered very successful in the cases of lactose 

intolerance (Suvarna and Boby, 2005), inflammatory 

bowel disease (Daniel et al., 2006), colon cancer, 

Helicobacter pylori infection (Ouwehand et al., 2002), 

reduction of allergy, irritable bowel syndrome (Ljungh and 

Wadström, 2006), and certain diarrheal disease including 

antibiotic-associated diarrhea in adults, travelers’ diarrhea, 

and diarrheal diseases in young children (Reyed, 2007). 

Additionally, probiotics may improve intestinal mobility 

and relieve constipation, especially in seniors (Ouwehand 

et al., 2002; Crittenden et al., 2005). They also reduce the 

cholesterol levels in serum (Liong and Shah, 2005) and no 

doubt many other benefits are there to be found by deligent 

research efforts. 

Nowadays, probiotics are available in a variety of food 

products, dietary supplements (Parvez et al., 2006) and 

drugs (Sanders, 2003). In the United States, food products 

containing probiotics are almost exclusively dairy products 

- fluid milk and yoghurt- due to the historical association 

of lactic acid bacteria with fermented milk (Schillinger, 

1999). The most frequently used bacteria in these products 

include Lactobacillus and Bifidobacterium (Sanders, 

2003). 

Probiotics are commonly not long-term colonizers of 

the GI tract, although they can adhere temporarily to the 

epithelium (Bezkorovainy, 2001). Instead, they may divide 

very slowly in the intestine, while remaining metabolically 

active (Marco et al., 2006). Therefore, daily consumption 

of these bacteria is probably the best way to maintain their 

effectiveness (Champs et al., 2003). 

Isolation and characterization of novel strains of lactic 

acid bacteria from uninvestigated niche could have the 

dual advantage of revealing taxonomic characteristics and 

obtaining strains with interesting new functional traits that 

may be useful for probiotic application (Ortu et al., 2007). 

Among resources of probiotic bacteria are traditional 

fermented foods which vary according to societies and 

social habits of dieting (Reddy et al., 2007). 

2. Present status of the art 

Searching literature demonstrates the rapid growth of 

probiotics research with most published articles dates after 

2003 (Reid et al., 2006). The type of research is being 

extended to include discovering events taking place at the 

interface between mucosal lining and microbiota, links 

between probiotics use and effects at distant body sites. 

Applications in the fields of allergy, inflammation, 

cardiovascular diseases and cancers are top priority targets 

hoping to benefit mankind, the emphasis being upon 

therapy rather than health improvements only. Recent 

research results were successful in using certain probiotic 

bacteria as a delivery system of endostatin for cancer gene 

therapy (Hu et al., 2009). The biological activity of some 

probiotics is attributed to fermentation end products 

including among others organic acids, CO2, H 2O 2, 

diacetyl, and bacteriocins (Müller et al., 2009; Sanahan, 

2010). In the majority of cases, this biological activity is a 

combination of all these factors (Todorov and Dicks, 

2005). Probiotic induced-pathogen inhibitor may provide 

significant protection against pathogen spread in the 

gastrointestinal tract leading to enhanced human health 

(Collado et al., 2007a) through inhibition, displacement or 

competition with the pathogen (Gueimonde et al., 2006). 

Among the most studied bacteria as a probiotic included 

mainly isolates of the genera Lactobacillus and 

Bifidobacterium. Other bacteria of less potential as 

probiotics are isolates of the genus Bacillus such as 

Bacillus subtilis, Bacillus clausii, Bacillus pumilus and 

Bacillus coagulans (Hong et al., 2005; Patel et al., 2009). 

Reports claiming that probiotics use strengthened immune 

system, and helped in combating allergies, excessive 

alcohol intake and other diseases (Nichols, 2007; Sanders, 

2003) encouraged researchers to search for novel probiotic 

bacteria in traditionally fermented foods which is usually 

linked to good health of people who consume such foods 

regularly (Salminen et al., 1998). 

According to Reid, et al., 2006, the understanding of 

probiotic microorganisms has expanded in the last 20 years 

after incepting the term in research circles. The term now 

implicates exact speciation of the microorganism, safe and 

effective use of probiotic formulations, exhibition of health 

and or therapeutic benefits on experimental models and 

probably volunteers and finally safe manufacture and 

retail. Unfortunately, these requirements are not fully 

observed worldwide, resulting in marketing too many of 

the so-called probiotics that do not meeting the proper 

criteria of a true probiotic. Table 1 presents few examples 

of bacterial probiotic strains which belong mainly to 

species of the genera Lactobacillus and Bifidobacterium 

with exceptions pertaining to Escherichia coli and the 

yeast Saccharomyces cerevisiae. Such information provide 

us with substantial evidence that in the last decade 

probiotics are beginning to be a convincing complimentary 

rout to traditional drug-based therapies. This trend, will 

with no doubt pave the way for more sophisticated 

approaches to develop genetically modified 

microorganisms which harbour new traits in constructed 

probiotics for special therapeutic purposes; such thoughts 

were entertained by Lartigue et al., (2007) in his article 

about genome transplantation in bacteria.


Table 1. Probiotic microorganisms exhibiting positive clinical responses. 

Strain Probiotic clinical response 

Lactobacillus rhamnosus GG 

Bifidobacterium animalis BB12 

Bifidobacterium infantis 35624 

Lactobacillus paracasei LP-33 

Lactobacillus acidophilus La5 

Lactobacillus reuteri ATCC 55730 

Bifidobacterium longum BL1 

Saccharomyces cerevisiae Lyo 

Escherichia coli Nissle 1917 

Lactobacillus plantarum LP31 

Bifidobacterium longum 

Lactobacillus salivarius UCC118 

Lactobacillus buchneri P2 

Lactobacillus casei 

3. Bioprospecting for probiotics in traditional 

fermented foods 

The majority of infectious diseases caused by 

pathogenic bacteria and fungi represent a real challenge for 

current efforts to combat it through chemical and 

pharmacological research (Sanders et al., 2003). Rapid 

emergence of antibiotic resistance by many pathogens, 

along with increased toxicity of in field antibiotics prompts 

the continuous search and development of new antiinfective 

and antipathogenic materials (Sleator and Hill, 

2006). Antipathogenic and probiotic bacteria would be the 

corner-stone in the search for new and effective alternative 

to traditional prophylactic means in a variety of clinical 

cases and settings (Sleator and Hill, 2008). In the last 

decade, it was observed that the selection of probiotics is 

based mainly on their ability to adhere and colonize the 

gastrointestinal epithelia and to compete with pathogens 

for binding sites and nutrients (Collado et al., 2007a; 

Ouwehand and Salminen, 2003). The functional activity of 

probiotics have been associated with managing the 

diarrheal and gastrointestinal infections by probiotics 

strains of different species of Lactics isolated mainly from 

fermented dairy products and related sources available in 

the western hemisphere (D'Souza et al., 2002). In addition, 

there is ample evidence suggesting the use of probiotics to 

treat and prevent urinary tract infection (Velraeds et al., 

1998), rotavirus diarrhea (Szajewska et al., 2001), 

recurrence of certain cancers (Ohashi et al., 2002)), and 

reduction of allergies (Gill and Guarner, 2004)and 

recently, probiotic prophylaxis against asthma and eczema 

is being entertained (Sleator and Hill, 2008). 

Most research articles pertaining to the aforementioned 

observations were dependent upon bacterial probiotics 

originating mainly from fermented dairy products and to 

less extent from human body indigenous microflora such 

as vaginal isolates or infants faeces (Reid, 2005). While 

the probiotic market is growing rapidly, it becomes 

eminent to diversify our sources in the search for new and 

Adhesion displacement of several pathogens (Collade et al., 

2007b). 

Prevention and treatment of diarrhea (Weizman et al., 2005). 

Relieve abdominal pain (O'Mahony et al., 2005). 

Relieve of allergic rhinitis (Wang et al., 2004a). 

Helicobacter pylori inhibition (Wang et al., 2004b). 

Production of CD4- positive T- lymphocytes (Valeur et al., 2004). 

Serum cholesterol reduction (Xiao et al., 2003). 

Reduced diarrhea (Kurugol and Koturoglu, 2005). 

Colitis treatment (Tromm et al., 2004) 

Inhibition of food pathogens (Müller et al., 2009). 

Antitumor effect (Hu et al., 2009). 

Colon cancer reduction in mice (O'Mahony et al., 2001). 

Serum cholesterol reduction (Zeng et al., 2010). 

Reduction of bladder cancer (Ohashi et al., 2002). 

135 

novel probiotic microorganisms. This trend is encouraged 

by remarks stating that using different strains from 

different sources present interesting situations since 

differences between strains of the same species do exist 

(Reid, 2005; Weizman et al., 2005). 

4. Oriental sources for probiotic strain selection 

With the increased data about benefits of probiotics for 

human health and treatment and since most isolated and 

patented strains are of western origin, it is greatly inviting 

to try and isolate such probiotics from the untapped source 

examplified by a wide variety of different fermented foods 

of the orient (Table 2). For example, Keshik which is a 

Jordanian traditional fermented food made up of barboiled 

dried wheat and butter milk is of interest (Tamime and 

O'Connor, 1995). The product is similar to Tarhana 

(Turkish traditional fermented food) which proved to be a 

rich source of probiotic Lactic acid bacteria (Sengun, 

2009). Among other potential foods also is the fermented 

eggplant (locally named Makdoos) made up of baby 

Aubergine stuffed with ground wall-nut, garlic, parsley 

and fermented in olive oil. Jameed which is solar-dried 

curd of sheep or goat naturally-fermented milk prepared 

and used traditionally by Jordanian Beduins (the old desert 

dwellers) is another unique source of probiotic bacteria. In 

a preliminary screen (un-published data) we were able to 

isolate a wide selection of lactic acid bacteria from these 

foods to be tested further for their suitability and unique 

probiotic properties. Recently, probiotic lactic acid 

bacteria have been isolated from unpasturized natural 

camel milk with superior probiotic characteristics (Yateem 

et al., 2008; Khedid et al., 2009). These are just few 

examples of traditional foods in Jordan as part of the 

Middle East and many other countries of the orient would 

probably be richer especially traditional fermented foods 

of South East Asia and India, which invites more research 

in this direction. The long shelf-life of such traditional 

foods could probably indicate the presence of

136 


antimicrobial compounds among other characteristics 

exhibited by the indigenous bacteria which makes it a 

good probiotic candidate. Linking this to the increased 

consumer demand for natural and additive free foods 

would definitely maximize the interest in search for new 

sources of probiotic strains (Müller et al., 2009). 

Table 2. Some oriental traditional foods of East Mediterranean countries including Jordan. 

Traditional food Ingredients/ natural fermentation 

Aubergine Makdoos 

Green pepper Makdoos 

Pickled Green or Black Olives 

Vine leaves 

Keshik 

Jameed 

Tarhana 

Turkish Tarhana 

Cyprus Tarhana 

Shatta 

5. Probiotic delivery and persistence: 

In order to secure full functionality of a probiotic, an 

efficient delivery system, in vivo survival and clear 

clinical efficacy must be met (Doleyres and Lacroix, 

2005). In this context, it is implicated that increasing the 

stresses’ tolerance level of the probiotic microorganism is 

of utmost importance (Sheehan et al., 2007). The novel 

thoughts of improving probiotic functions may be seen 

through modifying the strain tolerance to different stresses 

on the genetic level. This thought has been tested using 

some probiotic strains of Bifidobacterium breve and 

Lactobacillus salivarius (Sheehan et al., 2006), but further 

investigations are needed such as interference with the 

ability of a probiotic microorganism to enhance its 

compatible solutes productivity which is another approach 

of arming probiotics against different stresses (Termont et 

al., 2006), an area which also needs further exploration in 

the quest for the best probiotic formulations. The third 

prospective approach involves what is referred to as 

designer probiotics i.e. which are basically tailoredprobiotics 

that would be very specific in targeting 

pathogens or intoxications where by doing this a 

pronounced prophylactic and therapeutic effects are 

realized (Laurel and Berger, 2005; Paton et al., 2005). 

Genetic engineering has been thought of as a useful 

approach for the design of probiotic bacteria that 

counteract the symptoms of genetic and age related 

diseases (Saier and Mansour, 2005). In combination 

therapy, components of pathogenic and nonpathogenic 

food-related bacteria are currently being evaluated as 

candidates for oral vaccines (Amdekar et al., 2009; Gill 

and Prasad, 2008; Collado et al., 2007b). It is believed 

now that as our knowledge of microbial variations is 

Aubergine, wall-nuts, garlic, parsley, salt fermented in olive 

oil. 

Sweet green pepper, shredded tomato, parsley, salt garlic 

fermented in water or olive oil. 

Olives, salt, water fermented or pickled in olive oil. 

Vine leaves, pickled or packed to ferment naturally. 

Boiled wheat, thick curd of goat or sheep yoghurt or fermented 

milk, salt subjected to solar drying where slow fermentation 

takes place. 

Goat or sheep thick yoghurt curd, salt and then solar dried 

where slow fermentation improve the taste. 

Dried mixture of cracked wheat yoghurt or fermented milk. 

Cracked wheat or flour, yoghurt and vegetables fermented and 

then dried. 

Cracked wheat and fermented milk flavoured with bay leaf, 

thyme and fennel seed. 

Ground dried miniature chilies fermented in salt water and 

vegetable oil. 

refined, tailoring of human associated microorganisms is 

rational and may lead to remodeling of their functions 

(Predis and Versalovic, 2009). Roos et al., (2010) reported 

improved humoral immune response against E. coli and 

bovine herpes vaccines in lambs through feeding with 

probiotic B. cereus and Saccharomyces boulardii strains. 

6. Side effects and risks: 

Some microorganisms have a long history of use as 

probiotics without causing illnesses in consumers. 

However, some probiotics safety has not been fully studied 

and understood scientifically. More information is 

especially needed on how safe they are for infants, 

children, old people and those with compromised immune 

systems. 

Probiotics side effects, if they exist, would probably be 

mild digestive disturbances including gas and bloating. 

More serious contraindications have been observed in 

some incidences. Probiotics might in theory cause 

infections that need antibiotic treatments especially with 

people underlying health problems. They may also cause 

unhealthy metabolic activities i.e. too much stimulation of 

the immune system or even gene transfer among cells 

(Nerstedt, 2007). 

Side effects and unsubstantiated claims are possible 

with prophylactic agents including probiotics. Probiotics 

are microorganisms, and we know the unpredictability of 

microorganisms in terms of how it will react to the existing 

or indigenous microbiota located in the target host. Gould 

and Shrot (2008) pointed out that particular illnesses such 

as post-antibiotic diarrheae are very responsive to 

probiotic treatment. However, they emphasize that many 

studies on humans have been disappointing although so


many of therapeutic potentials of probiotics still need great 

deal of substantiation before being recommended for 

medicinal applications. With these in mind, probiotics 

might be considered as one facet in a patient's health 

maintenance strategy. To conclude, we would say that 

since each human family and each individual in that family 

harbour a different combination of gut microflora, there 

may be some genetic propensities for and against certain 

probiotic strains. More investigations are needed to find 

out which group may benefit from which probiotic 

candidates and probably the source-effect of that probiotic 

microorganism. Further along the same concept, it is 

usually accepted to say that many studies of probiotics are 

carried on experimental animals rather than human 

subjects where lab results and animal studies cannot 

always be generalized to results in humans. In this context, 

it is observed that a single bacterial strain colonizing the 

gut of a gnotobiotic usually reaches a much higher counts 

than it does in a conventional animal, where the bacteria is 

faced with competition from others (Tannock, 2004). It is 

also noted that in the complex conventional ecosystem, the 

process of up and down regulation of host genes 

expression induced by different bacterial species vary 

tremendously with the presence of varying species and 

even strains (Hooper et al., 2001). 

7. Conclusion 

Probiotics are receiving great deal of attention in 

different fields of microbial biotechnology applications 

including health improvement and therapeutic purposes. 

This necessitates further diversification of sources of 

isolation to include traditional fermented foods of different 

cultures and geographical settings. Further works are 

needed to elucidate the functional characteristics of 

probiotic microorganisms. Designer probiotic for specific 

treatment is also an emerging field of research which 

would strengthen the drive of using probiotics for the 

treatment of different ailments and human health 

improvements. 

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JJBS 



ISSN 1995-6673 

Pages 141 - 146 

Effect of Selenium and its Compounds on Oxygen Uptake in 

Freshwater Fish Gambusia affinis after Exposure to Lethal Doses 

Rajashri. R Naik a and Huchhappgoudar.S.Patil b 

a Faculty of Pharmacy and Medical Sciences, Amman University, Amman, Jordan ; b Department of Zoology, Karnataka University, 

Abstract 

Dharwad , Karnataka India 

. 

The purpose of this study was to investigate the change in oxygen consumption of Gambusia affinis after exposure to 

selenium and its compounds. Male and female fish used in this study were exposed to known concentration of selenium and 

its compounds. All the forms of selenium showed concentration and exposure dependent inhibition. At the higher 

concentration of selenium and selenite male fish showed decrease in consumption, which later recovered, with increase in 

exposure period. Selenate showed relative decrease in uptake of oxygen. In female fish, selenium at lower concentration 

showed uniform decrease, at higher concentration after initial decrease recovery in uptake was observed. In selenate at lower 

concentration there was increase in oxygen uptake and at higher concentration there was decrease in uptake. All forms of 

selenium showed inhibitory action with decline at lower concentration and fluctuations at higher concentration of metals, 

with increase in exposure period there was slight recovery in oxygen uptake. 

Keywords: Selenium, Selenite, Selenate, Oxygen uptake, Gambusia affinis and Fish. 


Freshwater are highly vulnerable to pollutants since 

they act as immediate sink for the consequences of human 

activity always associated with danger of accidental 

discharges or criminal negligence (Vutukuru, 2003). 

Heavy metals constitute a core group of aquatic pollutants 

and additional concentrations of these metals accumulate 

in the aquatic ecosystem as a result of land based 

activities. Fish mostly have the tendency to bioaccumulate 

heavy metals and human might be at great risk some time 

even lethal, through contamination of food chain (Ui, 

1972). Selenium widely used in glass manufacturing 

industries chemical and pigment factories; it is also 

released from municipal waste, combustion of fossil fuels 

and industrial loses. Selenium is a naturally occurring 

element required in trace amounts for plants and animals. 

It is found in four oxidation states, selenate and selenite 

are highly soluble in water and are know to be toxic to 

biological system at relatively low concentration. Selenate 

and selenite predominate in aquatic environment because 

of their high solubility in water (Massecheleyn et al 1990). 

Studies have indicated that selenite was found to be more 

toxic then selenite (Maier et al., 1988 b). Selenium is 

essential metal for number of domestic animals, the 

optimal concentration ranges for fish growth and 

* Corresponding author. rajashrinaik4@yahoo.com. 


reproduction are narrow and both excess and deficiency 

are harmful to the fish. 

Information on lethal exposure of selenium and its 

compounds on the physiology of fish are limited and its 

effect on Gambusia affinis is not known. Knowledge of 

acute toxicity of a xenobiotic often can be very helpful in 

preventing and predicting acute damage to aquatic life in 

receiving water and as well as in regulating toxic waste 

discharges (APHA,1998). In view of this oxygen uptake 

by both male and female Gambusia affinis were studied 

after exposing it to lethal dose of selenium and its 

compounds. The corresponding results is being discussed 

in this paper and compared with other fishes exposed to 

various other metallic and environmental stresses. 

Gambusia affinis is freshwater member of poecilidae is 

a diminutive fish rarely exceeding 46 mm in standard 

length, fish of this genus are well know for their 

consumption of insect larvae. This fish is used as 

biological control in the infestation of mosquito larva and 

is commonly known as mosquito fish. It is used world 

wide in control of mosquito larvae, native of southeastern 

United States and northeastern Mexico. Now it is one of 

the most widely distributed freshwater fish (Krumholz, 

1948). 

2. Materials and methods. 

Fish collected from the local pond were transferred to 

fish tank in laboratory with continuous flow of 

dechlorinated tap water, fish were fed every alternate day

142 


with Shalimar fish feed. Male and female fish were 

separated based on their size (female being larger), 

coloration and presence of gonopodial hook in male and 

gravid spot in female fish. Prior to the study all the 

glassware were washed thoroughly and both male and 

female fish of approximately equal size transferred to 

rectangular glass for experimentation, each trial was 

conducted with parallel control, feed was not given during 

the study and 24 hr prior to the study. Water quality 

characteristic in each aquarium were determined at the 

initial stage by following APHA 1998. 

2.1. Preparation of stock solution 

Selenium: Metallic selenium (Se purity – 99.5%) was 

digested with 2.5 ml concentrated nitric acid in a beaker; 

the digested solution was transferred to 100 ml volumetric 

flask and diluted with distilled water upto the mark. 

Oxygen uptake was studied using this stock solution with a 

parallel control (with same amount of concentrated nitric 

acid). 

Selenite: Sodium selenite (NaSeo3 5H2O- purity 

99.0%) was weighed and transferred to volumetric flask, 

dissolved with distilled water and volume made upto 

100ml, the concentration of selenite in salt was 0.478 g 

and Na and H2O and impurities is 0.527 g per 100ml of 

solution. Therefore, each ml of stock solution contains 

4.78 mg selenite. Oxygen uptake was calculated on the 

basis of amount of selenite in solution using distilled water 

as control. 

Selenate: Sodium selenate 1.0 g (NaSeo410H2O purity 

97.0%) was weighed and transferred to 100 ml volumetric 

flask, selenate was dissolved in distilled water and the 

volume was made upto 100 ml. Selenate is 0.375 g and 

sodium and other impurities are 0.625 g per 100ml of 

solution. Therefore each ml of stock solution contains 75 

mg of selenate. Oxygen consumption was calculated on 

the basis of selenate in the solution and using distilled 

water as control. 

2.2. Oxygen uptake 

For oxygen uptake Winkler's Azide modification 

method (APHA, 1998) was employed. In this method one 

molecule of O2 = 2 molecules of iodine produced at the 

end of reaction in bottle. 

Therefore 1 ml of standard sodiumthiosulphate (0.025 

N) = 0.2 mg of dissolved oxygen as mg/l = 0.2×5 = 1 mg/l. 

Hence, burette reading directly gives amount in weight of 

oxygen dissolved. Choubey and Pandey (1993) method 

was adapted for measurement of oxygen consumption with 

surfacing prevented and surfacing allowed to the 

experimental fish, fishes were confined to fixed volume of 

water in respiratory jar for particular length of time, 

volume of water was in proportion to size and weight of 

fish, for each set of experiment a parallel control with fish 

and without toxicant and a blank was set. Blank was used 

to detect oxygen consumption of microorganism and other 

oxidizing materials. After a know interval of time 

dissolved oxygen of water in jar was estimated, from 

dissolved oxygen of blank dissolve oxygen of water in 

which control fish were put and dissolved oxygen of water 

in which experimental fish, the amount of oxygen 

consumed by test fishes was calculated, weight of control 

and exposed fish was noted and oxygen consumed was 

expressed as mg of O2 h- 1 g body weight, the consumption 

rate of control was taken as 100% (Normal rate) around 10 

samples were taken. 

3. Results 

Male and female fish were exposed to three different 

concentrations of selenium, selenite and selenate for 24, 

48, 72, and 96 hrs and oxygen uptake of the stressed fish 

was measured at intervals of 24, 48, 72, 96 hr of exposure 

At lower concentration of 5 mg selenium, male fish 

showed an initial increase (24 hr) of 36.70% in percent 

utilization of oxygen which dropped to 15.745 at 48 hr, 

there after a rapid increase in uptake was observed from 

50.21 to 59.39% at 72 and 96 hr exposure. At 6 mg/l, small 

amount of 5.06% of oxygen was consumed followed by 

marked depletion in uptake at 48 hr (-62.96%) which later 

increased to 21.81%. Higher concentration of 10 mg /l 

showed an initial enhancement of 20.88% followed by 

sudden drop in uptake of -76.85% at 48 hr, which 

recovered from 72 hr with 3.43% and 12.04% at 96 hr. 

On exposure to different concentration of selenite, it 

was found to be time and concentration dependent. Lower 

concentration of selenite (8 mg /l ) showed steady increase 

of 28% which raised to 59.76% at 96 hr. Percent 

utilization of oxygen ranged from 23.40 at 24 hr to 55.85 

at 96 hr on exposure to 9.5 mg/l. Oxygen consumption 

was reduced at 13 mg/l to 7.09% which thereafter 

increased gradually to 53.12%. It is evident from the data 

that percent uptake of oxygen declined with increasing 

concentration in the test medium. 

Selenate a less toxic compound when compared to 

other two forms also induced fish to consume more 

oxygen available in test medium. At 65 mg/l selenate, a 

constant uptake of 32.74% in consumption of oxygen was 

observed upto 48 hr of exposure, thereafter a sudden 

increase in uptake of 53.19% was observed at 72 hr which 

further rose to 61.81% at 96 hr. At 75 mg/l, percent 

oxygen uptake ranged from 15.20 at 24 hr to 31.03 at 96 

hr, high concentration of 85 mg/l selenate lowered rate of 

uptake was recorded, with the values that varied between 

2.92 at 24 hr and 29.88% at 96 hr. 

Consumption of oxygen in male fish was found to be 

concentration and time dependent, the rate of oxygen 

uptake reduced with increase in concentration of selenate, 

however with increase in exposure period there was 

increase in uptake of oxygen. The results were statistically 

analyzed with two way ANOVA and was found to be 

significant at P


Figure 1. Oxygen consumption in male fish. 

Figure 2. Oxygen consumption in female fish. 

143

144 


Female fish was exposed to three lethal concentrations 

of selenium and its compounds. The three lethal 

concentration of selenium chosen were 2, 5 and 10 mg/l 

and the response to oxygen uptake was studied. There was 

a uniform decrease in oxygen utilization at the lowest dose 

of 2 mg/l, percent utilization fluctuated between 59.01% 

and 62.24%. At 5 mg/l, the rate of uptake was drastically 

affected and a slow recovery in uptake with increase in 

exposure period was observed. Fish after exposure to 10 

mg/l showed initial increase in uptake, which decreased 

gradually from 18.03% to 13.69% (at 72 hr) and later 

recovery in uptake of 40% was observed at 96 hr of 

exposure. Data revealed that first two days of exposure, 

percent uptake was not found to be concentration – 

dependent and decrease in last two days of uptake was 

concentration – dependent. 

In response to selenite exposure (2, 5 and 10 mg/l), fish 

did not show uniform consumption of oxygen however 

the uptake rate fluctuated with time of exposure and 

concentration selenite concentration. Lower concentration 

of selenite showed initial increase in uptake fallowed by 

sharp decline to 2.61% and in subsequent observation an 

enhancement fallowed by decline in uptake was noticed. 

Similar trend in uptake was observed at 5 and 10 mg/l of 

selenite. The results were statistically analyzed with Two 

way ANOVA and the results were statistically significant 

at P0.005 at exposure period. 

The pattern of variation in oxygen uptake in fish on 

exposure to three different concentrations of 5, 10 and 15 

mg/l selenate showed a different trend. Fish dosed with 5 

mg/l showed rapid increase in uptake at 24 hr. Thereafter 

there was a steep decline and later uniform pattern in 

uptake was observed through out the experimental period. 

Oxygen uptake reduced from 46.67% to 18.42% at 72 hr, 

followed by recovery in uptake of 28.81% at 96 hr. At 

higher concentration of 15 mg/l fish consumed 35.29% 

oxygen at 24 hr, which dropped to 3.88%, thereafter steady 

increase in uptake was observed. Results were statistically 

analyzed by two way ANOVA and were found to be 

significant at P0.0054. Results are presented in table 2 and Fig 2. 

4. Discussion 

The results of the present study show that fish under 

toxic stress to different forms of selenium altered oxygen 

uptake. In general, initial decrease of oxygen uptake 

followed by an increase in its consumption was observed. 

All forms of Se have shown inhibitory action on rate of 

oxygen utilization and at time irregular uptake was 

noticed. However, as exposure period advanced a slight 

recovery was found in both male and female fish (Koti, 

1996) has shown that Cu, Zn and Ni during lethal and sub 

lethal exposure (Individual and mixture of metals) altered 

oxygen consumption in both sexes of G.affinis. It was 

observed that fish in response to metal exposure secreted 

mucus in the test medium and red patches appeared at gill 

region and basal part of pectoral fins. Environmental 

factors such as temperature, pH, and hardness of the test 

medium, have shown cumulative effect on oxygen uptake 

of G.affinis in the presence of Cu, Zn and Ni 

(Kallangoudar and Patil, 1997). Lemly (1993) 

demonstrated metabolic stress in bluegills Lepomis 

macrochirus due to elevated concentration of selenium. He 

also showed reduced respiratory activity with increase in 

respiratory demand and oxygen consumption due to gill 

damage. According to (Tovell et al., 1975) metals mainly 

enter fish through respiratory system. The mechanism for 

metal uptake through gill probably occur through pores by 

simple diffusion (Bryan, 1979) these metals are then 

absorbed through cell membranes (Opperhuizen et 

al.,1985) Metals then coagulate in protoplasm after 

absorption into the bodies of aquatic animals (Skidmore, 

1964). The decrease in oxygen uptake observed following 

exposure to selenium, selenite and selenate was possibly 

due to mucus precipitation on gills, during the present 

study mucus was present on the gills which appeared as 

reddish patches and was possibly secreted in response to 

the irritation caused by metalloids (Carpenter, 1930) 

investigated lethal action of dissolved metals salts on fish 

leading to death. According to him death resulted from 

interaction between metallic ions and mucus secreted by 

the gills and not from internal poisoning. A layer of 

coagulated mucus is formed on the gill surface which 

impairs respiratory efficiency to such an extent that fish 

becomes asphyxiated (Rani and Ramamurthi, 1987; Gosh 

and Chakraborti, 1990). Increased utilization of oxygen 

during later part of lethal exposure to selenium and its 

forms indicate that under stress fish might have used more 

oxygen to meet metabolic demand. Similar effect of metal 

stress on respiratory activity in other fish has been 

reported, (Davis, 1975; Van Resburg1989; Shivraj, 1990; 

Koti, 1996; Vijayamohanan et al., 2000). Other possible 

alternate reason of inhibitory action of pollutants include 

gill damage (Natarajan, 1981; Koti, 1996) and internal 

action of pollutants (Natarajan, 1981; Tuurala and Soivio, 

1982) 

Selenium and its compounds has shown to affect 

oxygen uptake in both male and female fish after exposure 

to lethal dose, which is evident from the gradual decline in 

uptake at lower concentration and fluctuations at higher 

concentration. Which may be due to over secretion of 

mucus resulting in blocking of gills or due to onset of 

severe hyoxia, which alter the metabolic pathways or due 

to damage caused my metals to gill. Increase in uptake 

may be due to increase in demand under toxicant stress.


Table 1. Percent oxygen uptake in male fish G.affinis after exposure to lethal concentration of selenium and its salts. 

Toxicant Dose( mg/l) 

Control - 

Exposure period ( hours) 

24 48 72 96 

39.57±0.86 

(100%) 

35.25±0.96 

(100%) 

22.62±1.16 

(100%) 

18.69±1.28 

(100%) 

F-Ratio P-value 

- - 

Se 5 36.70±0.48 15.74±0.44 50.21±0.57 59.39±0.53 0.530 0.001 

6 5.06±0.73 -62 .96±1.53 18.02±0.93 21.80±1.02 6.630 0.001 

10 20.88±0.61 -76.85±0.93 -3.43±1.18 12.40±1.14 5.570 0.001 

selenite 8 28.36±0.51 45.59±0.53 57.44±0.50 59.76±0.52 70.260 0.001 

9.5 23.40±0.56 42.40±0.57 61.27±0.45 55.85±0.59 7.610 0.001 

13 7.09±0.65 37.17±0.60 53.19±0.57 53.12±0.61 52.220 0.001 

selenate 65 32.74±0.60 32.96±0.65 55.08±0.55 61.68±0.50 186.854 0.001 

75 15.20±0.73 7.85±0.87 19.49±0.94 31.03±0.89 25.504 0.001 

85 2.92±0.81 5.75±0.90 6.77±1.08 29.88±0.90 12.914 0.001 

Results are Significant at P

146 


Skidmore JF.1964. Respiration and osmoregulation in rainbow 

trout with gills damaged by zinc sulphate. J Exp Biol. 52: 481 – 

484. 

Tovell PWA Howes D Newsome CS. 1975. Absorption 

metabolism and excretion by goldfish of the anionic detergent, 

sodium lauryl sulphate. Toxicology 4: 17 – 29. 

Tuurala H Soivio A. 1982. Structural and circulatory changes in 

the secondary lamellae of Salmon gairdneri gills after sublethal 

exposure to dehydroabietic acid and zinc. Aquat.Tox. 2: 21 – 29. 

Ui J . 1972. The Changing Chemistry of the Oceans. Almquist 

and Wiksells, Stockholm 

Van Resburg EL. 1989. The bioconenrtation of atrazine, zinc and 

iron in Tilapia sparrmanii (Chiclidae) PhD thesis, Rand: African 

Univ South Africa p – 137. 

Vijayamohanan Nair A Suryanarayanan H. 2000. Lethal limits 

and respiration in the chiclid fishes Etroplus Maculatus (Bloch) 

and Etroplus suratensis (Bloch) exposed to effluents from 

Titanium di oxide factory. J Environ Biol. 21 (3): 169 – 172. 

Vutukuru SS. 2003. Chromium induced alterations in some 

biochemical profiles of the Indian major carp, Labeo rohita 

(Hamilton). Bull. Environ Contanm Toxicol. 70: 118 – 123.

JJBS 



ISSN 1995-6673 

Pages 147 - 152 

Curative Effect of Garlic on Alcoholic Liver Diseased Patients 

Abstract 

Sankaran Mirunalini*, Vadivel Arulmozhi and Thangam Arulmozhi 

Department of Biochemistry and Biotechnology, Annamalai University, Annamalai nagar-608 002, Tamil Nadu, India. 

Alcohol is currently recognized as the most prevalent known cause of abnormal human development. Our aim was to 

investigate the effect of raw garlic on patients suffering from alcoholic liver disease. 20 alcoholic patients and 20 healthy 

individuals were selected. Both patients and normal individuals were subjected to detailed clinical examination and 

laboratory investigations. Blood samples were collected and the liver disease was assessed by measuring the activities of 

liver marker enzymes such as aspartate aminotransferase (AST), alanine aminotransferase (ALT), alkaline phosphatase 

(ALP), gamma glutamyl transferase (GGT) and lactate dehydrogenase (LDH) which were elevated in alcoholic patients. 

Increased lipid peroxidation in alcoholic patients was accompanied by decreased activities of Superoxide dismutase (SOD), 

Catalase (CAT), Glutathione peroxidase (GPx). Oral supplementation of 2 small sized raw garlic cloves (1 clove = 1.2g) to 

alcoholic patients for 45 days, significantly lowered the activities of liver marker enzymes, decreased the levels of lipid 

peroxidation and enhanced the antioxidant status to near normal. Thus, the data of the present study suggest that raw garlic 

offers protection against oxidative stress and antioxidant activities in alcoholic liver disease patients. 


Keywords: Alcoholic liver disease, Antioxidants, Garlic, Lipid peroxidation, Liver marker enzymes, Oxidative stress. 


Alcoholic liver disease is one of the most serious 

consequences of chronic alcohol abuse. The disease is 

often progressive and is considered to be a major cause of 

morbidity and mortality (Sherlock, 1995). Free radicals 

and oxidative stress have been implicated in the 

pathogenesis of ethanol induced liver injury in humans and 

experimental animals (Lin et al., 1998; Zima et al., 2001). 

Basically, ethanol is metabolized into cytotoxic 

acetaldehyde by alcohol dehydrogenase in the liver and 

acetaldehyde is oxidized to acetate by aldehyde oxidase or 

xanthine oxidase giving rise to Reactive oxygen species 

(ROS) via Cytp450 (Fridovich, 1989; Nordmann et al., 

1992). Thus, excess intake of alcohol resulted in the 

production of oxygen radicals which leads to lowering the 

body’s normal defense mechanism thereby altered enzyme 

activity, decreased DNA repair and impaired utilization of 

oxygen, lipid peroxidation and protein oxidation. Some of 

these alterations induced by oxidative stress can eventually 

cause necrosis and subsequently leads to oxygen damage 

(Kurose et al., 1996). In recent years, the popularity of 

native medicine has increased for various reasons. Since 

there is no reliable hepatoprotective drug available in 

modern medicine, alcohol researchers have focused on 

developing phytotherapeutic medicines which can provide 

* Corresponding author. mirunasankar@gmail.com. 

many invaluable drugs to treat alcoholic liver disease. 

Thus, the research conducted on several natural plant 

products used as hepatoprotective agents is welldocumented 

(Saravanan et al., 2006). 

Allium sativum commonly known as garlic is a bulbforming 

herb of lilliaceae family. Garlic is the oldest 

cultivated plant and has been used as a spice, food and 

folklore medicine for over 4000 years. It has been used as 

a traditional medicine in the treatment of heart diseases, 

tumors and headaches and exhibits medicinal properties 

including immunomodulation, hepatoprotection, 

antioxidant, antimutagenic, antibacterial and 

anticarcinogenic effects (Agarwal, 1996). Moreover, it has 

also been reported to possess antifungal (Halliwell et al., 

1992), hypoglycemic (Yoshida et al., 1987), 

hyperglycemic (Nadkarni, 1976), hypolipidemic 

(Pushpendran et al., 1982), anti-atherosclerotic properties 

(Bordia, 1981) and has been claimed to be effective 

against a number of diseases (Block et al., 1984). The 

active principle present in garlic is organosulphur 

compound such as allicin, allin, alliase, S-allyl cystein, 

diallyl disulphide and allyl methyl trisulphide (Augusti, 

1996). These active compounds are mainly responsible for 

protecting from tissue damage and various disorders. 

Among many supplements, aged garlic extract has a 

reproducible array of compounds which have been 

analyzed and studied extensively for their high antioxidant 

content and health protective potential. However, the 

inhibition of lipid peroxidation and free radical scavenging 

activity has been suggested as a possible mechanism of

148 


hepatoprotective action. Thus, the present study was 

under-taken to establish the hepatoprotective effect of raw 

garlic on alcohol liver disease patients. 

2. Patients and Methods 

The present study is comprised of 20 newly diagnosed 

alcoholic patients from Rajah Muthiah Medical College 

and Hospital, Annamalai University, Tamilnadu, India. An 

equal number of healthy subjects (volunteers) were also 

investigated. The subjects were all males with the ages 

ranging from 48-55years. Patients suffering from any other 

diseases other than alcohol intake were excluded from the 

study. The selected patients were alcoholic for the past 5-6 

years and during the treatment, the patients stopped 

consuming alcohol. Both patients and normal individuals 

were subjected to detailed clinical examination and 

laboratory investigations. The ethical committee of Rajah 

Muthiah Medical College and Hospital Annamalai 

University, Tamilnadu, India, approved the study protocol 

in the year 2008. 

Alcoholic patients received 2 small sized raw garlic 

cloves (1 clove = 1.2 g) daily morning under fasting 

conditions (12-24 hrs) for 45 days. Blood samples were 

collected from various arm puncture into plain tubes from 

healthy individuals and alcoholic patients before and after 

the treatment with raw garlic. Heparnised blood samples 

containing serum and plasma were separated by 

centrifugation at 3000rpm for 5min and buffy coat was 

removed and packed cell washed three times with 

physiological saline. Biochemical estimations were done 

in serum and in erythrocyte membranes of alcoholic 

patients before and after treatment with raw garlic. The 

results obtained were compared with normal individuals. 

2.1. Biochemical Analysis 

2.1.1. Estimation of liver marker enzymes 

The activities of serum aspartate aminotransferase 

(AST, E.C.2.6.1.1) and serum alanine aminotransferase 

(ALT, E.C.2.6.1.2) were assayed by the method of 

Reitman’s and Frankel (1957). Serum alkaline phosphatase 

(ALP, E.C.3.1.2.3.1) was estimated using Kind & King’s 

method (1954), King (1965). The serum gamma glutamyl 

tranferase (GGT, E.C.2.3.2.2) was assayed according to 

the method of Rosalki and Rau (1972). The activity of 

lactate dehydrogenase (LDH, E.C1.1.27) was estimated by 

the method of King (1965). Serum total protein, albumin 

were estimated by Biuret method Reinhold (1953). 

2.1.2. Lipid peroxidation and enzyme assays 

Lipid peroxidation was measured by estimating the 

levels of malondialdehyde (MDA) using Thiobarbituric 

acid reaction method. Thiobarbituric acid (TBARS) in 

plasma was estimated by the method of Yagi (1978) and 

TBARS in erythrocyte membrane was estimated by the 

method of Donnan (1950). The activities of enzymatic 

antioxidants SOD (E.C.1.15.1.1) was assayed by the 

method of Kakkar et al., (1984). The activity of CAT 

(E.C.1.11.1.6) was assayed by the method of Sinha (1972). 

The activity of GPx was assayed by the method of Rotruck 

et al., (1973). 

2.2. Statistical analysis 

The values were expressed as mean ±S.D. Statistical 

evaluation was done using one way analysis of variance 

(ANNOVA) which is followed by Duncan’s multiple 

range test (DMRT). The level of statistical significance 

was set at p< 0.05. 

3. Results 

Table 1 show that alcoholic patients have severe liver 

damage which was indicated by the increase in marker 

enzymes such as AST, ALT, ALP, GGT and LDH. 

However, administration of raw garlic significantly 

decreased the activity of these enzymes which was 

compared to that before treatment. 

The levels of serum total protein was increased and the 

albumin levels were decreased in alcoholic patients, while 

on treatment with raw garlic it significantly improved both 

protein levels and albumin levels to near normal which 

was also compared to that of the normal individuals. 

Table 2 shows that the levels of lipid peroxidation 

indicated by TBARS were significantly higher in plasma 

and erythrocytes of alcoholic patients as compared with 

normal subjects. TBARS level was lowered significantly 

in the plasma and erythrocytes of patients treated with 

garlic. 

Further, the activities of SOD, CAT and GPx in 

erythrocytes were observed in normal and alcoholic 

patients. In alcoholic patients, the activity of SOD, CAT 

and GPx were significantly lower than the normal subjects. 

Treatment of alcoholic patients with garlic significantly 

elevated the antioxidant defense activity compared with 

that before treatment.


Table 1. Effect of raw garlic treatment on hepatic marker enzymes and serum proteins in alcoholic patients. 

Parameters 

AST (IU/L) 

ALT (IU/L) 

ALP (IU/L) 

GGT (IU/L) 

LDH (IU/L) 

Total protein (g/dl) 

I 

Normal individuals 

19.4±4.07 a 

43.4±7.3 a 

89.9±13.3 a 

41.7±5.1 a 

88.3±20.8 a 

7.2±0.2 a 

Groups 

II 

Alcoholic patients 

before garlic treatment 

80±21 b 

124.2±15.7 b 

` 

165.9±21.9 b 

226.7±28.8 b 

349.8±32 b 

8.5±0.5 b 

III 

Alcoholic patients after 

garlic treatment 

45±12 ac 

55±8.5 ac 

92±13.5 ac 

65±10.5 ac 

105±15.2 ac 

7.0±0.2 ac 

Albumin (g/dl) 4.1±0.2 a 3.4±0.7 b 4.0±3.0 ac 

Values are expressed as mean ± SD; n=20. Values not sharing a common superscript letter are significantly different at p

150 

4. Discussion 


Free radical mediated damage to macromolecule plays 

a crucial role in the pathophysiology of atherosclerosis, 

inflammation, carcinogenesis, aging, drug reaction and 

toxicity (Jose et al., 1999). When the liver gets damaged 

after consumption of alcohol, it leads to leakage of cellular 

enzymes into the plasma (Baldi et al., 1993). The 

increased levels of serum enzymes such as (AST), (ALT), 

(ALP), (GGT) and (LDH) observed in alcoholic patients, 

resulted in liver damage, increased permeability and 

necrosis of hepatocytes (Goldberg and Watts, 1965). In our 

study, administration of raw garlic to alcoholic patients 

alleviates the increased activities of serum enzymes AST, 

ALT and ALP to near normal. Serum GGT is a sensitive 

marker enzyme widely used as a laboratory test for the 

hepatobillary diseases especially alcoholic liver disease 

and alcohol induced liver damage (Nakanishi et al., 2006). 

In the present study, we observed that GGT has invariably 

elevated while AST and ALP are slightly increased in 

alcoholic patients. Garlic supplementation significantly 

lowered the activities of GGT demonstrating reduced liver 

damage following garlic administration. 

Albumins and globulins are two key components of 

serum proteins. As albumin is synthesized in the liver, it 

can be used as a biomarker to monitor liver function 

(Friedman et al., 1980). In serum total proteins, albumin 

contents were reduced in alcoholic patients. Hence a 

significant decrease in the serum total protein and increase 

in serum albumin was observed in alcoholic patients 

treated with raw garlic. This stabilization of serum protein 

level is a clear indication of garlic being related to an 

improvement in the functional status of the liver cells. 

Lipid peroxidation mediated by free radicals is 

considered to play a pivotal role in the mechanism by 

which ethanol may exert its toxic effects on the liver and 

other extra hepatic tissues (Nordmann, 1994). Increase in 

the levels of TBARS indicates enhanced lipid peroxidation 

leading to tissue injury and failure of the antioxidant 

defense mechanism to prevent the formation of excess free 

radicals (Comporti, 1985). In our study we observed an 

increase in TBARS and a decline in antioxidant status in 

plasma and erythrocytes of alcoholic patients. However, 

treatment with garlic significantly decreased the levels of 

lipid peroxidation. 

Free radical scavenging enzymes such as SOD, CAT, 

and GPx are the major defence enzymes against oxidative 

injury. SOD is a ubiquitous chain breaking antioxidant, 

plays an important role in protection against deleterious 

effects of lipid peroxidation (Dinkova–Kostova and 

Talalay, 1999). It converts the highly reactive superoxide 

radical to hydrogen peroxide, which in turn either 

metabolized by catalase or by glutathione peroxidase. 

The primary role of catalase is to scavange H2O 2 and 

convert it into H 2O. It plays an important role in the 

acquisition of tolerance to oxidative stress in adaptive 

response of cells. Studies have shown that decrease in 

catalase during alcohol consumption may be due to the 

decreased protein synthesis. Thus, there is an increased 

utilization of CAT during alcohol consumption. 

Gpx is a selenium dependent enzyme found primarily 

in the cytoplasm and also found in the mitochondria. It 

catalyses the detoxification of endogenous metabolic 

peroxides and hydroperoxides that leads to the oxidation of 

GSH. It has a high potency in scavenging reactive free 

radicals in response to oxidative stress. 

The antioxidant defense systems SOD, CAT and GPx 

activity is significantly decreased in alcoholic patients. 

This decrease could be due to a feedback inhibition or 

oxidative inactivation of enzyme protein because of excess 

ROS generation. The generation of α-hydroxyethyl radical 

may lead to inactivation of these enzymes (Pigeolot et al., 

1990) and accumulation of highly reactive free radicals 

also lead to deleterious effects such as loss of cell 

membrane integrity & membrane function (Krishnakanth 

and Lokesh, 1993). 

There was a significant increase in the activity of these 

enzymes after raw garlic administration. It is reported that 

garlic suppresses the formation of superoxide anion and 

hydrogen peroxide by increasing the activity of SOD, CAT 

and GPx (Borek 2001). Therefore, garlic increases 

antioxidant action by scavenging ROS, enhancing the 

cellular antioxidant enzymes and increasing glutathione in 

the cells. Moreover, it has also been reported that garlic 

modulates the levels of lipid peroxidation (Hussein et al., 

2007). Although multiple actions may take place during 

hepatoprotective activity, modulation of lipid peroxidation 

and antioxidant status may be one of the important 

mechanisms by which garlic exerts its toxic inhibitory 

effect. 

Thus, our results suggest that, oral administration of 

raw garlic protects tissue damage by increasing the 

antioxidant status against oxidative stress. Hence, garlic 

plays a promising role in antioxidant and it can be 

considered as a potent drug for the treatment of alcoholic 

disorders. Further studies are needed to unravel the 

mechanism of action of garlic and its active components. 

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JJBS 



ISSN 1995-6673 

Pages 153 - 164 

Seasonal Variation of Copepoda in Chabahar Bay-Gulf of Oman 

Neda Fazeli a , Hamid Rezai Marnani b , Saeed Sanjani b , Rasool Zare a , Simin 

Dehghan a and Najme Jahani a 

a Khorramshahr University of Marine Science, Department of Biology, Khorramshahr, Iran 

b Iranian National Center of Oceanography (INCO) 

. 


Zooplankton was collected with vertical plankton tows 

using 100 μm mesh nets during August to November 

2007 and February to May 2008 from five stations 

through the Chabahar Bay. Totally, 75 copepods species 

were identified. Post-monsoon was characterized by the 

highest numerous of copepod species and diversity. Premonsoon 

showed the lowest number of copepod species 

and diversity index. The results showed that seasonal 

variation of chlorophyll-a concentration associated 

phosphate concentration is a major factor controlling 

abundance of copepod after a time lag. Abundance of 

copepod was significantly higher during the premonsoon 

as compared to other seasons. 

Keywords: Copepoda, Abundance, Diversity, Monsoon, Chabahar Bay, Species richness. 


Chabahar Bay is a sub-tropical and semi-enclosed bay 

with high biological production, providing an ideal 

breeding ground for many economically important fishes 

and shell fishes (Fazeli, 2008). Information on the marine 

zooplankton of the Chabahar Bay is scanty, except for the 

projects of Sanjarani, 2007 and Zareei, 1994, who worked 

in the Goater Bay. Further, many projects existed at Oman 

Sea such as Seraji, 2007. 

The ecological importance of zooplankton, especially 

its main component such as copepods, in the pelagic food 

webs of the world’s oceans has long been recognized. 

These organisms often constitute a significant component 

of the plankton community in many marine environments 

(Relevante et al., 1985; Burkill et al., 1987; Al-Najjar, 

2002); and play a central role in the transfer of nutrients 

and energy through the marine food webs (Poulet and 

Williams, 1991; Williams et al., 1994; Kiorboe, 1997) and 

have an important role in the trophy food web (Thiriot, 

1978). Copepods support energy transfer between primary 

* Corresponding author. n_fazeli200@yahoo.com. 

و 2007 ﻲﻧﺎﺜﻟا ﻦﻳﺮﺸﺗ ﻰﻟا بأ ) ةﺮﺘﻔﻟا لﻼﺧ ﺔﻴﻧاﻮﻴﺤﻟا ﻢﺋاﻮﻬﻟا ﺖﻌﻤﺟ 

75 ﺪﻳﺪﺤﺗ ﻢﺗ . رﺎﻬﺒﻬﺷ ﺞﻴﻠﺧ ﻲﻓ ﻊﻗاﻮﻣ ﺔﺴﻤﺧ ﻦﻣ ( 2008 رﺎﻳا ﻰﻟا طﺎﺒﺷ 

ﺪﻌﺑ تﺎﻴﻓاﺪﺠﻤﻟا رﻮﻬﻈﻟ اﺰﻴﻤﺗ ﺞﺋﺎﺘﻨﻟا تﺮﻬﻇا . تﺎﻴﻓﺎﺠﺠﻤﻟا ﻦﻣ ﺎﻋﻮﻧ 

حﺎﻳﺮﻟا بﻮﺒه ﻞﺒﻗ ارﻮﻬﻇ ﻞﻗا ﻚﻟاﺬآ و ﺔﻴﻤﺳﻮﻤﻟا رﺎﻄﻣﻻا لﻮﻄه 

ﺎﻣ ةﺮﺘﻓ لﻼﺧ ﺎﺤﺿاو نﺎآ تﺎﻴﻓاﺪﺠﻤﻠﻟ يﺮهﻮﺠﻟا فﻼﺘﺧﻻا 

. ﺔﻴﻤﺳﻮﻤﻟا 

نا ﺞﺋﺎﺘﻨﻟا ةﺮﻬﻇا . ىﺮﺧﻻا ﻢﺳاﻮﻤﻟﺎﺑ ﺔﻧرﺎﻘﻣ ﺔﻴﻤﺳﻮﻤﻟا حﺎﻳﺮﻟا بﻮﺒه ﻞﺒﻗ 

ﺰﻴآاﺮﺘﺑ ﺎﻘﻴﺛو ﺎﻃﺎﺒﺗرا ﻂﺒﺗرا تﺎﻴﻓاﺪﺠﻤﻟا رﻮﻬﻈﻟ ﺔﻴﻠﺼﻔﻟا تاﺮﻴﻐﺘﻟا 

. تﺎﻔﺳﻮﻔﻟا و رﻮﻀﺨﻴﻟا 


producers (phytoplankton) and the final consumer of 

highly valuable fish and crustacean species (Faure, 1951). 

Despite abundant evidence of the importance of 

zooplankton in marine pelagic food webs, little is known 

about their density, composition, stratification and 

distribution in Chabahar Bay. The main objective of the 

present study is to examine the composition of the main 

planktonic taxes, temporal and spatial variation of the 

abundance and distribution of copepods and the impact of 

environmental factors on copepod’s abundance. 

2. 2. Materials and Methods 

2.1. Study Area 

Chabahar Bay is a small semi-enclosed bay on the 

southeastern coasts of Iran (from 25° 17' 45"N- 60° 37' 45" 

E). This Bay is connected to the Indian Ocean by the 

Oman Sea. The Bay surface area is 290 km 2 with 14 km 

wide located between of Chabahar and Konarak (Fig.1). 

The average depth of this Bay is 12 m (ranges from 8- 

22m).

154 


Figure 1. Sampling stations in the Chabahar Bay-Oman Sea

2.2. Sampling 


Four sampling cruises were carried out in August 

2007 (SW-monsoon), November 2007 (post-monsoon), 

February 2008 (NE-monsoon), and May 2008 (premonsoon). 

Five stations were investigated throughout the 

Chabahar Bay. Two stations (St. 1 and 2) were located far 

from shore waters with 22 m depth, another two stations 

were near the shore with 6m depth (St. 3 and 5) and the 

final station (St. 4) was located in the middle of the bay 

with 12m depth. Zooplankton was collected by using 100- 

µm mesh nets equipped with Hydrobios flow meter, from 

near the bottom to the surface at each station where 

physico-chemical variables were determined. The samples 

were preserved immediately in 4-5% formalin, bufferered 

to a pH of 8 with sodim tetraborate (borax). Organisms 

were identified to groups and copepods to species level 

(whenever possible) and counted. Density was expressed 

as individuals per m - ³ (individual. m - ³).Only adult copepods 

were counted (Somoue et al., 2005). 

2.3. Data Analysis 

Species diversity was calculated using Shannon– 

Weaver diversity index (Shannon–Weaver, 1963) and 

Species richness (Margalef, 1968). The data were further 

subjected to hierarchical cluster and multidimensional 

scaling (MDS) analyses to identify the similarity between 

stations based on composition of copepod species that 

were calculated as Braye Curtis similarity index using 

PRIMER (Clarke and Warwick, 1994). 

3. Results 

3.1. Environmental variables 

The mean of water temperature varied from 

(20.53 0.20°C) in NE-monsoon to (29.92 0.05°C) in 

SW-monsoon. The mean of salinity ranged from 

(36.7 0.06 Psu) in SW-monsoon to (36.91Psu) in premonsoon 

(Fig.2b). The minimum and maximum values of 

chlorophyll-a concentrations were noticed (0.77 0.08 

mg. m־³) in SW-monsoon to (1.84 0.92 mg. m־³) in NEmonsoon 

(Fig.2c). The average of dissolved oxygen (DO) 

ranged from 5.66 0.05 ml.l -1 in SW-monsoon to 

8.80 0.03 ml.l -1 ± ± 

± 

± 

± 

± 

± in NE-monsoon (Fig.2d). 

Pre-monsoon season showed the maximum Silicate 

(SiO4) concentration (av. 0.031 ± 0.006 mg. m־³) whereas 

it was minimum during the NE-monsoon (av.0.017 ± 0.05 

mg. m־³) (Fig. 2e). The variation of nitrate (NO3) was (av. 

0.026 ± 0.004 mg. m־³) in pre-monsoon (av; 0.002 

± 0.0002 mg. m־³) in post-monsoon (Fig. 2f). Minimum 

and maximum values of phosphate (PO4) were from 

0.015 ± 0.006 mg. m־³ during the NE-monsoon season to 

0.008 ± 0.002 mg. m־³ during the SW-monsoon season 

(Fig. 2g). 

3.2. Copepoda abundance and composition 

Copepods were the dominant group during four 

seasons, reaching 69.73% (1253.57 302.65 ind. m־³) 

during pre-monsoon, 67.02% (613.30 326.35 ind.m -³ ± 

±± 

) 

during SW-monsoon, 62.58% (594.12 54.11 ind. m־³) 

during post-monsoon and 47.38% (904.17 ± 161.7 ind. 

m־³) in NE-monsoon (Fig 3; Fig 4). Copepod abundance 

155 

increased significantly (p

156 


Figure 2. a, b, c, d, Distribution of major physico-chemical variables during monsoonal seasons (x axis as stations and Y axis as physicochemical 

variables).


Figure 2. e, f, g, Distribution of major physico-chemical variables during monsoonal seasons (x axis as stations and Y axis as physicochemical 

variables). 

Since, there was no correlation between copepoda 

abundance and temperature-salinity, we conclude that the 

abundance of copepoda does not have any relationship 

with these parameters in Chabahar bay, while in some 

tropical embayments and estuaries in India, accelerate of 

zooplankton production during the periods of high salinity 

was documented by (Baidya and Choudhury, 1984; 

Tiwari and Nair 1993) and high temperature by (Li et al., 

2008). 

Copepod diversity and richness were related to 

copepod abundance inversely. Species richness was 

enhanced towards the far from the shore and middle 

stations of the bay (Table 3). This is because organisms 

living in near shore waters seem to be adapted to the 

qualification and unable to thrive in offshore area (Faure, 

1951). Increase of diversity and richness indices in far 

from shore communities is common in Indian Ocean 

157 

(Madhupratap, 1986). This trend was observed in waters of 

Africa by (Okemwa, 1990) in Tudor Bay, (Mwaluma, 

1997) in Kenya, (Osore, 1992; Osore, 1994) in Gazi Bay 

and (James et al., 2003) in Media creek. In India, in the 

Bay of Bengal and Cochin backwaters, the similar trend 

were reported by (Pillai et al., 1973; Nair et al. 1981; 

Tiwari and Vijayyalakshmi, 1993), who attributed this 

high diversity to the calmer, more stable oceanic waters. 

In this study Oithona nana had much abundance 

through the year. This species is a euryhaline and euryterm 

species in tropical water (Nishida, 1985). Most abundance 

of copepod species during the pre-monsoon belongs to 

Harpacticoida in particular Macrosetlla gracilis ، 

Microsetella rosea ،Euterpina 

acutifrons and Corycaeus 

andrewsi. 

In conclusion, chlorophyll-a concentration appear to be 

the important factor leading to increase of copepod

158 


Figure 3. Percentage of zooplankton groups (%) during monsoonal seasons in Chabahar Bay. 

Figure 4. Seasonal (a) and spatial (b) distribution of copepoda during monsoonal seasons in Chabahar Bay.


Figure 5. Cluster and MDS analyses showing similarity of stations during monsoonal seasons based on copepod composition in Chabahar 

Bay. 

*Figure 5 continues in the next page. 

159

160 


Figure 5. Cluster and MDS analyses showing similarity of stations during monsoonal seasons based on copepod composition in Chabahar 

Bay.

Species 

Paracalanus crassirostris 

P.elegans 

P.aculatus 

P.denudatus 

P.parvus 

P.sp 

Acrocalanus longicornis 

A.gracilis 

A.gibber 

A.monochus 

A.sp 

T. desicaudata 

T.turbinata 

T.stylifera 

Eucalanus subcrassus 

E. morcantus 

E.sp 

E. crassus 

E. attenuatus 

E.monochus 

E. pileatus 

E. halinus 

Acartia pasifica 

A.erythraea 

A.sp 

A. longirenis 

Clausocalanus furcatus 

C. gracilis 

C. minor 

C.sp 

Calocalanus styliremis 

C. plumulosus 

C.pavo 

Pseudodiptomus sp 

P.marinus 

Centropages furcatus 

C. tenuremis 

Labidocera sp 

Pontellina 

Paracanadica truncata 

Lucicutia sp 

L. flavicormis 

L. gaussae 

Bestiulina similis 

Delius nudus 

Euchata marina 


Table 1. Abundance of copepod species (ind. m־³) in monsoonal seasons in Chabahar Bay. 

SW .m 

1125.62 

2782.11 

56.1676 

579.69 

189.02 

600.52 

1230.81 

2152.94 

2479.67 

1374.52 

1219.27 

89.43 

677.3 

- 

221.32 

- 

87 

231.25 

41.03 

85.10 

44.07 

44.07 

644.97 

47.60 

187.56 

205.66 

- 

- 

- 

600.52 

45.30 

- 

47.60 

136.03 

- 

- 

690.54 

27518.82 

- 

- 

- 

- 

- 

- 

- 

- 

post. m 

2830. 62 

4162.53 

1701.56 

540.17 

140.55 

1350.36 

339.7 

61.54 

187.59 

87.90 

541.49 

1584.75 

5698.92 

299.07 

626.23 

210.12 

- 

133.25 

- 

49.84 

- 

- 

- 

- 

277.50 

389.75 

- 

110.42 

- 

- 

42.60 

63.06 

55 

- 

- 

- 

384.41 

84.49 

90. 115 

- 

- 

20.51 

22.04 

- 

- 

- 

NE. m 

255 .24 

1558.07 

160 

165 

125 

- 

222.22 

630.48 

246.96 

316.75 

525.71 

40 

9291.32 

- 

1004.45 

- 

31.75 

31.75 

40 

- 

- 

- 

- 

- 

111.11 

236.11 

430.58 

766.96 

285 

- 

31.75 

4994.04 

589.21 

713.22 

9441.95 

375.24 

- 

191 / 11 

31 / 75 

- 

- 

- 

- 

31.75 

pre.m 

548.34 

516.59 

47.418 

- 

87.129 

288.60 

- 

- 

- 

259.74 

412.67 

- 

5717.78 

- 

- 

- 

- 

- 

- 

- 

- 

- 

- 

- 

225.11 

- 

- 

- 

- 

- 

- 

- 

299.32 

- 

- 

839 

- 

- 

- 

- 

- 

- 

130 

127 

- 

161

162 

Oithona oculata 

O. attenuata 

O.nana 

O. bremicornis 

O.simplex 

O. rigida 

O.plumifera 

O. sp 

O.fallax 

Corycaus pacificus 

C. andrewsi 

C. asiaticus 

C. erythraeus 

C. sp 

C. affinis 

C. dahli 

C. speciosus 

Oncea media 

O. venusta 

O. clevei 

O. minuta 

Sapphirina sp 

S. gastrica 

S. nigromoculata 

Clytemnestra scutellata 

Macrosetlla gracilis 

Microsetella rosea 

Euterpina acutifrons 

Monstrilloida 


1952.91 

3600.99 

3551.84 

336.41 

1343.38 

3883.92 

45.35 

5270.54 

- 

194.72 

1005.18 

321.52 

90.52 

725.13 

- 

- 

- 

608.28 

703 

417.74 

44.07 

- 

- 

- 

- 

302.14 

172.92 

4058.41 

- 

1742.31 

2762.99 

5254.90 

2496.91 

5624.04 

1913.12 

1058.42 

5911.14 

- 

311.33 

659.05 

279.52 

2013 

390.30 

243.68 

384.77 

65.86 

3626.43 

1860.83 

1174.20 

670.01 

- 

44.35 

45.35 

123.08 

2375.38 

280.86 

8791.82 

105.17 

1558.78 

1891.85 

10203.44 

3761.27 

750.95 

1284.20 

591.11 

5735.79 

31.75 

166.98 

1528.07 

236.11 

267.86 

166.96 

125 

361.11 

220.24 

2907.78 

634.20 

160 

- 

331.35 

- 

- 

1227.88 

753.49 

366.96 

4831.53 

Table 2. Pearson correlation of major environmental parameters and copepoda density 

Variables Chl-a Temperature Salinity DO SiO3 NO3 PO4 

Copepod 

density 

Chl- a 

0.05 

-0.26 

-0.08 

1.00 -0.38 0.06 0.33 0.05 0.05 0.93** 

0.20 

(‘*’ significant at 0.05 level; ‘**’ significant at 0.01 level). 

- 

- 

- 

- 

1619.05 

965.99 

6323.23 

1238.10 

761.90 

1111.11 

894.66 

7163.06 

- 

- 

5125.54 

1910.13 

- 

285.71 

331.07 

- 

- 

- 

259.74 

- 

387.72 

- 

- 

- 

704.81 

14286.96 

8116.86 

10440.73 

-


Table 3. Diversity index (H') and species richness (D) of Copepoda in monsoonal seasons. 

Stations SW .m post .m NE .m pre. m 

1 

2 

3 

4 

5 

Mean 

3.09 (4.10) 3.03 (4.59) 2.89 (4.39) 2.52 (1.65) 

3.41 (4.11) 3.34 (4.23) 2.67 (2.40) 2.47 (1.90) 

2.40 (1.35) 2.62 (2.99) 2.19 (1.44) 1.96 (1.57) 

2.73 (3.13) 2.85 (3.58) 2.88 (2.97) 2.14 (1.84) 

1.15 (1.71) 2.33 (1.79) 2.54 (2.55) 1.93 (1.04) 

2.55 (2.88) 2.83 (3.43) 2.63 (2.75) 2.20 (1.60) 

Number species 50 58 57 33 

abundance (after a time lag) and associated phosphate 

concentrations during pre-monsoon. 

Acknowledgements 

We wish to thank Dr. Irina Prusova for guide and 

Iranian National Center of Oceanography for the 

encouragement and support. The study was supported by 

Khorramshahr University of Marine Science. 

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Sciences, Santa Cruz, CA 96063, ETATS-UNIS, pp. 487-520. 

Williams R Conway DV and Hunt HG. 1994. The role of 

copepods in the planktonic ecosystems of mixed and stratified 

waters of the European shelf seas. Hydroboil. 292: 521-530. 

Zareei A. 1994. The case study of Hydrology and Hydrobiology 

of the Goatr strait. Proceedings of the 2nd marine conference. 

University of Shahid Chmran. Ahvaz, Iran.

JJBS 



ISSN 1995-6673 

Pages 165 - 174 

Nandrolone Decanoate Administration to Male Rats Induces 

Oxidative Stress, Seminiferous Tubules Abnormalities, and 

Sperm DNA Fragmentation 

Lubna H. Tahtamouni a,* , Noor H. Mustafa a , Iman M. Hassan a , Iman M. Ahmad b , 

Salem R. Yasin a , Maher Y. Abdalla a,c 

a Deptartment of Biology and Biotechnology, b Deptartment of Radiography, The Hashemite University, P.O. Box 150459, Zarqa 13115, 

Jordan; c Vaccine Branch, Center for Cancer Research, National Cancer Institute, National Naval Medical Center, Bldg. 8, Rm. 4155, 8901 

Wisconsin Ave. Bethesda, MD, USA 


The present study was conducted to evaluate the effects 

of Nandrolone Decanoate (an anabolic steroid) on the 

level of oxidative stress markers, sperm chromatin 

integrity, seminiferous tubules structure, and 

spermatogonia/Sertoli cell ratio in adult rat. Rats were 

divided into three groups: control, low (3mg/Kg) and 

high-dose (10mg/Kg) Nandrolone Decanoate-receiving 

groups. Seminal fluid analysis was performed, and the 

serum was used to evaluate testosterone level. Testicular 

oxidative stress markers were measured and routine 

histological preparation and androgen receptor 

immunochemistry was used to evaluate the effects of 

Nandrolone Decanoate injection on seminiferous tubules. 

Injection of Nandrolone Decanoate caused an increase in 

the production of thiobarbituric acid-reactive substances 

in the testes of treated rats. The level of sperm DNA 

fragmentation and the percentage of seminiferous tubules 

showing maturation arrest were also increased in treated 

animals. The absolute numbers of spermatogonia and 

Sertoli cells in the rats receiving Nandrolone Decanoate 

decreased significantly; however, the ratio of 

spermatogonia/Sertoli cells did not. Administration of 

anabolic steroids at supraphysiological doses leads to 

multiple pathological changes in the reproductive system 

of treated rats. Testosterone or its derivatives such as 

Nandrolone Decanoate are being abused commonly. 

Athletes, coaches, and physicians should be aware of 

their harmful side effects. 

Nandrolone Decanoate ﻦﻘﺣ رﺎﺛﺁ ﻢﻴﻴﻘﺗ ﻰﻟإ ﺔﻴﻟﺎﺤﻟا ﺔﺳارﺪﻟا فﺪﻬﺗ 

،ﻲﻨﻴﺠﻴﺴآوﻻا ﺪﻬﺠﻟا ىﻮﺘﺴﻣ ﻰﻠﻋ ( ﺔﻴﺋﺎﻨﺒﻟا تاﺪﻳوﺮﻴﺘﺴﻟا ﻦﻣ ﺪﺣاو) 

ﺐﻴﺑﺎﻧﻷا تﺎﻧﻮﻜﻣو ﻞﻜﺷ و ،ﺔﻳﻮﻨﻤﻟا 

تﺎﻧاﻮﻴﺤﻠﻟ 

ﺔﻴﺛارﻮﻟا ةدﺎﻤﻟا ﺔﻣﻼﺳو 

( ﻲﻟﻮﺗﺮﺳ ﺎﻳﻼﺧ) 

ةﺪﻋﺎﺴﻤﻟا 

ﺎﻳﻼﺨﻠﻟ مﻷا ﺔﻳﻮﻨﻤﻟا ﺎﻳﻼﺨﻟا ﺔﺒﺴﻧو ،ﺔﻳﻮﻨﻤﻟا 

: تﺎﻋﻮﻤﺠﻣ ﺔﺛﻼﺛ ﻰﻟإ ناذﺮﺠﻟا ﻢﻴﺴﻘﺗ ﻢﺗ . ﺎﻬﻨﻘﺣ ﻢﺗ ﻲﺘﻟا ناذﺮﺠﻟا ﻲﻓ 

Decanoate ﻦﻣ ﻲﻧﺪﺘﻣ ﺰﻴآﺮﺘﺑ ﺖﻨﻘﺣ ﺔﻋﻮﻤﺠﻣ و ﻂﺒﻀﻟا ﺔﻋﻮﻤﺠﻣ 

ﻲﻟﺎﻋ ﺰﻴآﺮﺘﺑ ﺖﻨﻘﺣ ﺔﻋﻮﻤﺠﻣ و ( ﻢﻐآ/ 

ﺞﻣ3) 

Nandrolone 

ﺐآﺮﻤﻟ طﺮﻔﻤﻟا ماﺪﺨﺘﺳﻹا 

نأ ﻰﻟإ ﺔﺳارﺪﻟا ﺖﻠﺻﻮﺗ .( ﻢﻐآ/ 

ﺞﻣ10) 

تﺎﻧاﻮﻴﺤﻠﻟ 

يوﻮﻨﻟا ﺾﻤﺤﻟا 

دﺎﺴﻓإ ﻰﻟإ ىدأ Nandrolone Decanoate 

. ﺔﻔﻠﺘﺨﻣ ﻞﺣاﺮﻣ ﻲﻓ ﺔﻳﻮﻨﻤﻟا تﺎﻧاﻮﻴﺤﻟا ﻦﻳﻮﻜﺗ ﺔﻴﻠﻤﻋ فﺎﻘﻳإ 

ﻰﻟإ و ﺔﻳﻮﻨﻤﻟا 

،ﻲﻟﻮﺗﺮﺳ ﺎﻳﻼﺧ ﻰﻟإ مﻷا ﺔﻳﻮﻨﻤﻟا ﺎﻳﻼﺨﻟا ﺔﺒﺴﻧ ﻲﻓ ﺮﻴﻴﻐﺗ يأ ثﺪﺤﻳ ﻢﻟو 

،ﻚﻟذ ﻰﻟإ ﺔﻓﺎﺿﻹﺎﺑو . ﺮﻴﺒآ ﻞﻜﺸﺑ َﻞﻗ ﺎﻳﻼﺨﻟا ﻩﺬﻬﻟ ﻖﻠﻄﻤﻟا دﺪﻌﻟا ﻦﻜﻟو 

Acid جﺎﺘﻧإ ةدﺎﻳز ﻲﻓ ﺐﺒﺴﺗ ﺔﻴﺋﺎﻨﺒﻟا 

تاﺪﻳوﺮﻴﺘﺴﻟا ﻦﻘﺣ 

ﺔﻴﺼﺧ ﻲﻓ GSH ىﻮﺘﺴﻣ ﻲﻓ ﺮﻴﻴﻐﺗ يأ ثوﺪﺣ نود Thiobarbituric 

لﺎﻤﻌﺘﺳا ةءﺎﺳإ نإ . Nandrolone Decanoate ب ﺖﻨﻘﺣ ﻲﺘﻟا ﻦﻳذاﺮﺠﻟا 

ﺔﻣﺎﻌﻟا ﺔﺤﺼﻟا لﺎﺠﻣ ﻲﻓ ﺔﻴﺳﺎﺳأ ﺔﻠﻜﺸﻣ ﺢﺒﺼﺗ تأﺪﺑ ﺔﻴﺋﺎﻨﺒﻟا تاﺪﻳوﺮﻴﺘﺴﻟا 

ﻦﻴﻘهاﺮﻤﻟا 

ﺮﻳﺬﺤﺗو ﺔﻴﻋﻮﺘﻟ 

ﺔﻴﻤﻴﻠﻌﺘﻟا ﺞﻣاﺮﺒﻟا ﺬﻴﻔﻨﺗ ةروﺮﺿ ﻲﻨﻌﻳ ﺎﻣ ﻮهو 

تارﺎﻘﻌﻟا ﻩﺬﻬﻟ ﺔﻴﺒﻠﺴﻟاو 

ﺔﻴﺒﻧﺎﺠﻟا رﺎﺛﻵا ﻦﻋ ءاﻮﺳ ﺪﺣ ﻰﻠﻋ ﻦﻳﺪﺷﺮﻤﻟاو 

. ﺎﻬﻴﻣﺪﺨﺘﺴﻣ ﺔﺤﺻ ﻰﻠﻋ 

Keywords: Germinal Epithelium, TBARS, Glutathione, Anabolic Steroids, Sertoli Cells, Androgen Receptor. 


Anabolic-androgenic steroids (AAS) are synthetic 

compounds which are based on the structure of 

testosterone, and are used to treat various conditions such 

* Corresponding author. lubnatahtamuni@hu.edu.jo. 


as reproductive system dysfunction, breast cancer and 

anemia (Thiblin and Petersson, 2005). Three basic 

modifications are made to the structure of testosterone to 

enhance deliverability and potency and slow down rate of 

degradation. The first of these modifications (class I) 

involves esterification of testosterone at the 17-β-hydroxy 

location (Hall and Hall, 2005). This modification, which is 

made to injectable AAS, slows down degradation but 

enhances androgenic properties (Hall and Hall, 2005).

166 


Nandrolone Decanoate (ND) is a class I AAS. The second 

modification (class II) results from alkylation at the 17-αhydroxy 

position, which depresses hepatic degradation 

(Wilson, 1988). The third modification (class III) has been 

used to generate together oral and injectable formulations. 

One pattern of class III modifications results in an AAS 

with analogous properties to that of Class II AAS, but with 

a decreased or missing hepatic effect (Wilson, 1988; Hall 

and Hall, 2005). 

AAS are taken by abusing athletes at 

supraphysiological doses; such doses are usually 10 to 100 

fold the recommended therapeutic dose (Clark et al., 

1997). Traditionally, AAS have been abused in drug-use 

cycles of 6-14 weeks followed by a drug-free period to 

prevent building up tolerance to AAS (Karila et al., 2004). 

Defining the exact adverse effects of AAS abuse is 

very hard due to the lack of clinical trials which mimics 

AAS abuse by athletes (Hall and Hall, 2005). In addition, 

almost all major tissues in the body have androgen 

receptors, and thus AAS abuse affects almost all body 

systems (Karila et al., 2004). Side effects of AAS abuse 

include liver failure, acne, a decrease in high-density 

lipoprotein (HDL) levels and hepatic adenomas (Boyadjiev 

et al, 2000; Hall and Hall, 2005), mood fluctuation, 

aggressive behavior, violence and suicide attempts (Clark 

et al., 1997). 

One of the most pronounced effects of AAS abuse is 

the negative impact on the hypothalamus-pituitary-gonadal 

axis (Takahashi et al., 2004). In men abusing AAS, there 

is a noticeable reduction of serum testosterone level as 

well as FSH and LH (Jarow and Lipshultz, 1990). 

In addition, AAS abuse has been linked to reduced quality 

and quantity of semen which could be related to infertility 

(Torres-Calleja et al., 2001). Long-term AAS 

administration results in reduction in testicular weight, 

testicular atrophy and abnormal morphology (Jarow and 

Lipshultz, 1990). 

Although many studies have investigated the effects of 

testosterone suppression on spermatogenesis through 

sperm output evaluation (Torres-Calleja et al., 

2001), there are no reports on the effects of AAS abuse 

and thus testosterone suppression on Sertoli cells number 

and function, structural changes of the testis or sperm 

chromatin integrity. Hence, this work was conducted to 

evaluate the effects of administration of ND at 

supraphysiological doses on oxidative stress biomarkers 

and male reproductive system. 

2. Experimental Procedure 

2.1. Animals and treatments 

Animal care, handling, and all of the experiments 

performed were approved by the Hashemite University 

Institutional Animal Care and Use Committee. 

Forty-five adult Wister male rats (Rattus norvegicus), 

weighing between 150–300g (three to four months old), 

were randomly selected from the laboratory animal center 

at The Hashemite University (Zarqa-Jordan). The animals 

were housed individually in an air-conditioned room (12 hr 

dark/12 hr light) at 23 ± 2 ºC, and had free access to tap 

water and standard food pellet. After one week of 

acclimatization, the 45 animals were randomly divided 

into three groups of 15 each: Group 1 (control), receiving 

10 mg/kg/wk of the vehicle peanut oil, Group 2 (low 

dose), receiving 3 mg/kg/wk of ND (N.V. Organon Oss 

Holland), and Group 3 (high dose), receiving 10 mg/kg 

/wk of ND Treatments were administered weekly via 

intramuscular injection (0.1ml) for 14 weeks. The doses of 

ND administered to rats and period of administration 

mimics one cycle of AAS abuse by athletes (Hall and Hall, 

2005; Mirkhani et al., 2005; Trenton and Currier, 2005). 

2.2. Sample collection and processing 

One week after the final drug administration, body 

weight was measured and the rats were killed rapidly 

under ether anesthesia followed by cervical dislocation. 

The following samples were collected and processed: 

2.2.1. Serum 

Blood was collected via heart puncture, centrifuged at 

2,000 rpm for 10 min and the supernatant (serum) was 

stored at -20ºC. The serum was used to measure total 

serum testosterone which was determined using AxSYM 

® Testosterone test (Abbott, USA). The test is based on 

Micropar t ical Enzyme Immunoassay (MEIA) technology 

for the quant itat ive determinat ion of total testosterone in 

serum (Gonzalez-Sagrado et al., 2000) . 

2.2.2. Sperm suspension 

The left vas deferens of the rats from the three different 

groups was exposed and 1 cm of its distal portion was 

removed. The diffusion method was used to collect semen 

(Seed et al., 1996). Sperm suspension was used to 

calculate sperm count and motility. Sperm samples were 

collected from distal region (cauda) of the left epididymis 

(Syntin and Robaire, 2001) and were used for evaluation 

of sperm morphology and chromatin integrity by acridine 

orange staining. For sperm morphology analysis, 20 µl of 

sperm suspension were smeared, air dried and stained with 

hematoxylin and eosin (H&E). 200 sperm per sample were 

evaluated for normal and abnormal sperm forms [such as 

angulated (bent) sperm, broken sperm (i.e., headless, 

tailless), short sperm, and coiled-tailed sperm]. Sperm 

DNA fragmentation was evaluated by acridine orange 

staining which was performed according to the method of 

Tejada et al. (1984) and Chohan et al. (2004). An average 

of 200 sperm cells was counted on each slide by the same 

examiner. Upon excitation, the monomeric acridine orange 

bound to double-stranded DNA fluoresces green. The 

aggregated acridine orange on single-stranded DNA 

fluoresce a spectrum of yellow-orange to red (Chohan et 

al., 2004). 

2.2.3. Right testis 

The right testis was removed and cut in half. The first 

half was used to measure oxidative stress markers. Lipid 

peroxidation products were quant ified by the 

thiobarbituric acid (TBA) method (Ohkawa et al., 1979) 

and expressed as Thiobarbituric Acid-Reactive Substances 

(TBARS) Levels (nmoles/g protein). Total glutathione 

content (GSH) and oxidized glutathione (GSSG) were 

determined by the method of Anderson (1985) and the 

results were expressed as nmoles of GSH or GSSG/mg 

protein. 

The second half of the right testis was used to analyse 

the effects of ND on the expression of androgen receptor


by immunoblotting. Briefly, the tissues were washed with 

cold PBS and then immersed in lysis buffer (10 mM Tris- 

HCl pH 7.5, 10 mM NaF, 2% SDS, 5 mM DTT, 2 mM 

EGTA). Equivalent amounts of protein were resolved by 

SDS-PAGE on 7.5% gel, transferred to nitrocellulose 

membrane and immunoblotted with rabbit polyclonal antiandrogen 

receptor (AR) primary antibody (1:2,000) 

(Sigma, USA). Blots are representative of at least two 

independent experiments. Left testis 

The left testis was removed and weighed. The volume 

of testis prior to fixation was estimated using the 

immersion method (Plethysmometer, Ugo Basile, Italy). 

The tissue was fixed in 10 % neutral formalin fixative and 

embedded in paraffin. The tissue was then used either for 

routine H&E staining or for androgen receptor 

immunochemistry. 

To study the process of spermatogenesis and on the 

basis of standard qualitative interpretation of H&E 

staining, testis sections were classified as follows: (i) 

Normal histology: almost all tubules showing elongating 

spermatids in each cross section, (ii) Early maturation 

arrest of spermatogenesis (EMA): most tubules showing 

spermatogenesis arrest at the level of primary of 

spermatocyte, with spermatids never observed, and (iii) 

Late maturation arrest (LMA) of spermatogenesis: most 

tubules showing spermatogenesis with only round 

spermatids being observed. 

In order to determine the spermatogenic capacity of the 

male rat, the number of spermatogonia supported by one 

Sertoli cell was counted. Sertoli cells were identified by 

positive staining with rabbit polyclonal anti-androgen 

receptor (AR) primary antibody (1:200) (Sigma, USA). 

The primary/secondary antibody reaction was detected 

using high sensitivity streptavidin conjugated to 

horseradish peroxidase (HSS-HRP) and revealed by 3, 3 

diaminobenzidine (DAB) chromogen. The sections were 

counterstained with Mayer’s hematoxylin. A total of five 

seminiferous tubules per animal were randomly selected, 

and the number of spermatogonia and Sertoli cells were 

counted (Watanabe, 2005). All histological observations 

were carried out using bright field microscope (Nikon 

E800, Japan). 


All samples were processed individually and measured 

in triplicate in the same assay. Data are stated as mean ± 

Standard Error of the Mean (SEM).When appropriate, data 

were analyzed by a one-way ANOVA test. A significant 

level of 0.05 was considered appropriate. 

3. Results 

The effects of ND administration on several parameters 

of serum, testis, and semen in male rats were investigated. 

3.1. Effect of ND administration on body weight 

The body weight for all animals in the three groups was 

measured before and after treatments (Fig. 1). After 14 

weeks, the final body weight of animals in the three groups 

was not significantly different as compared to their weight 

at the beginning of the study, but the rate of weight gain 

was more in the control group; although not significant 

(p=0.582). 

167 

3.2. Effects of ND administration on testosterone level 

Measuring total testosterone level in the serum of the 

control and treated groups indicated that injection of ND 

caused a significant decrease in testosterone level in both 

the low (5.3 ± 3.7 pg/ml) and the high-dose (60.1 ± 19.3 

pg/ml) ND receiving groups (p=0.001) as compared to the 

control group (633.3 ± 210.1 pg/ml). 

3.3. Effects of ND administration on sperm characteristics 

The average sperm concentration of both groups 

receiving low (31.4 ± 5.9x10 6 /ml) and high (44.7 ± 

5.9x10 6 /ml) doses of ND was significantly decreased as 

compared to that of the control group (116.0 ± 1.1 

x10 6 /ml) (p=0.001). 78.1 ± 2.7% of sperm extracted from 

the vas deferens of rats in the control group showed 

progressive forward motility. In contrast, treatment of rats 

with the low and high doses of ND caused a significant 

decrease (p=0.001) in the percentage of progressively 

motile sperm (39.2 ± 4.1% and 19.4 ± 3.1%, respectively). 

The percentage of sperm with normal morphology was 

statistically decreased (p=0.001) in the low-and high-dose 

receiving groups (61.8 ± 4.7% and 59.4 ± 5.0%, 

respectively) as compared to the control group (92.9 ± 

1.1%). 

The effect of ND administration on sperm chromatin 

integrity was evaluated by acridine orange staining. 200 

sperm per slide were counted, and the percentage of sperm 

with single-strand DNA (Red, yellow-orange/total x 100) 

was calculated (Fig. 2A). The percentage of sperm with 

defected DNA was significantly increased in the treated 

rats receiving low and high doses of ND (72.3% and 

53.3%, respectively) as compared to the control group 

(19.7%) (p=0.001) (Fig. 2B). 

3.4. Effects of ND administration on testes 

The volume of the testes decreased significantly in 

animals which received low (0.81 ± 0.14 ml) and high 

doses (0.93 ± 0.02 ml) (p=0.001) of ND in comparison 

with the animals in the control group (1.78 ± 0.04 ml). 

Injection of ND caused a significant increase in 

TBARS production in the testis of both the low and the 

high-dose receiving groups as compared to the control 

group (p=0.001) (Fig. 3). On the other hand, the testicular 

levels of both total glutathione (GSH) and oxidized 

glutathione (GSSG) were not significantly different 

(p=0.519 and 0.551, respectively) between treated and 

untreated groups (Table 1). 

Table 1. Effect of Nandrolone Decanoate administration on 

testicular glutathione levels. Values are expressed as means ± 

SEM (n in each group=3-6) 

Group 

Total GSH (nmoles/mg 

protein) 

GSSG (nmoles/mg 

protein) 

Control 18.9 ± 1.2 2.4 ± 0.15 

Low Dose 21.1 ± 2.3 2.1 ± 0.09 

High Dose 19.3 ± 2.1 2.9 ± 0.35

168 


Figure 1. Effect of Nandrolone Decanoate administration on body weight. Body weight is expressed as (final body weight – initial body 

weight /initial body weight ×100). n=15 in each group. 

Figure 2. Effect of Nandrolone Decanoate administration on sperm chromatin integrity. A) Acridine orange test applied to rat sperm 

showing a sperm with intact chromatin (green) and a sperm with damaged chromatin (yellow-orange), B) The percentage of sperm with 

abnormal chromatin integrity was higher in treated groups as compared to the control group. (Values are expressed as mean ± SEM, n =15 

in each group, *p=0.001). 

Figure 3. Effect of Nandrolone Decanoate administration on testicular TBARS levels. Both low and high-dose receiving groups had a 

higher level of TBARS as compared to the control group. (Values are expressed as mean ± SEM, n = 6-9 in each group, *p=0.001).


After analyzing different cross sections of testes of 

control and treated animals, obvious differences were 

noted. One of these differences was atrophy (low number 

of germ cells) in the seminiferous tubules (ST) of treated 

rats (receiving low or high doses of ND) with large focal 

areas, and a noticeable decreased accumulation of 

spermatozoa within the lumen (hypospermatogenesis) 

(Fig. 4B) as compared to ST of control rats (Fig. 4A). 

169 

Also, some ST in the testes of treated rats showed 

abnormal architecture of the seminiferous epithelium (Fig. 

4C), and maturation arrest (early or late) (Fig. 4D and E, 

respectively). In addition to the abnormal patterns of 

spermatogenesis mentioned, normal seminiferous tubules 

were also found in cross sections of testes of treated rats. 

A summary of spermatogenesis patterns in control and 

treated rats is shown in Table (2). 

Figure 4. Histological appearance of representative examples of seminiferous tubules (ST) of control and treated rats stained with 

hematoxylin and eosin. A) A cross section of ST from control rat showing normal architecture of germinal epithelium, i.e., multiple layers 

of germ cells ranging from spermatogonia, 1 o spermatocytes, 2 o spermatocytes, round and elongated spermatids and sperm in the lumen, B) 

A cross section of ST from a low-dose treated rat displaying atrophic germinal epithelium (2-3 layers of germ cells) and almost lacking 

sperm in the lumen, C) A cross section of ST from a low-dose treated rat showing abnormal organization of the germinal epithelium, D) A 

cross section of ST from a low-dose treated rat showing early maturation arrest in which germ cells differentiation stops at 1 o spermatocytes, 

E) A cross section of ST from a high-dose treated rat displaying round spermatids as the last stage of germ cell differentiation (late 

maturation arrest). Scale bar = 50 µm.

170 


Table 2. Different patterns of spermatogenesis observed in control and N a n d ro lone Decan o ate -receiving rats. Values represents 

mean of percentages ± SEM, n in each group=7, *: p=0.001 

Group 

% of ST showing maturation Arrest 

% of ST showing normal 

spermatogenesis Early Late 

% of ST showing hypo- 

spermatogenesis 

Control 94.1 ± 0.26 4.3 ± 0.3 1.2 ± 0.1 0.4 ± 0.3 

Low Dose 21.1 ±1.2 * 44.3 ± 1.2 * 20.7 ± 1.8 * 13.9 ± 1.5 * 

High Dose 20.7 ± 2.1 * 30.0 ± 1.1 * 33.7 ± 1.8 * 15.6 ± 1.2 * 

Finally, we examined the pathological changes that 

might have occurred to spermatogonia and Sertoli cells in 

the testes of treated rats. Immunohistochemical 

localization of AR expression within seminiferous tubules 

was restricted to nuclei of Sertoli cells (Fig. 5A). 

Spermatogonia in seminiferous tubules of control rats were 

closely packed and the nuclei were darkly-stained, and the 

nuclei of Sertoli cells were located regularly in the 

periphery of the tubules (Fig. 5A). Seminiferous tubules 

of treated rats (receiving either low or high doses of ND) 

showed abnormal organization of spermatogenic cells 

(Fig. 5B), and the number of layers of germ cells was 

reduced. In addition, the morphology, nuclear size and 

position of Sertoli cells were changed in the STs of treated 

rats (Figure 5B). The number of spermatogonia in the 

testes of rats in both low and high-dose receiving groups 

was significantly decreased as compared to the control 

(p=0.001) (Fig. 5C). In addition, there were fewer Sertoli 

cells in the seminiferous tubules of ND-treated animals 

than in those of the control rats (p=0.001) (Fig. 5C), which 

was confirmed by analyzing the level of AR expression by 

immunoblotting of extracted testicular proteins (Fig. 5D). 

Quantification of normalized AR levels in treated animals 

relative to that of controls (lane 1,2) revealed that extracts 

from both low- (lane 3) and high-dose receiving groups 

(lane 4) showed a reduction (32% and 47%, respectively) 

in AR expression as compared to extracts of control 

animals (Fig. 5D). However, the ratio of spermatogonia to 

Sertoli cells in the treated rats was not significantly 

different from that of the control group (p=0.287). 

4. Discussion 

One of the most prominent effects of AAS is the 

negative impact on the pituitary-gonadal axis (Aubert et 

al., 1985; Takahashi et al., 2004).AAS stimulates 

hypogonadotrophic hypogonadism coupled with decreased 

serum testosterone concentrations (Harkness et al., 1975; 

Schurmeyer et al., 1984; Jarow and Lipshultz, 19908). In 

the current study, total serum testosterone level in treated 

rats was lower than in control animals, which is in accord 

with what was previously reported. 

The dysfunction accounting for these abnormalities is 

supposed to be steroid-induced suppression of 

gonadotrophin production; it was reported that there is a 

noticeable depression of serum FSH and LH in men 

abusing AAS (Harkness et al., 1975; Clerico et al., 1981). 

This in turn results in a condition of impaired 

spermatogenesis including oligozoospermia to 

azoospermia, abnormalities of sperm motility and 

morphology (Ramaswamy et al., 2000; Torres-Calleja et 

al., 2001; Takahashi et al., 2004). Suppression of sperm 

output is attributed to the degree of inhibition of germ cell 

development which is related to the degree of FSH, LH 

and testosterone suppression (O'Donnell et al., 2001). This 

could explain decreased sperm concentration, motility and 

normal morphology induced by long-term ND 

administration to rats. Also, it could explain the maturation 

arrest noted in the ST of treated rats (Table 2). 

Since little information is available on the effects of 17β-alkylated 

steroid treatment on oxidative stress markers, 

we aimed to investigate whether prolonged treatment of 

rats with low or high doses of ND modified oxidative 

stress markers through studying TBARS production as a 

result of lipid peroxidation and redox status of glutathione 

(GSH). Figure 3 shows that prolonged administration of 

ND induced a significant increase (p=0.001) in TBARS 

levels which serves as an index of extended lipid 

peroxidation. However, this treatment did not modify 

testicular levels of GSH in treated rats (Table 1). To our 

knowledge, this is the first time that the effects of ND 

treatment on oxidative stress biomarker levels have been 

studied. AAS seek to maximize the anabolic effects and 

overcome the catabolic pathways thus increasing anabolic 

pathways, so the possibility of oxidative stress condition 

could increase (Saborido et al., 1993; Molano et al., 1997). 

It was shown previously that prolonged administration 

of Stanazolol (17-α-alkylated AAS) provoked dysfunction 

of the mitochondria respiratory chain complexes and 

mono-oxygenase systems; it would be possible that these 

alterations were accompanied by an increased reactive 

oxygen species (ROS) generation (Saborido et al., 1993; 

Molano et al., 1997; Pey et al., 2003). 

One more supposed source of free radicals generation 

is cytochrome P450 cholesterol side-chain cleavage 

enzyme isoforms of the steroidogenic pathway during their 

catalytic cycles, these isoforms have been shown to release 

ROS under basal conditions especially with uncoupled 

substrates (Chang et al., 1995). Consequently, metabolism 

of high doses of ND by cytochrome P450 monooxygenases 

would have increased greatly the production of 

ROS resulting in a state of oxidative stress and upregulation 

of the activity of the antioxidant enzymes such 

as SOD and glutathione peroxidase (GPx), gluthatione 

reductase (GR) and catalase (Georgiou et al., 1987; 

Diemer et al., 2003; Pey et al., 2003; Chen et al., 2005). 

However, the mechanism through which the intramuscular 

injection of ND could be associated with free radical 

production is unidentified at present. 

On the other hand, there was no change on GSH level 

(Table 1), which might be due to the body using other 

antioxidant defense mechanisms such as the activities of


Figure 5. Effect of Nandrolone Decanoate administration on spermatogonia and Sertoli cells. A) A representative example of a cross section 

of a ST from control rat immunostained for androgen receptor, the outermost layer shows darkly stained spermatogonia and evenly placed 

Sertoli cells (arrow), B) A representative example of a cross section in ST of a low-dose treated rat immunostained for androgen receptor, 

showing reduced number of germ cells, and misplaced Sertoli cells. Scale bar = 50 µm. C) The number of spermatogonia and Sertoli cells 

in the ST of treated rats was significantly reduced as compared to the control group, values are expressed as mean ± SEM, n=5, *p=0.001, 

D) Immunoblot analysis for AR levels. Testis lysates from control (lanes1, 2), low (lane 3) and high-dose receiving rats (lane 4) where 

immunoblotted with anti-AR antibody. 

several scavenging enzymes [SOD, GPx, GR, catalase and 

hemoxygenase-1 (HO-1)] (Georgiou et al., 1987; Diemer 

et al., 2003; Chen et al., 2005). 

To our knowledge there is no available data that 

evaluates the effect of ND on sperm chromatin integrity. 

Sperm DNA fragmentation could be due to several reasons 

such as deficiency in recombination during 

spermatogenesis (Bannister and Schimenti, 2004). 

Exposure of mature spermatozoa to excessive levels of 

ROS produced by immature sperm during migration from 

the seminiferous tubules to the epididymis could also lead 

to fragmented DNA (Ollero et al., 2001). In addition, 

abnormal spermatid maturation could result in DNAfragmented 

sperm. 

Around 80-90% of the weight of each testis consists of 

tightly packed ST (Greenspan and Gardner, 1994). The 

major supporters of spermatogenesis process are the 

Sertoli cells which take up a volume of around 17–19% of 

the seminiferous tubules of adult rats. Sertoli cells are the 

only somatic cells in direct connection to germ cells (Mruk 

and Yan, 2004). 

171 

Androgen action in the testis, as in other tissues, is 

mediated through androgen receptor (AR) transcriptional 

activation (Bremner et al., 1994). Inside Sertoli cells, 

testosterone is selectively bound to the androgen receptor 

and activation of the receptor will result in initiation and 

maintenance of the spermatogenic process and inhibition 

of germ cell apoptosis (Dohle et al., 2003). In testes, ARs 

are expressed in the somatic Leydig, peritubular myoid 

and Sertoli cells as well as to rete testis, the epithelial cells 

of the epididymis, and prostate (Vornberger et al., 1994; 

Bilinska et al., 2005). 

AR expression is maintained by endogenous testicular 

androgens; withdrawal of testosterone is known to lead to 

disruption of spermatogenesis (Kerr et al., 1985). After 

long-term hypophysectomy and elimination of residual 

testosterone, spermatogenesis rarely proceeds beyond 

meiosis, with very few round spermatids observed and 

elongated spermatids nearly non-existing (Franca et al., 

1998). In the current work, injection of male rats with low 

or high doses of ND resulted in reduction of testosterone, 

which caused maturation arrest at the primary

172 


spermatocyte level (Fig.4D), and at the spermatid level 

(Fig.4E). 

In addition, it was found that loss of AR activity from 

Sertoli cells would lead to spermatogenic failure resulting 

in incomplete meiosis and collapse to transition of 

spermatocytes to haploid round spermatids (Birgner et al., 

2008; Holdcraft and Braun, 2008).In the current study, the 

immunoexpression of AR was scored as the number of 

positive nuclei within the boundaries of STs (Fig. 5A) and 

by immunoblotting (5D), and it was found that NDadministration 

caused a reduction in the number of Sertoli 

cells expressing AR (Fig.5C), which in turn could explain 

the maturation arrest observed in treated animals (Table 2) 

and testicular atrophy (Fig.4B). 

Sertoli cells play an important role in organizing the 

somatic cell lineages and in determining the structure of 

the testis (McLaren, 2000); they also support a finite 

number of germ cells, and thus their number determines 

the spermatogenic capacity of the adult (Orth et al., 1988; 

Sharpe, 1994; McLachlan et al., 1996). Our results 

indicate an AAS-induced reduction in Sertoli cell number 

(Fig.5C) which might be due to a structural response of 

Sertoli cells to deprivation of testosterone (Watanabe, 

2005). The reduction in Sertoli cell number in treated rats 

could have resulted in a subsequent reduction in the 

number of spermatogonia (Fig.5C) leading eventually to a 

decrease in sperm count. 

There are no reports on the effects of testosterone 

suppression on spermatogonia cell differentiation. In 

addition, the quantitative structural changes of the testis 

caused by AAS abuse received little or no attention. The 

current study reports a number of abnormalities in the 

architecture of the seminiferous tubules of treated rats 

(Table 2) namely atrophy in the ST (Fig. 4B), abnormal 

organization of the germinal epithelium (Fig. 4C), and 

maturation arrest (Fig. 4D and E). 

Injection of male rats with low or high doses of ND 

caused a reduction in testicular volume as compared to 

control rats. Estimation of testicular volume is a good 

indicator of testicular atrophy, as evident in Fig. 4B. The 

decrease in testis volume might be a consequence of 

reduction in seminiferous tubules length (Noorafshan et 

al., 2005), or could have resulted from a negative feedback 

on the hypothalamic-pituitary axis with consequent 

testicular atrophy (Dohle et al., 2003). On the other hand, 

and as reported by others (Takahashi et al., 2004), body 

weight of the experimental animals did not differ from 

controls over the route of treatment (Fig.1). 

One final observation from the current work is that in 

some of the situations studied (effects of ND 

administration on TBRAS levels, motility and morphology 

of sperm, number of Sertoli cells and degree of late 

maturation arrest in ST), the actions of ND were directly 

receptor and dose dependent; the more drug injected the 

more adverse the side effect. When ND acts in a receptor 

mediated mode, we can assume that the high concentration 

of ND injected to rats can overcome the fact that AR has 

low affinity to ND (Saartok et al., 1984). In contrast, the 

effects of ND injection on level of sperm DNA 

fragmentation, serum testosterone concentration, sperm 

concentration, and the degree of ST early maturation arrest 

were receptor- and dose-independent. This observation 

about ND action could provide some evidence that ND has 

two distinct modes of actions, receptor-dependent and 

independent. However, both of ND modes of action in the 

testicular tissue may be closely linked (Rommerts, 1998). 

Androgen deficiency may have serious consequences in 

men, and this condition requires diagnosis and appropriate 

treatment. When administered properly, androgens are 

safe; however, when testosterone or its derivatives (such as 

AAS) are abused at supraphysiological doses, they may 

cause considerable harm. AAS are commonly used in our 

society, and physicians should be aware of their 

physiological effects. The present work reports that 

intramuscular injection of male rats with commonly used 

anabolic androgenic steroid ND (3 or 10 mg\kg) for 14 

weeks was deleterious to the structure of rat testes. These 

effects included testicular atrophy, maturation arrest in 

seminiferous tubules, severe depletion of the absolute 

number of spermatogenic and Sertoli cells, and marked 

suppression of sperm count. In addition, ND 

administrations caused testosterone depression, enhanced 

lipid peroxidation, as well as severe fragmentation in the 

DNA of sperm of treated rats. Although the concentration 

of ND which was administered to male rats is comparable 

to what is injected by AAS abusers, we are aware that 

caution should be taken when such results are extrapolated 

from animal to man.Acknowledgements 

This work was supported by a grant from The Deanship 

of Research and Graduate Studies, The Hashemite 

University. The authors are indebted to Mr. Ahed Al- 

Khateeb for his technical help with 

immunohistochemistry, and to Mr. Ghalib Al-Nusair for 

his valuable comments and manuscript editing. 

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JJBS 



ISSN 1995-6673 

Pages 175- 184 

Impact of Magnetic Application on the Parameters Related to 

Growth of Chickpea (Cicer arietinum L.) 

Nawroz Abdul-Razzak Tahir* and Hero Fatih Hama Karim 

University of Sulaimanyah, College of Agriculture, Bakrajo, Sulaimanyah, Iraq 

. 


The morphological data were used in this study for the 

evaluation of five chickpea (Cicer arietinum L.) varieties 

at the University of Sulaimanyah, College of Agriculture 

in 2010. Seeds of different varieties of chickpea were 

exposed in batches to static magnetic fields (1500 gauss 

of magnetic force) for 30, 50 and 70 min. Then, the 

magnetic seed were placed between two layers of moist 

germination paper in petri dish. They were placed in the 

germination incubator at 20°C in an upright position. 

After 8 days, different plant growth parameters were 

tested such as germination percentage, root length, shoot 

length, root fresh weight, shoot fresh weight, root dry 

weight and shoot dry weight, based on normal seedlings. 

The results showed that magnetic field application 

enhanced seed performance in terms of laboratory 

germination: seedling length and seedling fresh and dry 

weight compared to unexposed control. However, the 

response varied with duration of exposure. Among the 

various duration exposures, 50 and 70 min. exposures 

gave best results. A pot experiment was carried out in a 

greenhouse was aimed at finding the effect of a constant 

magnetic field on the root and shoot system, as well as 

on yield of spring chickpea. Seeds are grown in plastic 

cups for 4 months and irrigated with magnetized water 

which prepared by using static magnetic field. Six to 

fourteen plants were tagged for morphological data 

collection. The results showed that magnetized seeds 

irrigated with magnetized water have enhanced seed 

performance in terms of plant height, number of brancha, 

number of leaves, number of leaflets root and shoot fresh 

weight, root and shoot dry weight, the total 

photosynthetic pigments (chlorophyll a, b, and 

carotenoids) and yield in some varieties. 

Keywords: Chickpea, Magnetic field, growth parameter. 


Chickpea (Cicer arietinum L.), is the third most 

important cool season food legume in the world after dry 

beans and peas (FAOSTAT, 2006). Chickpea is a diploid 

* Corresponding author. nawrozbiology@gmail.com. 

ﺔﻌﻣﺎﺟ -ﺔﻋارﺰﻟا 

ﺔﻴﻠآ-ﺔﻴﻠﻘﺤﻟا 

ﻞﻴﺻﺎﺤﻤﻟا ﻢﺴﻗ ﻰﻓ ﺚﺤﺒﻟا يﺮﺟا 

Cicer ) ﺺﻤﺤﻟا ﻦﻣ فﺎﻨﺻأ ﺔﺴﻤﺧ ﻰﻠﻋ 2010 مﺎﻌﻟ ﺔﻴﻧﺎﻤﻴﻠﺴﻟا 

روﺬﺒﻟاو ىﺮﻟا ءﺎﻤﻟ ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا 

ﺔﺠﻟﺎﻌﻤﻟا ﺮﻴﺛﺎﺗ ﺔﻓﺮﻌﻤﻠﻟ ( arietinum L 

. ﺺﻤﺤﻟا تﺎﺒﻨﻟا و ةردﺎﺒﻟﺎﺑ ﺔﻘﻠﻌﺘﻤﻟا ﻮﻤﻨﻟا تﺎﻔﺻ ﺾﻌﺑ ﻰﻠﻋ 

ﺔﻴﻠﻤﻋ ﺖﻳﺮﺟا . ﺔﺻﻮﺑ 1 ﺮﻄﻘﺑ ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا 

ةﺰﻬﺟﻻا ﺖﻣﺪﺨﺘﺳا 

70 و 50 و 30 تاﺮﺘﻔﻠﻟ 

سوﺎآ 1500 ةﻮﻘﺑ ءﺎﻤﻟاو روﺬﺒﻟا ﺔﻄﻨﻐﻣ 

ﻞﺧاد ﺔﺒﻃر قرو ﻦﻣ ﻦﻴﺘﻘﺒﻃ ﻦﻴﺑ ﺔﻄﻨﻐﻤﻤﻟا 

روﺬﺒﻟا ﺖﻌﺿوو . ﺔﻘﻴﻗد 

ﺔﺟرد 20 ﺪﻨﻋ تﺎﺒﻧﻹا ﺔﻨﺿﺎﺣ 

ﻲﻓ قﺎﺒﻃﻻا ﺖﻌﺿوو . ىﺮﺘﺑ قﺎﺒﻃا 

ﺔﺒﺴﻧ : سﺎﺳأ ﻰﻠﻋ ﺔﻴﻌﻴﺒﻄﻟا تاردﺎﺒﻟا 

سﺎﻴﻗ ﻢﺗ ، مﺎﻳأ 8 ﺪﻌﺑ . ﺔﻳﻮﺌﻣ 

نزﻮﻟا ، رﺬﺠﻠﻟ 

ىﺮﻄﻟا 

نزﻮﻟا ، قﺎﺴﻟا لﻮﻃ ، روﺬﺠﻟا لﻮﻃ ،تﺎﺒﻧﻹا 

فﺎﺠﻟا نزﻮﻟاو رﺬﺠﻠﻟ 

فﺎﺠﻟا نزﻮﻟا ،ىﺮﻀﺧ 

عﻮﻤﺠﻤﻠﻟ ىﺮﻄﻟا 

ﻲﺴﻴﻃﺎﻨﻐﻤﻟا لﺎﺠﻤﻟا ﻖﻴﺒﻄﺗ نأ ﺞﺋﺎﺘﻨﻟا ﺖﺤﺿوأ 

و . ىﺮﻀﺧ عﻮﻤﺠﻤﻠﻟ 

،تاردﺎﺒﻟا 

لﻮﻃ : ﺔﻳﺮﺒﺘﺨﻤﻟا ﺮﻳﺎﻌﻤﻟا ﺚﻴﺣ ﻦﻣ روﺬﺒﻟا ﻦﺴﺤﺗ ﻰﻟا تدا 

ﻢﻟ ﻲﺘﻟا روﺬﺒﻟا ﻊﻣ ﺔﻧرﺎﻘﻣ ظﻮﺤﻠﻣ ﻞﻜﺸﺑ تاردﺎﺒﻠﻟ 

فﺎﺠﻟاو ىﺮﻄﻟا 

نزو 

ﺖﻠﺠﺴﻓ ، ﻚﻟذ ﻊﻣو . فﺎﻨﺻﻻا ﺾﻌﺑ ﻰﻓ ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا ﺔﺠﻟﺎﻌﻤﻠﻟ ضﺮﻌﺘﺗ 

ﺖﻧﺎآو . ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا ﺔﺠﻟﺎﻌﻤﻠﻟ ضﺮﻌﺘﻟا ةﺪﻣ فﻼﺘﺧﺎﺑ ﻪﻔﻠﺘﺨﻣ تﺎﺑﺎﺠﺘﺳا 

70 و 50 ةﺪﻤﻟ ًﺎﻴﺴﻴﻃﺎﻨﻐﻣ روﺬﺒﻟا ﺔﺠﻟﺎﻌﻣ ﺔﻠﻣﺎﻌﻤﻟا ﻦﻋ ﺞﺋﺎﺘﻨﻟا ﻞﻀﻓا 

. ( ةﺪﺣ ﻰﻠﻋ ﻞآ ) ﺔﻘﻴﻗد 

ﻞﺧاد ﺔﻴﺟﺎﺟﺰﻟا تﻮﻴﺒﻟا ﻲﻓ ﺺﻤﺤﻟا روﺬﺑ ﺔﻋارز ،ﺚﺤﺒﻟا 

ءﺎﻨﺛا ﻢﺗو 

ىرﺬﺠﻟا 

ﻮﻤﻨﻟا ﻰﻠﻋ ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا 

ﺔﺠﻟﺎﻌﻤﻟا 

ﺮﻴﺛﺄﺗ دﺎﺠﻳﻻ 

ﻚﻟذو ﺔﺑﺮﺘﻟا 

و ﺔﻄﻨﻐﻤﻤﻟا روﺬﺑ) 

روﺬﺒﻟا ﺖﻋرز ﺚﻴﺣ . ﺺﻤﺤﻟا جﺎﺘﻧاو 

ىﺮﻀﺨﻟاو 

تﺎﺗﺎﺒﻨﻟا ﺖﻴﻘﺳو 

ﺮﻬﺷأ 4 ةﺪﻤﻟ ﺔﻴﻜﻴﺘﺳﻼﺑ باﻮآأ ﻲﻓ ( ﺔﻄﻨﻐﻤﻤﻟا ﺮﻴﻏ روﺬﺑ 

ﺮﻴﻏ روﺬﺒﻠﻟ ) ﺔﻴﻔﻨﺤﻟا ءﺎﻤﻟاو ( ﺔﻄﻨﻐﻤﻤﻟا روﺬﺒﻠﻟ) 

ﻂﻨﻐﻤﻤﻟا ءﺎﻤﻟا ﻊﻣ 

. ﺔﻴﺟﻮﻟﻮﻓرﻮﻤﻟا تﺎﻧﺎﻴﺒﻟا ﻊﻤﺠﻟ َﺎﺗﺎﺒﻧ 14-6 

ﺖﻣﺪﺨﺘﺳأو 

. ( ﺔﻄﻨﻐﻤﻤﻟا 

دﺪﻋ ، تﺎﺒﻨﻟا عﺎﻔﺗرا لﺪﻌﻣ ﻲﻓ ﺔﻳﻮﻨﻌﻣ ةدﺎﻳز لﻮﺼﺣ ﺞﺋﺎﺘﻨﻟا تﺮﻬﻇأو 

،رﺬﺠﻠﻟ 

فﺎﺠﻟا و ىﺮﻄﻟا 

نزﻮﻟا ،قاروﻻا 

دﺪﻋ ،تﺎﻘﻳرﻮﻟا 

دﺪﻋ ،عوﺮﻔﻟا 

ﻲﺋﻮﻀﻟا ﻞﻴﺜﻤﺘﻟا تﺎﻐﺒﺻ ،ىﺮﻀﺧ 

عﻮﻤﺠﻤﻠﻟ 

فﺎﺠﻟاو يﺮﻄﻟا 

نزﻮﻟا 

ﺾﻌﺑ ﻲﻓ روﺬﺒﻟا 

جﺎﺘﻧﻻاو 

، ( تﺎﻨﻴﺗورﺎﻜﻟاو ب ، أ ﻞﻴﻓورﻮﻠﻜﻟا) 

ىﺮﻟا ءﺎﻤﻟ ﺔﺟودﺰﻤﻟا ﺔﻴﺴﻴﻃﺎﻨﻐﻤﻟا ﺔﺠﻟﺎﻌﻤﻟا ﺪﻨﻋ ﺺﻤﺤﻟا ﻦﻣ فﺎﻨﺻﻷا 

. ﺔﻄﻨﻐﻤﻤﻟا ﺮﻴﻏ ءﺎﻤﻟاو روﺬﺒﻟا ﻊﻣ ﺔﻧرﺎﻘﻣ روﺬﺒﻟاو 


with 2n = 2x = 16 (Arumuganathan and Earle, 1991) 

having a genome size of approximately 931 Mbp. 

Chickpea is a self-pollinated crop. Cross-pollination is 

rare; only 0-1 % is reported (Singh, 1987). 

The genus Cicer belongs to the family Leguminosae, 

subfamily Papilionoideae, tribe Cicereae Alef and 

comprises 43 species, nine of which being annual 

including chickpea (Cicer arietinum L.), while the rest are 

perennial (Van der Maesen, 1987). Chickpea is currently

176 


cultivated in over 40 countries worldwide and grown on 11 

million hectares producing around 9 million ton in 2005 

growing season (FAOSTAT, 2006). Two main types of 

chickpea cultivars are grown globally– kabuli and desi, 

representing two diverse gene pools. The kabuli types are 

generally grown in the Mediterranean region including 

Southern Europe, Western Asia and Northern Africa and 

the desi types are grown mainly in Ethiopia and Indian 

subcontinent (Pundir et al., 1985). Chickpea are grown 

usually as a rained cool-weather crop or as a dry climate 

crop in semi-arid regions. 

Pre-sowing seed treatment including chemical and 

physical treatments like electrical, microwave and 

irradiation are known to improve seed performance. 

Physical methods are not only cost effective; they also 

significantly improve the yield without adversely affecting 

the environment. They influence the physiological and 

biochemical process in the seeds, and thereby contribute to 

greater vigor and improved crop stand. Therefore, physical 

pre-sowing seed treatment for enhancing the seed 

performance, if standardized, can lead to commercial 

application. Alexander and Doijode (1995) noted that aged 

onion (Allium cepa) and rice (Oryza sativa) seeds exposed 

to a weak electromagnetic field for 12 h increased the 

germination shoot and root length of seedlings. Celestino 

et al. (2000) reported enhanced germination and growth of 

Cork oak (Quercus suber) seedlings when exposed to 

chronic magnetic field. Harichand et al. (2002) reported 

that exposure of magnetic field (10 mT; 40 h) increased 

plant height, seed weight per spike and yield of wheat. 

Aladjadjiyan (2002) observed that the magnetic field 

stimulated the shoot development of maize and led to an 

increase in germinating energy, fresh weight and shoot 

length. Growth of the germinated Vicia faba seedlings was 

enhanced by the application of power frequency magnetic 

fields (100 mT) that were supported by increased mitotic 

index and 3H-thymidine uptake (Rajendra et al., 2005). In 

broad bean (Phaseolus lunatus) and pea (Pisum sativum) 

cultivars the magnetic stimulation of seeds improved the 

sprouting and emergence of seed and resulted in higher 

pod number and seed yield (Podlesny et al., 2005). 

Harichand et al. (2002) reported that exposure of magnetic 

field (10 mT; 40 h) increased plant height, seed weight per 

spike and yield of wheat (Triticum aestivum). 

Magnetic treatment of water irrigation is an 

acknowledged technique for achieving high water use 

efficiencies due to its effect on some physical and 

chemical properties of water and soil (Noran et al., 1996). 

These changes result in an increased ability of soil to get 

rid of salt and consequently better assimilation of nutrients 

and fertilizers in plant during the vegetative growth period. 

Magnetizing methods among different physical and 

chemical methods of natural water treatment attract a 

special attention due to their ecological purity, safety, and 

simplicity. Magnetically treated water (MTW) is the water 

that is subjected to treatment by a magnetic field. The use 

of MTW is common in various branches of industry as a 

precaution against accumulation of scale in the water 

supply system, cooling tower, thermal and solar heating 

installation (Lin and Yotvat, 1989). The major objective of 

this study is to: evaluate the effect of magnetic application 

on some growth parameters of some chickpea varieties. 

2. Materials and Methods 

2.1. Plant material 

The plant material comprised of five varieties of 

chickpea including Rania, Chamchamal, Sangaw, FLIP98- 

133C (screened for their very sensitivity to Ascochyta 

rabiei) and FLIP83-48C (screened for their resistance to 

Ascochyta rabiei). All of the above material was obtained 

from Sulaimanyah Agricultural Research Center, 

Sulaimanyah, Iraq. Healthy seeds with identical 

dimensions were selected by visual observation. 

2.2. Magnetic treatment 

2.2.1. Germination characteristic 

This research was carried out in the 2009-2010 at 

College of Agriculture, University of Sulaimanyah to 

determine the impact of magnetic application on five 

chickpea varieties. A complete randomized design with 

three replications was used. Chickpea seeds were placed in 

magnetron (one inch of diameter and 1500 gauss of 

magnetic force as shown in Fig. 1) in a cylindrical shaped 

sample holder. One hundred visibly mature, healthy seeds 

were treated by magnetic field for various durations 

ranging from 30 min (T30), 50 min (T50) and 70 min 

(T70). Seed germination was achieved in three replications 

each with 15 seeds placed on two layers of moist filter 

paper in Petri dishes (imbibed with 12 ml of magnetized 

water). They were placed in the germination incubator at 

20 °C in an upright position. After 8 days, germinated 

seeds were grouped as normal, abnormal seedling, fresh 

ungerminated and dead seeds. Germination percentage was 

calculated based on normal seedlings. The seedlings from 

each replicate were randomly taken for measuring shoot 

and root length (using a ruler), and shoot and root fresh 

weight. Subsequently, they were dried in an oven at 90 °C 

for 48h and the dry weight of these seedlings was 

measured. 

2.2.2. Greenhouse experiment 

This research was carried out in 2010 (15.01.2010- 

18.05.2010) at the College of Agriculture, University of 

Sulaimanyah so as to determine the impact of magnetic 

application on five chickpea varieties grown under 

greenhouse conditions. A complete randomized design 

with ten replications was used. Two groups of chickpea 

(Cicer arietinum L.) seeds (magnetized group and control 

group for each variety) are selected with twenty seeds for 

each variety. Two seeds were sown (in 15.01.2010) in a 

plastic cup (25 cm height, 7 cm diameter) in 3 cm depth of 

soil containing mix (2 soil: 1 peat moss). Group (1) 

contained ten plastic cups (2 seeds/plastic cup) containing 

magnetized seed and irrigated with magnetized water, 

while group (2) contained ten plastic cups (2 seeds/plastic 

cup) containing unmagnetized seeds and irrigated with tap 

water. Irrigation was provided as and when required. The 

plastic cups were maintained in greenhouse under natural 

light. After four days the seedlings started to emerge over 

the soil level. 

2.3. Quantitative morphological traits 

Growth and developmental characteristics, including, 

plant height, number of primary branches, leaves, leaflets,


roots, fresh and dry weight of root and shoot, total pigment 

(Carotene + Chlorophylls a and b) of 28 days old plants 

were measured: 

1. Plant height: Height of plants (cm) from ground to the 

highest part of the plant by using a ruler. 

2. Number of primary branches: Actual counts of primary 

branches on the main stem per plants. 

3. Number of leaves and leaflets: Actual counts of number 

of leaves and leaflets per plant. 

4. Root biomass: Weight (g) of fresh and dry root per 

plant. 

5. Shoot biomass: Weight (g) of fresh and dry shoot per 

plant 

6. Total pigments (Carotene + Chlorophylls a and b) 

7. Grain yield: Dried weight (g) of seed per plant at 12% 

moisture content. 

2.4. Chlorophyll and carotene assay 

Photosynthetic pigments were extracted according to 

Mochizuki method (Mochizuki et al., 2001). One gram of 

fresh leaves of 28 days old plants (mixture of small 

177 

specimens picked up from all the 14 plants) were ground 

in liquid nitrogen, using a mortar and pestle. Ten milliliter 

of 80% acetone was added to a 15 ml Falcon tube, and 

mixed in dark for 15 min (note: chlorophylls degrade 

under light). The mixture was filtered through two 

Whatman filter papers. The absorbance (A) of chlorophyll 

and carotene content was measured, with three 

replications, at three-wave lengths 470, 646 and 663 using 

spectrophotometry. The chlorophyll and carotene 

concentrations are calculated as follows: 

Chlorophyll a (mg/g) = [12.21× A663 - 2.81 × A646] 

×V/1000×W 

Chlorophyll b (mg/g) = [20.13 × A646 - 5.03 × A663] 

×V/1000×W 

Carotenoids (mg/g) = [1000 × A470 – 3.27 × (Chl a) – 

[104 × (Chl b)/227] ×V/1000×W 

Total pigments = chlorophyll a + chlorophyll b + 

carotenoids 

Where V = volume of the extract (ml); W = Weight of 

fresh leaves (g). 

Figure 1: Showing Magnetron apparatus. 


Statistical analyses were conducted using SPSS for 

windows (version 18). The variance analyses (ANOVA) 

was used to test the main effects of magnetic field. The 

Duncan's test was done to find the significant differences 

between each magnetic treatment and control at level 5% 

(Levesque, 2007). 

untreated seeds (control seeds) was 40-45% for the 

varieties Chamchamal and Sangaw. 

The results revealed that shoot length was increased in 

treatment T50 for Rania, Chamchamal and Sangaw (Table 

1). There was no significant difference among the 

treatments: Control, T30, T50 and T70 for FLIP83-48C. 

On the other hand, the treatment T70 shared the maximum 

shoot length for FLIP98-133C. The improvement over 

control (untreated seeds) was 73 and 26 % for the 

3. Results and Discussion 

varieties: Chamchamal and Sangaw respectively (Table 1). 

For root fresh weight, significant positive value was 

3.1. Seedling growth (laboratory experiment) 

observed among the treatments: Control, T30, T50 and 

Concerning the germination percentage, exposure of 

chickpea seeds to different time of magnetic field did not 

show significant difference between the control and others 

treatments for all varieties (Table 1). Other developmental 

growth parameters including: root length of 8 days 

seedlings, showed significant differences among the 

treatments: Control, T30, T50 and T70 for Chamchamal, 

Sangaw and FLIP98-133C, while Rania and FLIP83-48C 

revealed non-significant difference among the treatments: 

Control, T30, T50 and T70 (Table 1). From these results, it 

was found that the average length of root of Chamchamal, 

Sangaw and FLIP98-133C was more than the average 

length of control. The improvement root length over 

T70 in all varieties except FLIP83-48C. The value of 

improvement, when compared with the control (untreated 

seeds), varied between 40 to 80% (Table 1). 

The parameter, shoot fresh weight, showed the 

significant positive value for the varieties: Chamchamal 

and FLIP98-133C, when compared with the control 

(untreated seeds). The percentage of improvement was 50- 

90% (Table 1). Root dry weight was significantly higher 

than the control in most of the treatments for all varieties 

except Rania. The percentage of improvement was 40-50% 

when compared to the control (Table 2). The average 

seedling shoot dry weights are tending to increase in 

treatments: T30, T50 and T70 for Chamchamal, T50 for 

Sangaw and T70 for FLIP98-133C (Table 2).

178 


Table 1: Effect of seed pretreatment by magnetic field and its duration on germination characteristic: germination percentage, root length, 

shoot length, root fresh weight and shoot fresh weight. 

Germination percentage (%) 

Treatments Rania Chamchamal Sangaw FLIP98-133C FLIP83-48C 

Control 90.33a 93.33a 95.55a 73.33a 93.33a 

T30 92.33a 93.33a 93.33a 73.33a 93.33a 

T50 95.55a 93.33a 95.55a 86.66a 93.33a 

T70 93.33a 95.55a 95.55a 82.22a 91.11a 

Root length (cm)/plant 

Control 4.18a 4.45b 4.84b 3.59a 1.81a 

T30 4.26a 5.54ab 4.98b 2.81b 1.57a 

T50 4.13a 6.18a 5.58ab 2.88b 1.94a 

T70 4.65a 6.48a 6.54a 3.64a 1.78a 

Shoot length (cm)/plant 

Control 2.26ab 2.10b 2.61b 1.84b 1.22a 

T30 2.04b 3.28a 2.63b 1.62b 1.11a 

T50 2.64a 3.92a 3.41a 1.84b 1.18a 

T70 2.37ab 3.65a 3.29a 2.75a 1.19a 

Root fresh weight (mg)/plant 

Control 114.23b 70.12b 132.26b 92.56b 68.21a 

T30 116.9b 85.53b 154.1ab 88.9b 61.23a 

T50 131.26a 134a 176.76a 102.5b 63.13a 

T70 136.26a 135.7a 187.8a 129.33a 56.9a 

Shoot fresh weight (mg)/plant 

Control 62.96ab 46.43c 70.13b 41.53b 32.55a 

T30 58.36b 77.3b 74.05b 36.26b 39.66a 

T50 75.36a 98.03a 120.03a 45.16b 34.4a 

T70 61.1ab 88.33ab 89.26b 60.06a 36.23a 

*Means designated with the same letter (s) do not differ significantly from each other according to Duncan's multiple range tests, p ≤ 0.05.


Table 2: Effect of seed pretreatment by magnetic treatment and its duration on germination characteristic: root dry weight and shoot dry 

weight. 

Root dry weight (mg)/plant 


Control 14.45a 11.31b 11.88b 10.54b 5.78ab 

T30 14.253a 14.14a 13.97ab 11.05b 4.95b 

T50 14.98a 14.92a 15.44a 11.83ab 6.29a 

T70 14.60a 14.92a 14.54a 14.13a 5.84ab 

Shoot dry weight (mg)/plant 

Control 8.14ab 7.33b 8.41b 5.69b 4.24a 

T30 8.19ab 10.35a 9.37b 5.73b 4.39a 

T50 8.8a 11.79a 11.99a 5.93b 4.36a 

T70 7.85b 10.02a 9.86b 7.54a 4.70a 

*Means designated with the same letter (s) do not differ significantly from each other according to Duncan's multiple range tests, p ≤ 0.05. 

Researchers carried out an experiment study on water 

absorption by lettuce seeds previously treated in a 

stationary magnetic field of 1 to 10 mT. They reported an 

increase in water uptake rate due to the applied magnetic 

field, which may explain the increase in the germination 

seed of treated lettuce seeds (Calatayud et al., 2003). 

Lentil seedlings from magnetically pretreated seeds grew 

better than the untreated, and also biomass and root growth 

were significantly increased (Ahmad et al., 2009). 

Biomass increase needs metabolic changes particularly 

increasing protein synthesis (Lebedev and Litvinenko, 

1977). The mechanism of stimulating effect of magnetic 

field-treatment on seed germination and seedling growth 

was unknown. Although most seemed to involve changes 

in intracellular levels of Ca +2 and in other ionic current 

density across cellular membrane (Florez et al., 2004) 

which caused alteration in osmotic pressure and changes in 

capacity of cellular tissues to absorb water (Calatayud et 

al., 2003). Magnetic fields can remove bounded of Ca +2 

from cell membrane which is essential for the stability of 

membranes. Consequently, their loss will increase 

temporary pore formation under the mechanical stresses 

from pressure differences within cell and abrasion by its 

moving content. The magnetic field could increase an 

inner energy which is distributed among the atoms causing 

accelerated metabolism (Campbell, 1977). 

In conclusion, the magnetic field pre-treatment for 50 

or 70 min enhanced root length, shoot length, root fresh 

weight, shoot fresh weight, root dry weight and shoot dry 

weight compared with the control. Seed germination 

percentage did not show any significant differences 

between the treatments times for all varieties. 

3.2. Greenhouse experiment 

Cumulative plant growth data (plant height, number of 

branch, number of leaves, number of leaflets and total 

pigments) were measured. The most significant different 

growth was observed in plants grown from magnetized 

seeds and water for the treatments T50 and T70 (Tables 3 

and 4). Growth data were measured onthe 28 th days after 

seeding. The greatest plant height was observed in plants 

179 

grown up from seeds magnetized for 50 (T50) and 70 min 

(T70) and irrigated with magnetized water for all varieties 

of chickpea except Rania (Table 3). This result was in 

agreement with that obtained by Algozari and Yao (2006) 

in the increasing of plant height as a result of magnetizing 

of seeds and water. They reported that the magnetic 

application lead to easy breakthrough of water for the cell 

membrane of plants. The easy breakthrough of water leads 

to better absorption of water and mineral by plant roots 

(Barefoot and Reich, 1992). Kronenberg et al. (2005) 

showed that the magnetic application lead to an increase in 

the availability of minerals in soil through the increasing 

of solubility of salts and minerals. The increasing of 

solubility of salts and minerals lead to the increasing of 

macro and micro elements from soil and division and 

elongation of cell during the plant growth. However, it was 

found that the pretreatment of seeds for 50 (T50) and 70 

min (T70) by magnetic field and irrigation by magnetized 

water had more growth in branch compared with the 

control plants in all varieties except FLIP98-133C and 

FLIP83-48C (Table 3). Also these data allow us to find 

significant differences among the treatments: Control, T30, 

T50 and T70 for the number of leaves and leaflets of 

chickpea plants (Tables 3). Total pigments content 

(Chlorophylls a, b and Carotene) increased significantly 

(20-25%) for Chamchamal, FLIP98-133C and FLIP83- 

48C with respect to control groups at T30 and T50. On the 

other hand, Rania did not show significance difference 

between the control and the magnetic treatments: T30, T50 

and T70 (Table 3). Total fresh weight (biomass) of plants 

was measured on the 28 th days after planting (Table 4). 

Shoot fresh weight, root fresh weight, root dry weight and 

shoot dry weight were significantly affected by magnetic 

application compared with the control. Significant 

genotypic variability was detected in all genotypes except 

Rania for shoot fresh weight (Table 4). Comparatively 

higher shoot fresh weight was obtained at magnetic 

treatment T70. The greatest increase (improved value) in 

shoot fresh weight was recorded with Chamchamal at T70. 

Analysis of variance for root fresh weight traits computed 

from the chickpea, treated or non-treated by magnetic

180 


Table 3: Effect of magnetized seed and water on plant height, number of branch, number of leaves, number of leaflets and total pigments 

(Chlorophyll a + Chlorophyll b + Carotene) of chickpea grown in soil under greenhouse condition. 

Plant height (cm)/plant 


Control 17.35a 15.44b 14.93b 13.80b 13.40b 

T30 16.52a 16.58ab 15.42b 15.26ab 14.97ab 

T50 16.37a 17.52a 16.99ab 15.69a 16.58a 

T70 17.85a 17.97a 18.13a 14.34ab 15.61ab 

Number of branch/plant 

Control 3.13b 3.13b 4.1b 4.4a 3.83a 

T30 3.7ab 3.73a 4.13b 4.26a 3.96a 

T50 3.43ab 3.86a 4.33ab 4.36a 4.3a 

T70 3.9a 3.76a 4.66a 4.56a 4.23a 

Number of leaves/plant 

Control 12.5ab 11.7b 16.83b 15.76b 14.43b 

T30 11.73b 11.6b 17.06b 16.2b 15.8ab 

T50 14a 14.86a 19.73a 19.06a 17.7a 

T70 13.93a 15.23a 20.73a 18.86a 16.33ab 

Number of leaflets/plant 

Control 79.26b 88.26bc 102.93b 82.36b 75.9c 

T30 79.7b 77.46c 101.46b 82.6b 88.96bc 

T50 89.33ab 98.96ab 114.86ab 111.83a 105.96a 

T70 96.1a 109.16a 122.8a 103.16a 96.96ab 

Total pigments (Chlorophyll a, b + Carotene) (mg/g fresh weight)/plant 

Control 0.253a 0.199bc 0.220a 0.201d 0.165b 

T30 0.258a 0.189c 0.218a 0.235b 0.202a 

T50 0.241a 0.240a 0.211a 0.236a 0.167b 

T70 0.251a 0.201b 0.201b 0.219c 0.161c 

*Means designated with the same letter (s) do not differ significantly from each other according to Duncan's multiple range tests, p ≤ 0.05.


Table 4: Effect of magnetized seed and water on shoot fresh weight, root fresh weight, shoot dry weight, root dry weight and seed 

yield/plant of chickpea grown in soil under greenhouse condition. 

Shoot fresh weight (g)/plant 


Control 2.79a 1.63b 3.17b 2.07c 2.36c 

T30 2.68a 1.5c 3.4a 2.19b 2.5b 

T50 2.87a 2.75a 2.95c 2.23ab 3a 

T70 2.67a 2.83a 3.03bc 2.29a 3.03a 

Root fresh weight (g)/plant 

Control 4.83b 3.55c 5.11b 3.45d 4c 

T30 4.66b 3.20c 5.33b 4.2c 5.23ab 

T50 6.86a 4.2b 5.05b 4.48b 5.35a 

T70 5.55b 4.83a 5.73a 5.46a 4.86b 

Shoot dry weight (g)/plant 

Control 0.359c 0.18d 0.57b 0.43b 0.43a 

T30 0.425b 0.31c 0.601b 0.44b 0.46a 

T50 0.453a 0.44b 0.605b 0.47a 0.46a 

T70 0.445ab 0.48a 0.79a 0.44b 0.47a 

Root dry weight (g)/plant 

Control 0.51c 0.31b 0.46b 0.27d 0.259c 

T30 0.515bc 0.25c 0.47b 0.32c 0.40a 

T50 0.525b 0.32b 0.50b 0.44a 0.36b 

T70 0.67a 0.42a 0.589a 0.42b 0.38b 

Seed yield (g)/plant 

Control 3.05c 3.01c 3.41b 2.61b 2.28d 

T30 3.27b 3.2b 3.28b 2.76b 2.93c 

T50 4.00a 3.76a 4.18a 3.36a 3.1b 

T70 3.98a 3.65a 4.15a 3.33a 3.22a 

*Means designated with the same letter (s) do not differ significantly from each other according to Duncan's multiple range tests, p ≤ 0.05. 

field, showed significance differences. The highest 

increased in root fresh weight was recorded by FLIP98- 

133C at T70 compared with the control (Table 4). 

Significant genotypic variability was detected in all 

genotypes except FLIP83-48C for shoot dry weight. The 

greatest increase (improved value) in shoot dry weight was 

recorded by Chamchamal at T70 compared with the 

control (Table 4). Analysis of variance for root dry weight 

traits computed from the chickpea treated or non-treated 

by magnetic field, showed significance differences. The 

highest increase in root dry weight was recorded by 

FLIP98-133C at T70 compared with the control (Table 4). 

The current study showed that seeds yield per plant was 

significantly affected by the duration of exposure to 

magnetic field as indicated by the significant one-way 

181 

based on ANOVA (p< 0.05) (Table 4). Rania (T50), 

Chamchamal (T50), Sangaw (T50), FLIP98-133C (T50) 

and FLIP83-48C (T70) showed an increase of 31, 25, 23, 

29 and 41% respectively of seeds yield compared with the 

control (Table 4). The increasing of seed yield as a result 

of increased plant growth and the effectiveness of the 

shoots in the photosynthesis process (Kronenberg et al., 

2005). 

The results obtained in this growth test allow us to 

conclude that magnetic treatment improves the stages of 

growth in higher plants. In general the seedlings from 

seeds magnetically pretreated grew taller and heavier than 

untreated controls. These seedlings showed greatly 

improved root characteristics. The stimulatory effect of the 

application of different magnetic times on the growth data

182 


reported in this study was in agreement with that obtained 

by other researchers. Florez et al. (2007) observed an 

increase in the initial growth stages and an early sprouting 

of maize and rice seeds exposed to 125 and 250mT 

stationary magnetic field. Martinez et al. (2002) observed 

similar effects on wheat and barley seeds magnetically 

treated. The mechanisms are not well known yet, but 

several theories have been proposed, including 

biochemical changes or altered enzyme activities by 

Phirke et al. (1996). Chickpea seedlings from magnetically 

pretreated seeds grew more than the untreated, and also 

biomass and root growth were significantly increased. 

Magnetic field is known as an environmental factor 

which affects gene expression. Therefore, augmentation of 

biological reactions like protein synthesis, biomass would 

increase too. Moreover, transcriptional factors are under 

effect of magnetic field stimulation (Xi and Ling, 1994). 

The effects of magnetic fields are superimposed on 

endogenous rhythms in some situations leading to 

inhibition, and in others to stimulation, while sometimes 

no effects had been reported. Moreover, magnetic fields 

have the ability to change water properties, thus 

magnetized water increased rice chlorophyll content (Tian 

et al., 1989). Similary, Racuciu et al. (2008) reported that 

long magnetic field exposure has the ability to increase 

assimilatory pigments. This fact was confirmed by several 

studies for different plants where magnetic field treatment 

increased the chlorophyll content in sugar beet (Beta 

vulgaris L.) leaves (Rochalska, 2005). Additionally, 

studies by Atak et al. (2007) involving magnetic field 

impact on soybean (Glycine max L.) confirmed that 

magnetic field significantly increased chlorophyll a, 

chlorophyll b and total chlorophyll contents. Whereas, 

magnetic field short exposure is accompanied with 

increases in chlorophyll a, chlorophyll b and total 

chlorophyll contents (Atak et al., 2000). The reduction of 

pigments explained by Commoner et al. (1956), that 

chemical with unpaired electrons possess a magnetic 

moment plays an important role in electron transfer and 

kinetics of chemical reactions. The electrons with 

magnetic moments can be oriented in the external 

magnetic field. As a result of the interaction between the 

external magnetic field and the magnetic moment of 

unpaired electrons, the energy is absorbed. Chloroplasts 

have magnetic moments and could be affected by the 

absorbed energy at a high dose of magnetic field which 

can disturb the pigments synthesis. Other possible 

explanations for the decline in pigments content are that 

carotenoids may be consumed in radical scavenging 

reactions (Strzalka et al., 2003), or free radicals inhibited 

the pigments synthesis through affecting photosynthesis 

enzymes. 

In conclusion, magnetic field could be used as a 

stimulator for growth related reactions. Photosynthetic 

pigments content have shown a significant increase in 

response to magnetic fields at low dose. Short exposure to 

alternating magnetic field had a positive impact, whereas 

long exposure had a negative effect on pigments content 

similar to magnetic field effect on proline (Dhawi Al- 

Khayri, 2008). Using magnetic field treatment could be a 

promising technique for agricultural improvements but 

extensive research is required, using different levels of 

magnetic field doses to determine the optimum dose. We 

can conclude that exposure of dry chickpea seeds to static 

magnetic field for different durations significantly 

increased laboratory germination characteristics. On the 

other hand, the exposure of seed to magnetic field and 

irrigation with magnetized water revealed the stimulatory 

influence on the following growth characters: significant 

enhancement of the fresh tissue mass, assimilated total 

pigments level, increase of the average plants height, 

number of branch, number of leaf and leaflet in some 

varieties of chickpea. 

In conclusion, the exposure of seed to magnetic field 

and irrigation with magnetized water revealed the 

stimulatory influence on the plants: significant 

enhancement of the fresh tissue mass, assimilatory total 

pigments level, increase of the average plants height, 

number of branch, number of leaves and leaflets in some 

varieties of chickpea. We recommend the following: 

1. Studying the effect of magnetic field on the flowering. 

2. Evaluation of expression of genes, total proteins and 

metabolic compounds related to the growth. 

3. Studying the effect of magnetic field on the resistance 

to biotic ( Ascochyta rabiei) and abiotic stress 

(Drought). 

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JJBS 



ISSN 1995-6673 

Pages 185 - 192 

In vitro Study of Adult Bone Marrow Mesenchymal Stem Cells 

Derived from Albino Rats and their Cardiomyogenic 

Differentiation 

Intissar N. Waheed a , Intidhar M. Mnati b and Abdul Hussain H.Kadhim b 

a College of Pharmacy, University of Duhok; b College of Education (Ibn Al-Haitham), University of Baghdad, Iraq 

. 


Mesenchymal stem cells (MSCs) are pluripotent adult 

stem cells residing within the bone marrow (BM) capable 

of self renewal, production of large number of 

differentiated progeny and regeneration of tissues. This 

study aimed at isolating the adult rats BM-MSCs and 

stimulating their in vitro differentiation into 

cardiomocytes. The BM, isolated from young male white 

rats (Rattus norvegicus albinos) and maintained in 

culture at 37C˚ and 5%CO2. The culture system which 

permits to direct differentiation of the MSCs into 

cardiomyocyte-like characteristics was treated with rat 

embryonic heart muscle extract (HME), and 

differentiated cells were detected with 

immunocytochemistry examination using anti - myosin 

and anti - cardiotin antibodies as markers. The MSCs had 

fibroblast like morphology before HME treatment, but 

their morphology began to change after treatment. 

Treated MSCs increased in size and had formed a ball 

and a stick like morphology and were connecting with 

adjoining cells after one week and began to form 

myotube like structures at the end of second week. After 

three weeks of treatment, the differentiated cells could be 

distinguished by the presence of a number of branches 

and began to interface with each other to form cardiac 

like cells. The differentiated cells were positive for 

myosin and cardiotin. The morphological changes were 

not seen in control cells. We can conclude that HME 

may contain certain growth factors that stimulate the 

differentiation of BM-MSCs to the muscular pathway. 

Keywords: Bone marrow, Cardiomyogenic differentiation, Mesenchymal stem cells, Cell culture.. 


Bone marrow stem cells (BMSCs) have myogenic 

potential and are therefore promising candidates for 

multiple cell-based therapies for myocardial diseases 

(Orlic et al., 2001). Recent attention has focused on BM as 

a source of stem cells which can be collected from adults 

and used for transplantation without posing ethical 

* Corresponding author. intissar1960@yahoo.com. 

ﻲهو ﻢﻈﻌﻟا ﻲﻘﻨﻟ ﺔﻘﻴﻗﺪﻟا ﺔﺌﻴﺒﻟا ﻦﻤﺿ ﺔﻴﻤﺤﻠﻟا ﺔﻴﻋﺬﺠﻟا ﺎﻳﻼﺨﻟا ﺪﺟاﻮﺘﺗ 

دﺪﺠﺘﻟاو ﺮﺛﺎﻜﺘﻟا ﻰﻠﻋ ةرﺪﻘﻟا ﺎﻬﻟ ،ىﻮﻘﻟا ةدﺪﻌﺘﻣ ﺔﻐﻟﺎﺑ ﻪﻴﻋﺬﺟ ﺎﻳﻼﺧ 

ﺪﻳﺪﺠﺗ ﻰﻠﻋ ﺎﻬﺘﻴﻠﺑﺎﻗ ﻰﻟإ ﺔﻓﺎﺿإ ةﺰﻳﺎﻤﺘﻤﻟا ﺎﻳﻼﺨﻟا ﻦﻣ ةﺮﻴﺒآ داﺪﻋأ 

ﻦﻳﻮﻜﺗو 

ﺔﻴﻋﺬﺠﻟا 

ﺎﻳﻼﺨﻟا ءﺎﻤﻧإو لﺰﻋ ﻰﻟإ ﺔﺳارﺪﻟا ﻩﺬه فﺪﻬﺗ . ﺔﻔﻟﺎﺘﻟا ﺔﺠﺴﻧﻷا 

جرﺎﺧ ﺎهﺰﻳﺎﻤﺗو ﺎهﻮﻤﻧ ﺰﻴﻔﺤﺗ ﻢﺛ ﻦﻣو ناذﺮﺠﻟا ﻢﻈﻋ ﻲﻘﻨﻟ ﺔﻐﻟﺎﺒﻟا ﺔﻴﻤﺤﻠﻟا 

ﺔﻴﻤﺤﻠﻟا ﺔﻴﻋﺬﺠﻟا ﺎﻳﻼﺨﻟا ﺖﻟﺰﻋ . ﺔﻴﺒﻠﻘﻟا ﺔﻴﻠﻀﻌﻟا ﺎﻳﻼﺨﻟا ﻰﻟإ ﻲﺤﻟا ﻢﺴﺠﻟا 

(Rattus norvegicus ﺔﻌﻓﺎﻴﻟا ءﺎﻀﻴﺒﻟا ناذﺮﺠﻟا رﻮآذ ﻦﻣ ﻢﻈﻌﻟا ﻲﻘﻨﻟ 

و 37C˚ ةراﺮﺣ ﺔﺟرﺪﺑو ﻲﻋرﺰﻟأ ﻂﺳﻮﻟا ﻲﻓ ﺎﻬﺘﻣادإ ﻢﺗوalbinos) 

ﺎﻳﻼﺧ ﻰﻟإ ﺎﻳﻼﺨﻟا ﻩﺬه ﺰﻳﺎﻤﺗ ﻪﻴﺟﻮﺘﻟو. 

نﻮﺑﺮﻜﻟا ﺪﻴﺴآوا ﻲﻧﺎﺛ زﺎﻏ % 5 

بﻮﻠﻗ تﻼﻀﻋ ﺺﻠﺨﺘﺴﻤﺑ ﺎﻬﺘﻠﻣﺎﻌﻣ ﻢﺗ ﺔﻴﺒﻠﻘﻟا ﺔﻴﻠﻀﻌﻟا ﺎﻳﻼﺨﻟﺎﺑ ﺔﻬﻴﺒﺷ 

لﺎﻤﻌﺘﺳﺎﺑ ةﺰﻳﺎﻤﺘﻤﻟا ﺎﻳﻼﺨﻟا ﻩﺬه ﻰﻠﻋ ﻒﺸﻜﻟا ﻢﺗ ﺎهﺪﻌﺑو . ناذﺮﺠﻟا ﺔﻨﺟأ 

( تﺎﻤﺳاو) 

تﺎﻤﻠﻌﻣ لﺎﻤﻌﺘﺳﺎﺑ ﻚﻟذو ﻲﻋﺎﻨﻤﻟا يﻮﻠﺨﻟا ﻲﺋﺎﻴﻤﻴﻜﻟا ﺺﺤﻔﻟا 

ﺎﻳﻼﺨﻟا وﺪﺒﺗ . anti-myosin and anti-cardiotin ﻞﺜﻣ ﻚﻟﺬﻟ ﺔﺼﺼﺨﺘﻣ 

ﻪﻴﺒﺷ ﻞﻜﺸﺑ ﺐﻠﻘﻟا تﻼﻀﻋ ﺺﻠﺨﺘﺴﻤﺑ ﺔﻠﻣﺎﻌﻤﻟا ﻞﺒﻗ ﺔﻴﻤﺤﻠﻟا ﺔﻴﻋﺬﺠﻟا 

أﺪﺒﺗ ﺚﻴﺣ ، ﺔﻠﻣﺎﻌﻤﻟا ﺪﻌﺑ 

ﺮﻳﺎﻐﺘﻟﺎﺑ ﺎﻬﻠﻜﺷ أﺪﺒﻳ ﻦﻜﻟو ﺔﻴﻔﻴﻠﻟا ﺔﻣورﻷﺎﺑ 

ﺎﻬﻠﻜﺷ ﺮﻴﻐﺘﻳ ﻢﺛ ﻦﻣو ةﺮﻜﻟﺎﺑ ﻪﻴﺒﺷ ﻞﻜﺷ نﻮﻜﺗو ﺎﻬﻤﺠﺣ ﻲﻓ ةدﺎﻳﺰﻟﺎﺑ ﺎﻳﻼﺨﻟا 

ﺎﻳﻼﺨﻟا ﻩﺬه أﺪﺒﺗ ﺔﻠﻣﺎﻌﻤﻟا ﻦﻣ ﺪﺣاو عﻮﺒﺳأ ﺪﻌﺑو ﺐﻴﻀﻘﻟﺎﺑ ﻪﻴﺒﺷ ﺢﺒﺼﻳو 

ﻦﻳﻮﻜﺘﺑ أﺪﺒﺗ ﻲﻧﺎﺜﻟا عﻮﺒﺳﻷا ﺔﻳﺎﻬﻧ ﻲﻓو ، ﺎﻬﻟ ةروﺎﺠﻤﻟا ﺎﻳﻼﺨﻟﺎﺑ طﺎﺒﺗرﻻﺎﺑ 

ﺢﺒﺼﻳ ﻊﻴﺑﺎﺳأ ﺔﺛﻼﺛ ﺪﻌﺑ ﻦﻜﻟو ،ﻲﻠﻀﻌﻟا بﻮﺒﻧﻷﺎﺑ ﺔﻬﻴﺒﺷ ﺐﻴآاﺮﺗ 

تﺎﻋﺮﻔﺘﻟا ﻦﻣ دﺪﻋ دﻮﺟﻮﺑ ﻚﻟذو ةﺰﻳﺎﻤﺘﻤﻟا ﺎﻳﻼﺨﻟا ﻩﺬه ﺰﻴﻴﻤﺗ نﺎﻜﻣﻹﺎﺑ 

ﻢﻟ تاﺮﻴﻐﺘﻟا ﻩﺬه ﻦﻜﻟو . ﺔﻴﺒﻠﻘﻟا ﺎﻳﻼﺨﻟﺎﺑ ﺔﻬﻴﺒﺷ ﺎﻳﻼﺧ ﺔﻧﻮﻜﻣ ﺔﻠﺼﺘﻤﻟا 

ﺔﺒﺟﻮﻣ ﺔﺑﺎﺠﺘﺳا ةﺰﻳﺎﻤﺘﻤﻟا ﺎﻳﻼﺨﻟا 

تﺮﻬﻇأ . ةﺮﻄﻴﺴﻟا 

ﺔﻋﻮﻤﺠﻣ ﻲﻓ ﻆﺣﻼﺗ 

نأ ﻦﻜﻤﻣ ﺔﺳارﺪﻟا ﻩﺬه ﺞﺋﺎﺘﻧ لﻼﺧ ﻦﻣ . تﺎﻤﺳاﻮﻟا ﻦﻣ ﻦﻴﻋﻮﻨﻟا ﻼﻜﻟ 

ﺔﻨﻴﻌﻣ ﻮﻤﻧ ﻞﻣاﻮﻋ ﻰﻠﻋ يﻮﺘﺤﻳ ﺪﻗ ﺐﻠﻘﻟا تﻼﻀﻋ ﺺﻠﺨﺘﺴﻣ نﺎﺑ ﺞﺘﻨﺘﺴﻧ 

ﻰﻟإ ﻢﻈﻌﻟا ﻲﻘﻨﻟ ﺔﻴﻤﺤﻠﻟا ﺔﻴﻋﺬﺠﻟا ﺎﻳﻼﺨﻟا ﺰﻳﺎﻤﺗ ﺰﻴﻔﺤﺘﺑ مﻮﻘﺗ ﺎهروﺪﺑ 

ﻲﺘﻟاو 

. ﻲﻠﻀﻌﻟا ﻩﺎﺠﺗﻻا 


questions or creating problems of tissue matching and 

rejection (Hassink et al., 2003). 

Mesenchymal stem cells (MSCs) are pluripotent adult 

stem cells residing within the BM microenvironment 

(Makino et al., 1999). Mesenchymal stem cells have an 

adherent nature and are expandable in culture and can 

differentiate into osteoblasts, chondrocytes, neurons, 

skeletal muscle cells (Prockop, 1997) and cardiomyocytes 

(Wang et al., 2000). Cardiomyogenic differentiation of 

stem cells has been vastly reported (Tomita et al., 1999; 

Kehat et al., 2001). The cells undergoing cardiomyogenic

186 


differentiation achieve the cardiomyocyte phenotype 

through the expression of specific genes encoding various 

transcriptional factors and structural and regulatory 

proteins (Peng et al., 2002). 

The potential of MSCs to differentiate into myogenic 

cells was first reported by (Wakitani et al., 1995) and then 

by a number of other investigators (Tomita et al., 1999; 

2002; Xu et al., 2004). Early in vitro studies of the primary 

culture of rat MSCs treated with 10µmol/L 5-azacytidinem 

(a DNA demethylating chemical compound used to induce 

cardiomyogenic differentiation), showed that after 2 weeks 

of treatment, murine BM-MSCs formed myotube like 

structure and expressed myocardial specific proteins, such 

as cardiac troponin I and cardiac myosin heavy chain 

(MHC). These data suggest that stromal stem cells 

including MSCs differentiate into cardiomyocytes under 

appropriate culture conditions (Tomita et al., 1999). The 

same results were also demonstrated by Makino et al., 

1999; Fukuda, 2001 and Bittira et al., 2002. At a 

concentration of 3 µmol/L for 1 week, 5-azacytidine 

induced BMCs into cardiomyogenic cells. These cells 

stained positive for myosin, actin and desmin and showed 

spontaneous beating at 3 weeks after treatment. Electron 

microscopy revealed a cardiomyocyte like structure 

including typical sarcomeres, a centrally positioned 

nucleus and a trial granule. 

An interesting study from Xu et al., 2004 showed that 

the MSCs of human BM when treated with 10µmol/L 5azacytidine 

appeared spindle shaped with irregular 

processes and the myogenic cells differentiated from 

MSCs were positive for beta–MHC, desmin and alpha 

cardiac actin. 

After-wards, various strategies have been adopted for 

directed differentiation of BM-MSCs into cardiomyocytes 

by culturing BM-MSCs in vitro using culture media 

supplemented with retinoic acid (RA), dimethyl 

sulphoxide (DMSO) and 5-azacytidine (Heng et al., 2004; 

Antonitsis et al.,2007). The study of AL-Jumely, (2006) 

showed that mice BM-Hematopoetic stem cells (HSCs) 

when treated with heart muscle extract (HME) of newborn 

mice differentiated into muscular pathway in vitro, and 

these cells are stained positive for myosin. 

The current study aimed at isolating and cultivating the 

BM-MSCs from young rats and stimulating their growth 

and differentiation in vitro into cardiomyocytes using 

HME. 


Young male white rats (50-55 day old) (Rattus 

norvegicus albinos) weighing 180-200gm were used for 

the isolation of MSCs from the BM. These animals were 

obtained from the animal breeding house of the Medical 

Research Unit - College of Medicine - Al-Nahrain 

University - Baghdad - Iraq. 

2.1. Isolation of bone marrow derived mesenchymal cells 

Bone marrow derived mesenchymal stem cells cultures 

were prepared according to the protocol of Wakitani et al., 

1995. Briefly, under sterile conditions, the femur and 

tibiae of the rats were excised, with special attention given 

to remove all connective tissue attached to bones. Bone 

marrow was extruded from these bones by flushing the 

BM cavity using a syringe with 20-gauge needle filled 

with culture medium (Minimum Essential Medium (MEM) 

supplemented with 10% fetal calf serum (FCS)). The 

harvested BMCs were gently pipetted to break up cell 

clumps in order to obtain cell suspension. After a 

homogenous cell suspension was achieved, the cells were 

centrifuged at 2000 rpm for 10 minutes and the cell pellet 

was resuspended in 3ml of culture medium. 

The cell suspension was loaded carefully onto 5ml of 

60% percoll in sterile conical tube, and then centrifuged 

for 20-25 minutes at 2000 rpm at 8Cº. The mononuclear 

cells (MNCs) were retrieved from the buffy coat layer by 

sterile Pasteur pipette and placed in 5ml sterile conical 

tube. The cells were washed two to three times with PBS 

to remove the percoll and centrifuged at 2000 rpm for 10 

minutes at 8 Cº. 

2.2. Culturing and expansion of MSCs 

The cell suspension was seeded in 50cm plastic tissue 

culture flasks with 5 ml culture medium and maintained at 

37C˚ in a humidified atmosphere with 5% CO2 for two 

weeks. Cultures of MSCs were inspected and refeed every 

three days and passaged when the MSCs have reached 

approximately 80% confluence (Javazon et al., 2001). The 

mesenchymal population was isolated on the basis of its 

ability to adhere to the culture plate. 

2.3. Cardiomyocytes differentiation of BM-MSCs in vitro: 

To stimulate the differentiation of MSCs in vitro to the 

cardiomyocytes progeny, the second passage of rat BM- 

MSCs were resuspended after trypsin treatment and seeded 

into 4-well culture plates at a density of 1X10 6 cell \ well. 

The second day after seeding, the tissue culture plates were 

divided into two groups as follows: 

• Control group: which were treated with MEM +10% 

FCS only without HME. 

• Treated group: which were treated with MEM +10% 

FCS and 0.1µl HME per 1ml medium. The cells of this 

group were cultured for three different periods: 1week, 

2weeks and 3weeks. 

The HME were prepared from the hearts of rat embryos 

of (18-19 days old) following the general principle of 

embryo extract preparation as described by New (1966) 

and modified by (Hammash and Waheed, 2004; and AL- 

Jumely, 2006). 

The medium was changed twice a week until the 

experiment was terminated. After that, the changes in 

morphology of treated cultures were reported and 

compared with the untreated (control) cultures. The cells 

in both groups were fixed with 4% phosphate buffered 

formalin for 10 minutes. The cells were detected using 

immunocytochemistry examination which was performed 

with primary monoclonal antibodies against anti-cardiotin 

and anti-myosin (Pochampally et al., 2004; Xu et al., 

2004). 

3. Results 

3.1. Effect of HME treatment on MSCs 

The results of the current study showed that the MSCs 

before HME treatment appeared elongated and flattened 

with a fibroblast like morphology (spindle like uni-polar or 

bipolar shape) (Fig. 1A). But after HME treatment, the

© 2010 Jordan Journal of Biological Sciences. All rights reserved - Volume 3, Number 1 187 

cells began to proliferate and differentiate during the first 

week (Fig. 1B). Approximately, 50% of all adherent cells 

had enlarged or increased in size and had formed a ball 

like appearance (Fig. 1C) or lengthened in one direction 

and formed a stick like morphology, these cells began to 

connect with adjoining cells in one week (Fig. 1D). 

Figure1: The morphology of differentiated MSCs in vitro in the first week of the second passage (before and after treatment with HME). 

(A): MSCs had fibroblast-like morphology (arrows) before HME treatment (X100.8). (B): the cells treated with HME began to proliferate 

(arrows) (X160). (C): some of adherent cells treated with HME enlarged and formed a ball-like appearance (arrows) (X160). (D): most of 

adherent cells lengthened in one direction and had formed stick-like morphology (arrows) and began to connect with adjoining cells 

(X100.8). 

At the end of second week, the cells began to connect 

to each others and then formed myotube-like structure 

(Fig. 2A). After three weeks, we noticed that most of the 

cells are mononuclear and some of them are binuclear but 

a few are extremely multinucleated (Fig. 2 B, C). The 

differentiated cells can be distinguished by the presence of 

a number of branches (Fig. 3 A, B), and these cells began 

to interface with each other to form cardiac-like cells (Fig. 

3 C). These morphologies changes of BM-MSCs during 

exposure to HME in treated groups during different 

exposed periods were not seen in control groups. 

3.2. Immunocytochemical Examination for Differentiation 

of Mesenchymal Stem Cells in vitro 

To determine if HME treatment can induce MSCs to 

express cardiac muscle specific or related proteins, an 

immunocytochemistry examination was performed with 

monoclonal antibodies against myosin and cardiotin (Fig. 

4, Table 1). 

The immunostaining of the differentiated MSCs with 

anti-myosin and anti-cardiotin at two and three weeks after 

HME treatment showed that about 80% of the resulting 

differentiated cells expressed these proteins which was 

found in the longitudinal sarcoplasmic reticulum of mature 

cardiomyocytes (Fig. 4 A, B, C). 

In contrast, the control groups expressed negative 

responses for these general (myosin) and specialized 

(cardiotin) (Fig 4 D). 

4. Discussion 

4.1. Effects of HME on MSC differentiation 

Mesenchymal stem cells which have been isolated from 

BM can be expanded and induced either in vitro or in vivo 

to terminally differentiate into osteoblasts, chondrocytes, 

neural cells, myotubes and hematopoietic-supporting 

stroma (Dennis and Charbord, 2002). The BM-MSCs can 

also be differentiated into skeletal and cardiac muscles 

using appropriate environmental conditions plus several 

growth factors (Tomita et al., 2002; Xu et al., 2004; Yoon 

et al., 2008). To direct the differentiation of MSCs into 

specialized population, the growth conditions of MSCs 

need to be changed in specific ways, such as adding 

growth factors to the culture medium or changing the 

chemical composition of the surface on which MSCs grow 

(Odorico et al., 2001). Consequently, we substituted these 

growth factors using rat embryonic HME as a crude source 

of stimulating factors for directing the differentiation of 

MSCs in vitro.

188 


A B 

C 

Figure 2: The morphology of differentiated MSCs in vitro at second passage after treatment with HME. (A): at the end of second week of 

culturing, the MSC cells connected with adjoining cells and began to form myotube-like structure (arrows) (X160). (B): at the third week of 

culturing, most of the cells are mononuclear (thick arrows) and some are binuclear (head arrow) but few are multinuclear (thin arrow) 

(X100.8). (C): the cells at third week, some of cells are mononuclear (thick arrows) and the other are binuclear (thin arrows) (X100.8).


Figure4: Immunocytochemical analysis for differentiation of MSCs in vitro in treated groups with HME at second passage. (A): The most 

of differentiated cells were positive for anti-myosin marker (brown color) (X100.8). (B): the most of differentiated cells were positive for 

anti-cardiotin marker (X100.8). (C): the differentiated cells at three weeks after HME treatment were positive for anti-cardiotin marker and 

some of these cells appeared binuclear (arrows) (X160). D: the MSCs in control groups were negative for anti-cardiotin marker (X100.8). 

Table1: Markers commonly used in the present study and characterized differentiated cell types. 

Markers Dilution Cellular distribution 

Anti-myosin 

1:10 

Anti-cardiotin 1:50 

Myoblasts, Myocytes 

Neonatal and mature 

cardiomyocyte 

The direction of differentiation of MSCs has been 

performed for the first time after treatment with HME at a 

concentration of 0.1µl/1mL media, which is considered as 

the optimal concentration for differentiation into myogenic 

cells with cardiomyocyte-like characteristics for different 

exposure periods. From the results of the present study, we 

observed the differentiation of BM-MSCs into cardiac-like 

cells in treated groups compared with control groups. This 

is confirmed with immunocytochemical analysis and the 

results of the present study are consistent with many of 

prior reports (Wakitani et al., 1995; Makino et al., 1999) 

that suggested that using 5-azacytidine induced BM-MSCs 

to differentiate into myogenic cells. These adherent and 

differentiated cells increased in size and formed a ball like 

appearance or formed a stick like morphology, and then 

formed myotube like structure which is a feature that was 

not present or detected in the control groups. The effects of 

HME treatment in stimulation and differentiation of MSCs 

in culture was similar to the effect of several materials 

Properties 

A component of structural and contractile protein found in 

myocyte 

A component of structural and contractile protein found in 

cardiomyocyte 

such as Amphotericin-B (Wakitani et al., 1995) or the drug 

5-azacytidine (Makino et al., 1999). 

The precise mechanism of how to induce BM-MCs to 

differentiate into muscle cells is unknown. In studies on 

myogenic differentiation of the mouse embryonic cell line 

with 5-azacytidine, Konieczy et al., (1984) proposed that 

these cells contain a myogenic determination locus in a 

methylated state with a transcriptionally inactive phase, 

which becomes demethylated and transcriptionally active 

with 5-azacytidine causing the cells to differentiate into 

myogenic cells . 

The use of HME to stimulate the differentiation of 

MSCs took three weeks of treatment which is longer than 

the period which caused the differentiation of MSc using 

the 5-azacytidine; the latter was for 24 h only (Makino et 

al., 1999; Xu et al., 2004). 

The role of these embryonic extract and as mentioned 

by Leor et al., (1996) is that most embryonic tissues are 

regarded as an important source of extracting factors that 

stimulate the growth and differentiation of stem cells into

190 


special direction. The newly differentiated cells can then 

be used for therapeutic angiogenesis. 

The critical role of extract also was observed by 

Waheed (Un-published data) when the induction of muscle 

differentiation from embryonic stem cells (ESCs) was 

carried in media containing New Born Bovine Serum 

(NBBS) and embryonic muscle extract. Additionally, the 

study made by (AL-Jumely, 2006) demonstrated that the 

differentiation of HSCs into muscle like cells in vitro 

could be done treating the colony of HSCs with HME of 

new born mice. 

4.2. Immunocytochemical Examination for Differentiation 

of Mesenchymal Stem Cells in vitro 

The results of the immunocytochemistry examination 

showed that the differentiated cells were positive when 

detected by anti-myosin antibody. This result is similar to 

different studies such as (Makino et al., 1999; AL-Jumely, 

2006) who suggested that the expression may be 

associated with activation of the myosin gene. 

Myosin is known to be an early marker of myogenic 

differentiation and myosin filaments are very important 

structures of muscle tissues that play an important role in 

contraction (Grigoriadis et al., 1988; Yablonka-Reuent, 

2005). The immunostaining analysis using anti-cardiotin 

marker demonstrated that most of the differentiated cells 

expressed this protein. These findings are similar to that 

described by Pochampally et al., (2004). 

Cardiotin is a high molecular weight protein complex 

(300KDa) located in the longitudinal sarcoplasmic 

reticulum (SR) of cardiac muscle. The cardiotin structure 

consists of subunits of 60KDa and 100KDa. During 

cardiac contractile dysfunction, a decreased in SR activity 

is detected (Schaart et al., 1993). 

According to the results of (Yoon et al., 2002) study, it 

was concluded that the cells from BM-MSCs co-cultured 

with rat neonatal cardiomyocytes expressed cardiac 

troponin I and other cardiac-specific proteins. When the rat 

cardiomyocytes were removed from the culture medium, 

the differentiation did not occur. These results confirm the 

important results obtained from the current study. We 

observed that MSCs when exposed to the culture medium 

without adding HME, the cells did not differentiate and 

were negative for anti-cardiotin marker. 

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JJBS 



ISSN 1995-6673 

Pages 193 - 202 

Mycobiota Associated with Sugarcane (Saccharum 

officinarum L.) Cultivars in Iraq. 

Samir K. Abdullah a,* and Yehya A. Saleh b 

a Biology Department, College of Education, Duhok University; b Plant Protection Department, College of Agriculture, Basrah University, 

Iraq. 

. 


During the study of the mycobiota associated with 

four sugarcane (Saccharum officinarum L.) cultivars 

(CO331, Co976, CP5-68, and Missan 1) currently 

cultivated for sugar production at sugarcane factory at 

Missan governorate, Southern Iraq, ten teleomorphic 

ascomycetes have been reported. These include 

Arxiomyces zubairiensis, Chaetomium atrobrnneum, 

C.convolutum, C.elatum, C.globosum, C.murorum, 

C.spiralotrichum, Coniochaeta saccardoi, Kerinia nitida 

and Leptosphaeria sacchari. All the identified species 

are reported for the first time on sugarcane plant in Iraq. 

A brief description along with photographs is provided 

for the reported species. 

Keywords: Sugarcane, Mycobiota, Ascomycetes, Iraq. 


Sugarcane (Saccharum officinarum L) is grown in 

tropical and subtropical regions of the world. The crop is 

introduced by the Arabs in the eight century A.D to the 

Mediterranean, Mesopotamia, Egypt, North Africa and 

Andalusia. By the tenth century, sugarcane cultivation was 

well established and some sources indicated that there was 

no village in Mesopotamia that did not grow sugarcane 

crop (Watson,1983). However, in recent Iraq, the 

production of the crop is restricted to Missan governorate, 

Southern Iraq (31 40 N-47 40 E). The first commercial 

production of the crop in Iraq was in 1965 after the 

building of a sugarcane factory at Al-Majar Al-Kabir town 

to the south of Missan governorate. The area cultivated 

with the crop is about 6000 hectar with average cane yield 

of 43.21 t/he which is far below the existing potential 

(Anonymous, 2002). 

Several pathogenic and saprophytic fungi have been 

reported as a mycobiota associated with sugarcane plant in 

several parts of the world (Watanabe, 1974, 1975 a,b,c; 

Zummo,1986, Sivanesan and Walter,1986; Dosayla et 

al.,1993; Magarey,1986,1995; Mena Partalos et al.,1995; 

Fernandez et al,.1995; Egan et al.,1997; Lopez Mena et 

al.,1999; Aoki, 2000). 

* Corresponding author. samer_abdalh@yahoo.com. 

ﺮﻜﺳ تﺎﺒﻨﻟ فﺎﻨﺻأ ﺔﻌﺑرﻻ ﺔﺒﺣﺎﺼﻤﻟا ﺔﻳﺮﻄﻔﻟا ﺔﻋﻮﻤﺠﻤﻟا ﺔﺳارد لﻼﺧ 

ﻲﻓ ﺮﻜﺴﻟا ﺔﻋﺎﻨﺼﻟ ﺔﻣﺎﻌﻟا ﺔآﺮﺸﻟا لﻮﻘﺣ ﻲﻓ ﺎﻴﻟﺎﺣ ﺔﻋورﺰﻤﻟا ﺐﺼﻘﻟا 

تﺎﻳﺮﻄﻔﻟا ﻦﻣ عاﻮﻧأ 

ةﺮﺸﻋ ﺺﻴﺨﺸﺗ ﻢﺗ ،قاﺮﻌﻟا 

بﻮﻨﺟ – نﺎﺴﻴﻣ 

: ﻲهو ﺔﻴﺴﻴﻜﻟا 

Arxiomyces zubairiensis, Chaetomium atrobrnneum, 

C.convolutum, C.elatum, C.globosum, C.murorum, 

C.spiralotrichum, Coniochaeta saccardoi, Kerinia nitida 

and Leptosphaeria .sacchari. 

ﻲﻓ ﺐﺼﻘﻟا ﺮﻜﺳ 

تﺎﺒﻧ ﻰﻠﻋ ةﺮﻣ لوﻷ ﻞﺠﺴﺗ ﺔﺼﺨﺸﻤﻟا عاﻮﻧﻷا ﻊﻴﻤﺟ 

رﻮﺼﻟﺎﺑ ةزﺰﻌﻣو رﺎﺼﺘﺧﺎﺑ ﺔﻠﺠﺴﻤﻟا عاﻮﻧﻷا ﺖﻔﺻو . قاﺮﻌﻟا 

. ﺔﻴﻓاﺮﻏﻮﺗﻮﻔﻟا 


In Iraq, however, studies on the mycobiota associated 

with sugarcane crop were restricted to internal reports 

made by the staff of the Directorate of General State for 

Sugarcane Production at Missan on the incidence of 

sugarcane smut (Ustilago scitaminea) on the cultivar 

NCO310 at Missan fields (Karam, 1983,1987) and on the 

microbiota responsible for deterioration of sugarcane juice 

(Mansour et al.1979). More recently, Abdullah and Saleh 

(2010) reported 16 mitosporic fungi assigned to the genera 

Alternaria (5 species), Bipolaris (4 species), Curvularia , 

Exserohilum (3 species each) and Drechslera (1 species). 

This paper reports the identification of ten ascomycetous 

fungi. 


A total of 60 pieces of living and dead leaves and 

stems (2 cm long) from four sugarcane cultivars or hybrids 

(C0331, C0976, CP5-68 and Missan1) were washed for 

several times with tap water and then rinsed three times 

with sterile distilled water. Washed pieces were plated on 

moist blotter and in plates containing PDA medium (200g 

potato, 20g dextrose, 20g agar and 1L distilled water) with 

chloramphenicol (250 mg/l) and incubated under 12h of 

darkness alternating with 12h of cool white fluorescent 

light. Plates were examined every 3 d for 3 wk. To achieve 

pure cultures, ascospores were transferred from the natural 

substrates or from the PDA plates to new PDA plates.

194 


Identification of isolates was made according to Malloch 

and Cain (1971), Arx et al. , (1986), Sivanesan and 

Waller(1986), Checa et al., (1988) and Abdullah and Al- 

Saadoon (1994). Specimens (dried cultures) of the reported 

species have been deposited at Basrah University 

herbarium (BSRA). 

3. Results and Discussion 

Arxiomyces zubairiensis Abdullah and Al-Saadoon. 

Marina Mesopotamica 9:246 (1994). Figs.1 and 2. 

Figures (1 and 2). Arxiomyces zubairiensis, 1-ascospores, 2-ascomata. 

Bar 1= 5µm Bar 2= 50µm. 

Ascomata superficial to semi-immersed, were dark This is the first record of the fungus on sugarcane plant 

brown to black due to spore mas, globose, 170-250 µm, in Iraq. However, the fungus has been repeatedly isolated 

glabrous or slightly hairy, neck-pale , yellow brown , from Iraq from soil at date palm plantation (Abdullah and 

cylindric, 40-80 X 35-40 µm. Asci 4-spored, broadly Zora,1993), from corn grains (Abdullah and Al-Mousawi, 

clavate, 9-11.5 X 13-16 µm, and evanescent. Ascospores 2006), from medicinal plants ( Abdullah et al., 

in turn were globose to subglobose with a truncate base 2002;2008), from sediment of Shatt Al-Arab River and 

and rounded apex ,4-5 µm diameter, and at first hyaline Southern marshes (Abdullah and Abbas ,2008; Abdullah 

becomes dark brown to black in mass, and smooth walled, et al., 2010). 

with a single large basal germ pore, 3.5-4 µm diameter. 

Chaetomium convolutum Chivers. Proc.Amer.Acad. 

Specimen examined: BSRA 11155. On dead stem of 48:85 (1912). Figs.5 and 6. 

cultivar C0331, November, 2001. This is the first record of Ascomata obovate to ovate, dark brown, superficial 

the species on sugarcane plant. The type species was 130-200 µm. Terminl hairs are spirally coiled, brown, 

originally described from Iraq (Abdullah and Al- septate, thick-walled , verrucose, or warty, and 4-5 µm 

Saadoon,1994) parasitizing Stachybotrys sp.on Phragmitis thick. Lateral hairs are seta-like, olive to brown, shorter 

australis dead stem collected from tidal zone of Khawr Al- than terminal hairs. Asci 8-spored, clavate, evanescent. 

Zubair canal, Southern Iraq. A.zubairiensis differes from Ascospores limoniform, slightly apiculate at both ends, 

two other known species in the genus ( A. vitis (Fuckel) pale brown at maturity, bilaterally flattened, 6-9 X 4-7 µm. 

P.F.Cannon and D.Hawksworth and A. campanulatus Specimen examined: BSRA 11161. Isolated from dead 

Horie, Udagawa and P.F.Cannon) by its globose to stem of C0371 cultivar, May, 2001. This is the first record 

subglobose ascospores, whereas ,the former two species for the species from Iraq. 

are characterized by having ovoid to ellipsoidal Chaetomium elatum Kunze, Mycol. Hefte 1:16 (1817). 

ascospores. 

Figs.7 and 8. 

Chaetomium atrobrunneum L.M.Ames. Mycologia Ascomata are spherical or ovate, superficial, 170-350 

41:641 (1949).Figs.3 and 4. Ascomata superficial, µm. Hairs are long dichotomously branched, verrucose or 

ostiolate, 60 – 150 µm. Terminal hairs arising around the warty, septate, 4-5 µm thick at base. Asci are 8-spored, 

ostiole , straight, septate, smooth brown in colour, tapering clavate, evanescent, 30-40 X 12-18 µm. Ascospores are 

at end, 3-4 µm broad at base. Lateral hairs are similar but liminiform, thick-walled, 7-11 X 6.5-8 µm, bilaterally 

slightly shorter. Asci 8-spored, clavate, vanescent. flattened , and brown at maturity, with an apical germ 

Ascospores fusiform or elongate pyriform, grey brown at pore. Specimen examined: BSRA 11162. Isolated from 

maturity, 9-15 X 4-7.5 µm, with subapical germ pore. 

Specimen examined: BSRA 11160.Isolated from stem of 

P52-68 cultivar, March, 2002. 

leaves of C0331 cultivar, September 2001.


Figures (3 and 4). Chaetomium atrobrunneum, 3-ascomata, 4-ascospores. 

Bar 3= 100 µm. Bar 4= 10µm. 

Figures (5 and 6). Chaetomium convolutum. 5-ascospores, 6-ascomata. 

Bar 5=10µm. Bar 6= 100µm. 

195

196 


This is the first report for the fungus on sugarcane plant 

in Iraq. However, the fungus has been previously isolated 

from different habitats in Iraq (Abdullah and Zora,1993), 

Abdullah and Al-Mousawi, 2006; Abdullah and Abbas 

,2008). 

Chaetomium globosum Kunze. Mykol.Hefte 

1:16(1817). 

Figs.9 and 10. Ascomata olive brown, ovate or 

obovate, ostiolate,superficial, 160-270 µm in size. 

Ascomatal hairs flexuous, undulate or coiled, usually 

unbranched,septate, brownish, 3-5 µm wide. Asci 8spored, 

clavate, 30-36 X 11-15 µm, evanescent. 

Ascospores liminiform usually basiapiculate, brownish at 

maturity, 9-12 X 8-10 µm, with an apiculate germ pore. 

Specimen examined: BSRA 11163. Isolated from stem 

of Missan 1 cultivar, September,2001. The species is 

common to all cultivars. This is the first report for the 

species on sugarcane plant in Iraq. However the fungus has 

been reported from different habitats in Iraq, including 

desert soil (Abdullah et al., 1986), corn grains (Abdullah 

and Al-Mousawi,2006), surface sediments of rivers and 

marshes (Abdullah and Abbas, 2008; Abdullah et al., 

2010) and herbal drugs (Abdullah et al., 2002). The 

species has been reported on sugarcane in India and 

Pakistan (Sivanesan and Waller,1968) and from 

sugarcane in Cuba (Hernandez et al., 1995). 

Chaetomium murorum Corda. Icon.Fung. 1:24 (1837). 

Figs.11 and 12. 

Ascomata superficial, spherical, dark olive, 145-230 

µm. Ascomatal hairs long, flexuous or undulate, thickwalled, 

septate, brown, 4-6 µm thick. Asci 8-spored, 

clavate 30-45 X 10-20 µm, evanescent. Ascospores 

ellipsoidal, 10-15 X 7-9 µm, with a distinct apical germ 

Figures (7 and 8). Chaetomium elatum. 7-ascospores, 8-ascomata. 

Bar 7=10µm. Bar 8=100µm. 

pore. Specimen examined: BSRA 11164. Isolated from 

leaves of cultivar C0331, January, 2001. 

This is the first report for the species on sugarcane 

plant in Iraq. However, it has been isolated from other 

sources (Abdullah and Zora,1993; Abdullah and Abbas, 

2008). 

Chaetomium spiralotrichum Lodha. J.Indian 

Bot.Soc.43:134 (1964). Figs,13 and 14. Ascomata 

spherical to ovate, ostiolate, dark brown, 110-180 µm. 

Ascomatal hairs flexuous, or spirally coiled, often forming 

long coils, indistinctly septate. Asci evanescent, 30-38 X 

13-16 µm. Ascospores ellipsoidal, olivaceous brown, 9-11 

X 5-7 µm with a distinct apical germ pore. Specimen 

examined: BSRA 11165. Isolated from dead leaves of 

Missan 1cultivar, November, 2001. This is the first report 

for the fungus in Iraq. 

Coniochaeta saccardoi (Marchal) Cain. Univ. Toronto 

Stud. Bot. Ser.38:65 (1934).Figs.15-18. Ascomata 

superficial,globose to pyriform, ostiolate, dark brown to 

black, 105 -280 µm, covered with setae, 20-80 X5-7 µm, 

swollen at base. Asci 8-spored, cylindrical, without distinct 

apical ring, 70-80 X5-8 µm. Ascospores uniseriate , onecelled, 

dark brown to black, narrowly ellipsoid, 8-10 X4-6 

µm with longitudinal germ slit. 

Specimen examined: BSRA 11166. Isolated from dead 

leaves and stems of Missan 1 cultivar. March, 2001. 

This is the first report for the fungus on sugarcane plant 

in Iraq. However, the species was previously reported on 

submerged dead palm leaves ( Al-Saadoon and 

Abdullah,2001). 

Kernia nitida (Saccado)Nieuwland. Amer. Midland 

Natur. 4:379 (1916). Figs,19 and 20. 

Ascomata varying in shape, irregular in outline, black 

opaque, non-ostiolate, 120-220 µm. Ascomatal appendages


arising in fascicles from two points, black, thick-walled, 

unbranched up to 1000 µm long and 5-7 µm wide. Asci 8spored, 

ovoid to globose, evanescent. Ascospores 4-6 X3-4 

µm, ellipsoidal, orange brown to copper-coloured in wet 

mass, thin-walled, smooth with a prominent de Bary 

197 

bubble, with germ pore at each end. Specimen examined: 

BSRA 11177. Isolated from dead stem of C0331 cultivar. 

March,2002. This is the first report for the fungus on 

sugarcane plant in Iraq. 

Figures (9 and 10). Chaetomium globosum. 9-ascospores, 10-ascomata. 

Bar 9= 10µm. Bar 10=100µm. 

Figures (11 and 12). Chaetomium murorum. 11-ascospores, 12-immature ascomata. 

Bar 11=10µm. Bar 12=100µm.

198 


Figures (13 and 14). Chaetomium spiralotrichum. 13-ascospores, 14-ascomata. 

Bar 13= 5µm. Bar14=100µm. 

Figures (15 - 16). Coniochaeta saccardoi. 15-asci, 16- ascomata, 17-setae. 18-ascospores. 

Bar 15=50µm, Bar 16=100µm, Bar 17= 50µm, Bar 18= 10µm.


Figures (17 - 18). Coniochaeta saccardoi. 15-asci, 16- ascomata, 17-setae. 18-ascospores. 

Bar 15=50µm, Bar 16=100µm, Bar 17= 50µm, Bar 18= 10µm. 

Figures (19 and 20). Kernia nitida 19-ascospores. 20-ascomata. 

Bar 19= 5 µm. Bar 20= 100µm. 

199

200 


The species is commonly found on dung of various 

herbivore animals as well as frequently isolated from soil 

and decaying plant materials (Malloch and Cain,1971). In 

Iraq, however, the fungus was isolated from various dung 

types (Abdullah,1982), and from soil in several occasions 

(Abdullah et al., 1986,2007). Leptosphaeria sacchari Van 

Breda de Haan. Meded. Proefstat suilcerr.W.Jeva 3:25 

(1892).Figs.21 and 22. 

Figures (21 and 22). Leptosphaeria sacchari. 21- asci and ascospores. 22- ascomata. 

Bar 21= 10µm. Bar 22= 50 µm. 

Ascomata globose to subglobose up to 200 µm size. 

Asci oblong-cylindric, 8-spored 40-60 X 8-12 µm. 

Ascospores oblong, fusoid, straight to somewhat curved, 

biseriate, subhyaline to light yellow brown, 3-septate, 18- 

23 X3-5.5 µm. Specimen examind: BSRA11178. Isolated 

from living leaves of CO331, July ,2001. 

This is the first record for the species in Iraq. The 

fungus was identified among the fungi causing ring spot of 

sugarcane leaf disease with a worldwide distribution 

(Hudson, 1962; Sivanesan and Waller,1986). 

References 

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