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Diversity and Taxonomic Distribution of Endophytic Bacterial Community in the Rice Plant and Its Prospective
Abstract
Endophytic bacterial communities are beneficial communities for host plants that exist inside the surfaces of plant tissues, and their application improves plant growth. They benefit directly from the host plant by enhancing the nutrient amount of the plant’s intake and influencing the phytohormones, which are responsible for growth promotion and stress. Endophytic bacteria play an important role in plant-growth promotion (PGP) by regulating the indirect mechanism targeting pest and pathogens through hydrolytic enzymes, antibiotics, biocontrol potential, and nutrient restriction for pathogens. To attain these benefits, firstly bacterial communities must be colonized by plant tissues. The nature of colonization can be achieved by using a set of traits, including attachment behavior and motility speed, degradation of plant polymers, and plant defense evasion. The diversity of bacterial endophytes colonization depends on various factors, such as plants’ relationship with environmental factors. Generally, each endophytic bacteria has a wide host range, and they are used as bio-inoculants in the form of synthetic applications for sustainable agriculture systems and to protect the environment from chemical hazards. This review discusses and explores the taxonomic distribution of endophytic bacteria associated with different genotypes of rice plants and their origin, movement, and mechanism of PGP. In addition, this review accentuates compressive meta data of endophytic bacteria communities associated with different genotypes of rice plants, retrieves their plant-growth-promoting properties and their antagonism against plant pathogens, and discusses the indication of endophytic bacterial flora in rice plant tissues using various methods. The future direction deepens the study of novel endophytic bacterial communities and their identification from rice plants through innovative techniques and their application for sustainable agriculture systems.
1. Introduction
Plants can build a relationship with their ecosystem members to enhance growth and development in natural environments, as well as maintaining an ecological niche for thriving microbes. Numerous kinds of microorganisms, including bacterial and fungal communities, are harboring plant compartments that have been isolated and identified by using plant tissues and are nominated as endophytes. A majority of endophytes colonize with different parts of the plant apoplast, proliferating among the cellular spaces, including xylem vessels. Endophytes can also colonize plant reproductive organs, such as flower buds, flower petals, fruits, and seeds [1]. For the first time, the isolation of the endophytic bacteria was carried out by Samish and Mund [2] after surface sterilization of the plant tissues. Afterward, many researchers successfully categorized and reported more than 200 genera of endophytic bacteria from different plant tissues. These genera belong to the 16 phyla that are culturable and unculturable endophytes: Acidobacteria, Aquificae, Actinobacteria, Bacteroidetes, Chloroflexi, Chlorobi, Cyanobacteria, Proteobacteria, Firmicutes, Deinococcus-thermus, Fusobacteria, Planctomycetes, Gemmatimonates, Nitrospira, Spirochaetes, and Verrucomicrobia [1,3]. However, there is no such compressive report on phylum numbers identified from rice plant tissues. The previous literature revealed that several endophytes represent the three main phyla, namely Proteobacteria, Firmicutes, and Actinobacteria, comprising members of Azoarcus [4], Bacillus [5], Enterobacter [6], Gluconobacter, Stentrophomonas [7], Herbaspirillum [8], Pseudomonas, Serratia [9], and Streptomyces [10].
Rice (Oryza sativa L.) is the most widely important grown cereal crop and is consumed by more than 50% of the world’s population [11]. The ever-increasing world population demands sustainable agriculture production to feed 7.3 billion people; that population may become 9.7 billion up to 2064 (estimated by the United Nations (UN) [12,13]). An increasing population needs a high yield of rice to compete for this competition, but it must be achieved without, or by minimizing, the application of synthetic products due to high concern about environmental protection. Still, the main source of crop improvement in the agriculture sector is the practice of applying synthetic products, such as commercial fertilizers, nutrient supplements, insecticides, and pesticides. This action has hazardous effects on the environment and human and livestock health. The farmer communities are convinced to change their old practices by using alternative products that could be environmentally friendly [14]. The bio-fertilizers and pesticides consist of non-pathogenic microorganisms; this uniqueness in nature facilitates attaining sustainable agriculture and environmental protection from chemical hazards. Additionally, bio-formulations might be the best alternative option to reduce environmental degradation and the threat to human health.
In the European Union Pesticides Database [15], several registered bio-fertilizers and pesticides containing bacterial products are mainly synthesized by using Bacillus species and Pseudomonas species. In China, Fang [16] reported the sources of registered bio-fertilizer products; these can be the single and combination of the bacterial strains of Bacillus species (B. licheniformis, B. amyloliguefaciens, B. megaterium, and B. subtilis) and Lactobacillus plantarum, Paemibacillus mucilaginosus, and other species. These abovementioned members of genera are dominated among plants, soil, and under other environments, due to salient features, such as rapid proliferation and simple diet requirements, which can assist in easy propagation of bacteria in the environment. The above-highlighted bacteria are famous as beneficial organisms for plant growth, as well as for producing many metabolites to improve plant health. Therefore, these genera could be the best choice for preparing potential inoculants by mixing bacterial strains due to their diversified adaption to multiple environmental factors, such as pH, low and high temperature, salinity, and high metals, as well as the ability of their cells to remain alive in diverse environments for a long time [17]. Importantly, the endophytic bacterial strains that are beneficial for growth promotion and disease suppression will be a better choice for making bio-preparations and minimize the risk of drawbacks and promote environmental protection. Endophytic bacteria can invade and colonize within plants in such a way that they are specific and remain intact. Moreover, strains of endophytic bacteria can enhance plant protection from phytopathogens and improve plant immunity.
The prominent abilities of endophytic bacteria to improve plant growth and minimize pathogen infestation via direct and indirect mechanisms [18,19] are attracting scientists globally. Direct mechanisms are set up to apply to those bacterial traits that directly promote plant growth. They include the production of Indole-acetic-acid (IAA), 1-aminocyclopane-1 carboxylic acid (ACC), and Gibberellic acids (GA), and also facilitate the uptake of fixed nitrogen, siderophore, phosphorus, and zinc production. Under indirect mechanisms, endophytic bacteria improve plant growth by acting as biocontrol agents. In addition, many endophytic bacteria have been reported to produce compounds classified as secondary metabolites for inhibition of pathogens, and they also adopt different mechanisms in order to produce cell wall degrading enzymes, antibiotics, competition and induced systemic resistance (ISR) [20].
Herein, we describe the comparative information of endophytic bacteria inhibit the rice plant, as well as their plant-growth-promoting traits and their biocontrol activity against pathogens; we also describe the innovative techniques and bioinformatics tools that may help to identify the key endophytes communities and plant growth-promoting genera. In addition, we discuss their phyla, classes, orders, families, genus, and species abundances in the different genotypes of rice plants.
2. Endophytic Bacterial Diversity in the Rice Plant
To study the endophytic bacteria taxonomic flora in the rice plant, we collected the prehistoric taxonomic data until 2020, with their plant-growth-promoting traits and their antagonism against phytopathogens, using the National Centre of biotechnology information (NCBI) PubMed (https://pubmed.ncbi.nlm.nih.gov/, accessed on 25 September 2020), Google Scholar (https://scholar.google.com/, accessed on 25 September 2020), and SciencDirect (https://www.sciencedirect.com/, accessed on 25 September 2020) web portals; after that, we plotted the taxonomic tree by writing a self-script in Python 2.7 [21] to convert the excel file into Newick format; the further Newick-format file was visualized and edited in iTOL version 5 [22]. Our data analysis showed 4 phyla, 6 classes, 22 orders, 46 families, and 74 genera of endophytic bacterial communities that have been mined from rice parts based on a culture-dependent method; complete details of taxonomic distribution are visualized in Figure 1. Moreover, our data analysis showed that the phylum Proteobacteria has a high abundance among rice tissues, while Bacteroidetes has a lower abundance (Figure 2A). To seek more details at the class level, we plotted the 3D-chord diagram to visualize the overlapping and diversity of classes within rice tissues. As a result, Gamma proteobacteria and Bacilli were more diversified and overlapped among rice tissues in contrast to Betaproteobacteria, Flavobacteria, and Sphingobacteria (Figure 2B).
The majority of the endophytic bacterial diversity was isolated from root portions that displayed more diverse communities. Many researchers isolated Bacillus, Pantoea, Methylobacterium and Sphingomonas genera, they are in high abundance with diverse species from the seed [23,24], root [25,26], and leaf part [27,28] of the rice plant (Supplementary Materials Data 1, Figure S1). Most species of Rhizobium, Azospirillum, Burkholderia, and Herbaspirillum were isolated from root tissues with distinct species [29,30,31,32], and Xanthomonas, Flavobacterium, and Knoellia genera were isolated from seeds (Supplementary Materials Data 1, Figure S1) [33,34]. These endophytes genera also have been identified after isolation from different plants, such as ben tree, (Moringa peregrina) [35], maize (Zea mays) [36,37], Datura metel (local name Devil’s Trumpet) [38], Kudouzi (Sophora alopecuroides) [39], Scots pine (Pinus sylvestris) [40], strawberry (Fragaria ananassa) [41,42], wheat (Triticum aestivum L.) [43], rose gum (Eucalyptus grandis) [44], sugarcane (Saccharum officinarum) [45], grapevine (Vitis vinifera) [46,47], poplar (Populus deltoides) [48], pepper (Capsicum annuum) [49], Huang-Qin (Scutellaria baicalensis Georgi) [50], cotton (Gossypium hirsutum) [51], potato (Solanum tuberosum) [52], cucumber (Cucumis sativus) [53], tobacco (Nicotiana tabacum L.) [54], peanut (Echinopsis chamaecereus “Lutea”) [55], tulasi (Ocimum sanctum) [56], and pea (Pisum sativum L.) [57]. Few studies have reported that bacterial genera are specific for seed colonization; for example, the Pseudomonas putida mutant during the secretion-system investigations displayed the reduction in their potential to colonize with maize seeds [58]. On the other hand, rice root endophytic bacteria are more diverse [25,59] compared to seed endophytes [60,61]; complete details can be visualized in Figure 1.
Seeds can also be colonized by bacteria existing on the surfaces of flower petals, fruits, and stems [62,63], and by additional pollen grains’ bacteria [64] that may be associated with ovules after pollination processes [65]. Root endophytic bacteria can be explored by using the soil surrounding plant roots or plant litter [36,66]. Moreover, endophytic bacterial diversity variation is associated with physicochemical properties of soil, as well as atmospheric conditions, cropping history, geographic location, and other agricultural practices [36,67,68]. In certain studies, it is suggested that root endophytic bacteria can mainly exist among the rhizosphere parts, and some of them can migrate through the xylem track to colonize the aerial parts [69,70].
Seed-borne pathogens can be persistent among new generations of plants. In the same way, seeds can also be harbored by endophytic bacteria that might be hereditary to new generations. Non-pathogenic bacteria have been categorized, from seeds and roots, parts of rice [25,29], maize [37], wheat [71], and other plants [37,72,73]. Many endophytes responsible for plant-growth-promoting traits (such as IAA, ACC, siderophore production, nitrogen fixation, phosphorus production, zinc solubilization, and ammonia production) have been isolated from leaves, seeds, stems, and roots of rice plants (Figure 1). These beneficial endophytes assist the host plants to maintain their growth and increase immunity against phytopathogens.
3. Factors Involving in Endophytic Bacterial Communities’ Variations
Endophytic bacterial communities strongly vary by environmental factors, numerous factors affecting endophytic bacterial diversity, such as host plant genotype, age of the plant, agricultural practices, and multi-kinds of nutrient availability, may help to increase bacterial diversity with diverse genera [74]. It is reported by Hardoim et al. [62] that the rice endophytes community varies with the growth stages of rice plants. The genotype of rice plants strongly influenced the endophytes community types [75]. It is well documented by Khaskheli el al. [25,59] that different rice cultivars planted in the soil containing same physiochemical properties can have distinct endophytic taxonomic composition and diversity. Thus, the soil physicochemical properties and different genotypes of plants can determine the endophytes communities’ composition. Numerous studies reported that the same genotypes of plant species were grown in different soil types having diverse endophyte communities with distinct taxonomic profiles [36]. Recently, climate conditions are influencing endophytic bacterial diversity composition and taxonomic variations [76,77]. For instance, Ren et al. [78] reported that rice endophytes’ bacterial community composition and their diversity are significantly affected by climate conditions. It is observed by Walitang et al. [79] that rice’s endophytic bacterial community diversity and diverse genera profile are influenced by salt concentration in the growth environment. Researchers reported that the resistant genotypes of different plant species against phytopathogens harbor a major portion of the endophytic bacterial community antagonistic to certain phytopathogens comparative to susceptible genotypes [80]. Andréa et al. [80] illustrated that the endophytes community was different from symptomatic and non-symptomatic samples of Colletotrichum spp. and Paullinia cupana, respectively. Hence, the selection of the endophytic bacteria community process is a very complex process, which is firmly controlled by the host plant tissues, it is well documented by Berendsen et al. [68] that plant roots play an essential role for the retrieval of microbiome community from soil.
4. Method for Isolation and Identification of Endophytic Bacteria
A majority of plant endophytic bacterial communities have been isolated and identified through culture-dependent methods [23,24,25,26,59,60,75,81,82,83,84,85]. However, to study the endophytic bacteria diversity by using these methods, the bacterial strains must be culturable under in vitro conditions. For endophytes, bacterial strains isolated from plant samples are completely dependent on the isolation procedure. The most common track for the isolation of endophytic bacteria diversity from rice tissues using a culture-dependent method which can be visualized in Figure 3, but each study uses a different concentration of surface sterilization agent according to the sample size, shape, and thinness of the rice tissues [27,86]. The surface sterilization of rice samples was carried out by using sodium hypochlorite (NaClO) with different concentrations, and then the samples were washed with 70% ethanol solution at the end, to use sterilize distilled water for removing traces of chemical solutions from samples [60,87]. For the confirmation of the effectiveness of the surface sterilization procedure, the last washing water is plated on the culture medium. Moreover, culture medium is very important to explore the endophytic bacterial diversity; for rice endophytes bacteria, most of the studies used Tryptone soya agar (TAS) medium, which is also known as a Trypticase soy agar [31,60,86,88,89]. Endophytes bacteria populations are dependent on the type of growth media used to culture the bacteria from plant tissues, host plant growth environment, and surface sterilization method to plant tissues. Growth-medium selection highly affects the number and divers of endophytes bacteria communities; indeed, there is no a single growth medium which can fulfill the growth requirements and nutritional values of all bacteria [90]. However, the abundance of culturable microorganisms is less than 1% in the environment, and this may be due to their unknown nutrient requirements or in vitro conditions, or due to the fact that a few microbes’ cells cannot be culturable, even if their cells are visible under an in vitro environment [78,91].
Further culturable bacteria identification is based on their morphological, physiological growth habits, and biochemical and molecular techniques [92]. Several kinds of molecular markers were available for the identification of specific microbial taxa. Among them, the most famous 16S rRNA gene markers were used for bacterial phylogeny analysis and their taxonomic classification. For rice endophytic bacterial taxonomic classification, most of the researchers amplify the 16S rRNA gene by using 27F (forward primer) and 1492R (reserve primer) for the identification and the taxonomic position [24,25]. Currently, the taxonomic classification of prokaryotes is based on a combination of steps from phenotypic, chemo-taxonomic, and genotypic data; this process is commonly known as poly-phasic taxonomy [93]. These steps provide sufficient information for taxonomic classification for most phyla of bacteria, but these steps are not sufficient for the Actinobacteria phylum [94]. Accurate taxonomic classification of Actinobacteria phylum can be achieved by using whole-genomic sequencing (WGS) [95,96]. Further genomic data proceed through DNA–DNA hybridization (DDH) analysis to attained authentic taxonomic classification of Actino-bacterial species [97]. Moreover, average nucleotide identity (ANI), including multilocus sequence analysis (MLSA), is highly recommended for genetic taxonomic profiles [98].
The culture-independent methods inhibited the culture-dependent methods and provided fast and true endophytes bacteria taxonomic. The genomic DNA (gDNA) extraction from surface-sterilized plant tissues, after that selective culture-independent method, was used to identify the endophytes communities (whole procedure is visualized in Figure 3). Moreover, several fingerprinting techniques can rely on the gDNA to amplify the specific gene marker of microbes; the most common known marker is the 16S rRNA gene for bacterial diversity analysis [99]. Several fragments of the 16S rRNA gene were amplified through DNA fingerprinting techniques, such as temperature gradient gel electrophoresis (TGGE), Amplified rDNA Restriction Analysis (ARDRA), Terminal Restriction Fragment Length Polymorphism (T-RFLP), denaturing gradient gel electrophoresis (GGGE), and automated ribosomal intergenic spacer analysis (ARISA) [100,101,102,103]. The culture-independent method has been utilized to obtain sequenced data, using Sanger sequencing and next-generation sequencing (NGS). For the identification of rice’s endophytic bacterial diversity, many researchers used Sanger sequencing [26,104,105]. A few studies used NGS for rice leaves and root endophytic bacterial community analysis [106,107]. In recent year, NGS applications have been excessed more in microbiome data analysis to identify the endophytic bacterial diversity from potato, spinach (Spinacia oleracea), lettuce (Lactuca sativa), and from the roots and leaves of Arabidopsis thaliana [108,109]. This method has been used to sequence the whole genome of plant endophytes’ microbe diversity and assign their true taxonomic afflictions [110].
5. Mechanism of Plant-Growth Promotion by Endophytes
The endophytic bacteria have been revealed to indirectly or directly transmit beneficial effects to their host plant. They can directly support plants to enhance the availability of easily usable nutrients and by regulating growth substances (phytohormones), which can increase growth and development of plants under normal and abnormal conditions [111]. The indirect mechanism, the endophytic bacteria, improves plant growth by decreasing the level of ethylene in plants, producing antibiotics and compounds for the inhibition of pathogens, producing cell-wall-degrading enzymes, and stimulating systemic resistance [112]. However, the direct mechanism of endophytic bacteria facilitates the host plant by increasing the uptake of phosphorus and helps the plant in establishing the biological nitrogen fixation, zinc solubilization in roots, and phytohormones within plants (e.g., IAA, ACC, and GAs) [20]. Herein, we discuss and summarize these mechanisms below.
5.1. Direct Plant-Growth Promotion by Endophytes
An adequate amount of nutrients that are required for plant growth, which are typically deficient in soils, can be attained through endophytic bacteria. They have the potential to increase and provide certain kinds of nutrients to the host plant, such as nitrogen, iron, and phosphorus. Details of these nutrients and responsible processes and/or mechanisms are discussed below.
Biological Nitrogen Fixation
Endophytic bacteria, express nitrogenase activity, which can play a role to fix atmospheric nitrogen in an available form for their host plants. Nitrogenase is a highly conserved protein, and this enzyme is commonly found in all nitrogen-fixing bacteria, with sufficient proof proposing that lateral gene essential components for biological nitrogen fixation, according to Ivleva et al. [113]. Ambient dinitrogen exists more than 78% in the atmosphere that is unavailable for direct plant consumption without conversion to available ammonia form for plant uptake. Several rice endophytic bacterial species help to increase the nitrogen fixation, such as Azoarcus sp. BH72, Herbaspirillum seropedicae, Burkholderia sp., and Gluconacetobacter diazotrophicus, have been reported to increase N2 fixation among the host plant and improve plant biomass under aseptic conditions [60,114]. There are three main processes for atmospheric nitrogen conversion into a usable form for plants: (i) the formation of the nitrogen oxides in the atmosphere from atmospheric nitrogen; (ii) the industrial formation of ammonia via processing the atmospheric nitrogen under catalytic processes in the presence of a high temperature (300–500 °C); and (iii) biological nitrogen fixation via microorganisms by utilizing complex procedures with the help of enzymes, such as nitrogenase, that effectively convert atmospheric nitrogen into ammonia [115,116] (see Figure 4A).
Biological nitrogen fixation is the key process that is fixing about 60% atmospheric nitrogen on the earth. Moreover, it is more environmentally friendly and economically valuable than industrial chemical fertilizers [116,117]. Nitrogen fixation takes place among non-leguminous crops by Plant-Growth-Promoting Rhizobacteria (PGPR) formally, known as diazotrophs [118]. The nitrogen fixation mechanism comprises the activity of nitrogenase, which is encoded by nif genes [119]. In bacteria, the nitrogen-fixation system has variations among different bacteria depending on the environments and, importantly, their growth rate [120]. Endophytic bacteria colonize within plant tissues/parts (e.g., leaves, stem, roots, and even reproductive organs), have the ability to fix atmospheric nitrogen, promote the plant growth, and protect plants from pathogens infestation [121,122,123]. Previous studies showed that the endophytic bacteria from rice, wheat, and maize, such as species of Burkholderia genus, Enterobacter asburiace, and Herbaspirillum seropedicae, and including other bacteria species of the Azotobacter genus, which are potential biological nitrogen fixers [1,60,124]. However, Carrell and Frank [125] have noted that the G. diazotrophicus strain has a great potential for nitrogen fixation, and it forms a symbiotic relationship with sugarcane and pine plants.
5.2. Availability of Phosphate
Phosphorous is also an essential micronutrient which is vital for enzymatic reactions after nitrogen that are necessary for many physiological processes in plants [126]. However, much of the soil’s phosphorous is not available in suitable forms that can be absorbed by plants. Plants can only absorb the soluble forms, mono- and dibasic phosphate. Besides, it is estimated that 75% of phosphorus application during agricultural practices in the form of fertilizer becomes unavailable for the plants from soil [127]. Endophytic bacteria can improve phosphorus supply for plants by solubilizing precipitated phosphates, using mechanisms such as acidification, chelation, exchange of ions and organic acid production. The rhizosphere species also belongs to such microorganisms that provide the iron soluble form to plants by processing siderophore products and have been isolated from rice, cucumber, cotton, peanut, sorghum (Sorghum bicolor), and maize [128,129,130]. Several bacterial communities were isolated from plant compartments and rhizosphere, have a great ability to provide a soluble form of the phosphorus to plant roots by mineralization of the organic and/or inorganic phosphate solubilization via acid production [131,132].
In addition, endophytes play an important role in the adsorption and also fixation of phosphate through assimilating solubilize phosphorus under phosphate-limiting conditions [133]. Hence, these bacteria may serve as a drain to supply the host plants with phosphorus when they require it. Characteristic of phosphate solubilization processes is usually encountered in endophytic bacteria. For example, about 59–100% of endophytes diversity were isolated from strawberry, rice, soybean (Glycine max), maize, cactus, and other legumes crops showed the potential of mineral phosphate solubilization [134,135]. Many rice endophytic bacterial strains effectively have been studied for phosphate solubilization (Figure 1), e.g., Burkholderia sp. strain BRRh-4 inoculation in rice seedling significantly enhanced the growth and grain yield of rice variety [136,137,138].
5.3. Phytohormones
Endophytic bacteria can boost the accumulation of nutrients and enhance the metabolism of host plants by generating phytohormones. Recent research investigating the colonization of phytohormones producing endophytic bacteria with the host plant increased plant nutrient absorption and biomass of plants [74]. There are five famously known types of phytohormones, abscisic acid (ABA), auxin, gibberellins (GAs), cytokinins (CKs), ethylene (ET) and Indole-3-acetic acid (IAA), these two hormones (IAA and ET) are the most important participants in building plant–bacterial interactions [139]. During the last decade, several rice endophytic bacteria showed that they have the great potential for phytohormone production [29,140].
5.3.1. Auxins
Several microorganisms produce auxin as the secondary metabolite, and many of them are isolated from the inner and outer parts of plants [141]. Many studies showed that the microorganisms produce IAA under peptone or tryptophan precursor availability. The IAA plays a multi-functional role in plant-growth promotion, such as cell division and enlargement, differentiation of tissues, primary root elongation, root inhibition, and physiological functions [142]. The most common genera of such bacteria are Alicaligenes faecalis, Azospirillim, Pseudomonas, Xanthomonas, Enterbacter cloacae, Bradyrhizobium japonicum, and Bacillales; they have displayed auxin production potential and enhance plant growth [143,144]. Various rice endophytic bacteria have been isolated from stem, roots, and leave tissues of different rice genotypes and have the potential to produce IAA in different amount of concentrations (see Figure 1) [29,59,140,145]. IAA biosynthesis is not the only way in which endophytic bacteria can enhance the growth of host plants. Certainly, its reverse process, the IAA catabolism/degradation, may also play an important role in boosting plant growth and its production. Leveau et al. [146] reported that Pseudomonas putida strain 1290 displayed an effective role in IAA degradation to enhance plant growth, such as elongation of the radish (Raphanus sativus) roots through eliminating the inhibitory effects of exogenous IAA. In the presence of tryptophan, which is a precursor of IAA, the bacteria also produce IAA. Nevertheless, it also has been described that the development of IAA by P. putida strain 1290 did not show the same deleterious impact on the radish roots compared to other high amounts shown by IAA-producing strains. The author proposed that its dual status mechanism, which includes the potential of both IAA production and its degradation, which enables this bacterial strain to produce the IAA total amounts, which can provide their beneficial effect to the host plant. Currently, several endophytic strains have been isolated and tested for the production of IAA and also showed a significant effect on plant-growth attributes, such as root and shoot elongation, and root and shoot fresh and dry weight; they also enhance chlorophyll contents in rice, soybean, and barley [27,147,148], as shown in Figure 4B.
5.3.2. Cytokinins
Many studies reported that certain beneficial endophytic bacteria can produce cytokinins (CKs) during interaction with host plants; CKs are N6-substituted amino purines that promote plant growth by activating cell division in roots and shoots parts of the plant [149]. The CKs are well-recognized phytohormones that promote plant roots’ growth, development, and release by non-pathogenic microorganisms adhering to plant roots [150]. The adenine precursor synthesis for CKs’ production by a common synthetic pathway in microorganisms such as Azotobacter sp., Corynebacterium fascians, and Rhizopogon roseolus highlighted the potential of the microbes for use in CKs’ synthesis [151,152]. A total of 90% of bacterial strains can produce cytokinin-like substances; these strains are isolated from the rhizosphere of different crops [116]. In vitro production of cytokinin-like compounds on growth media by different isolated bacterial strains from pine and Sambung nyawa, seedling roots strengthen the application of microbes in crops for improving plant growth and immunity [153]. The strains Bacillus and Pseudomonas that are isolated from various varieties of plants, such as rice, barley, canola (Brassica napus L.), soybean, and Arabidopsis, can produce these compounds. Endophytic Bacillus spp. have a great ability to produce CKs, which act as growth regulators [154].
5.3.3. Gibberellins
Gibberellins’ (GAs) composition consists of a type of terpenoids commonly referred to as iso-prenoids, which contain 20-carbon atoms, but in the active form, it contains 19-carbon atoms and also plant hormones. Additionally, 130 molecules are reported in these compounds [155]. GAs play an important role in stem elongation, seed germination and growth, and parthenocarpy, and more prominent action was observed during internode elongation. Many rice endophytic bacterial communities, such as Azospirillum brasilense, Acetobacter, Arthrobacter, Agrobacterium, A. lipoferum, Bacillus sp., Pseudomonas, Clostridium, Rhizobium, Flavobacterium, and Xanthomonas, have great potential to synthesize gas [156]. Acinetobacter calcoaceticus can produce GAs and its application in Chinese cabbage and crown daisy promoted the growth rate, as compared to non-inoculated crops [157]. It is reported by Ishak et al. [158] that B. subtilis strain LKM-BK is an endophytic bacterial strain isolated from surface-sterilized tissue of Theobroma cacao plants, which can produce GAs in certain concentration and further compounds of trans-zeatin. These findings showed the use of endophytic bacterial strains for plant-growth promotion and pathogen suppression is an applicable and result-oriented approach in agriculture development globally.
5.3.4. Ethylene and 1-Aminocyclopropane-1-Carboxylate Deaminase
Ethylene (ET) is a phytohormone and is broadly well-known for enhancing the process of ripening in different fruits and flower senescence. The ET plays an important role in plant developmental stages, such as ripening and abscission of fruit, flowering, petal, leaf senescence and abscission, root growth, and hair establishment [159]. It has been demonstrated by Dodd et al. [155] that ET also plays a role in root hair promotion, but it inhibits lateral root formation and primary root prolongation. Alleviated ET production was observed in plants against stresses, such as drought, pathogen attack, waterlogging, soil salinity, heat and cold stress, and high concentration of heavy metals [155,160]. ET is well known as a stress indicator hormone due to its synthesis under abiotic and biotic stresses under pathogen attack and drought conditions. ET in the planta produces 5′-deoxy-5′methylthioadenosine (MTA) and ACC by converting the S-adenosylmethionine (SAM), using enzymatic processes [161].
Several rhizospheres and endophytic bacteria contain enzymes of ACC deaminase, e.g., Pseudomonas, Bacillus, and Achromobacter, and also in very famous fungi, such as Trichoderma sp. Plant roots release ACC enzymes; these microbes transfer this enzyme to other parts of plant tissue and convert it to α-ketobutyrate and ammonia, as reported by Glick et al. [162]. Moreover, various studies have reported the ACC activity in rhizosphere, endophytic, and diastrophic bacteria that belong to a wide range of genera, ad well as their potential for growth promotion in the presence of several stress conditions, such as in maize [163], tomato (Solanum lycopersicum) [164,165], and wheat [166]. Ethylene protects the plant from pathogen attaching via altering the virulence signaling molecules to defend against the pathogen. These results indicating that a reduction in ACC and ET level in planta indicate a decreasing level of stress. Inoculation of bacteria with the ability to produce enzyme ACC deaminase in plants, which can protect plants from stresses induced by the high concentration of heavy metals, drought conditions, over flooding, waterlogging, pathogen attacks and organic toxic compounds [160,162,167].
5.3.5. Abscisic Acid
Abscisic acid belongs to phytohormones and comprises 15-carbon compounds that have similarities with ethylene. It plays an important role in seed development and particularly in maturation stages; activates plant defense mechanisms against stressors, such as salt stress, drought, a toxic metal, etc.; and plays a vital role in stomatal conductance. All of these features enhance its importance for plant-growth promotion [168]. In vitro ABA production by different genera of endophytes and free-living bacteria, such as Bradyrhizobium japonicum and Azospirillum sp., promotes its synthesis [169]. For instance, A. thaliana was inoculated with Azospirillum brasilense strain (Sp25), and the alleviated ABA level was observed under inoculated and non-inoculated plants. Moreover, ABA was reported to inhibit CK synthesis and enhance plant growth via modulating the CKs consortium [170]. It also experimentally proved that ABA increases shoot and root elongation via providing relief to the plants against stressors [169].
6. Indirect Plant-Growth Promotion by Endophytes
6.1. Biocontrol of Plant Pathogens by Endophytic Bacteria
The endophytic bacterial strains have great biocontrol potential against pathogens, including soil-borne pathogens and phytopathogens [171]. Still, many laps exist in understanding the biocontrol mechanism of phytopathogens and the application of the endophytic bacterial strains to suppress pathogen infestation and support the plants’ ability to improve their immunity. The biocontrol mechanism of plant pathogens comprises a multifactor interplay to suppress/inhibit pathogens, such as nutrient competition, antibiotic production, and ISR against pathogens. The endophytic bacteria mediate several mechanisms for biocontrol, and ISR is the potential mechanism that was reported in planta. The endophytic bacterial community can be observed through microscopic examination and also morphological changes, also examined within the plants to investigate the ISR. For instance, several Bacillus spp. have been reported by Melnick et al. [172], to colonize cacao plants and showed potential to suppress symptoms of the black-pod-rot disease and displayed effective biocontrol against Phytophthora capsici pathogen. Several studies reported that rice endophytic bacteria have highly potential against various phytopathogens (Table 1 and Figure 5). During in vitro assay, it was revealed that 18 strains out of 37 endophytic bacterial strains from Techona grandis and Samanea saman Merr L. have produced inhibiting compounds against Candida albicans [37,173,174,175] and many Bacillus and Streptomyces endophytic bacterial strains were also isolated from rice, wheat, maize, rice, and garlic that displayed the strong potential of antifungal activity against pathogens F. oxysporum, F. graminearum, R. solani, M. kuwatsukai, B. cinerea, R. cerealis, and G. graminis [175].
Table 1
Endophytes | Host | Antagonistic Activity | References |
---|---|---|---|
Bacillus wiedmannii strain C-1CL-2 | Japonica Rice (Oryza sativa L.) cultivar Xiushui 48 | Fusarium graminearum and Rhizoctonia solani | [25] |
Bacillus wiedmannii strain C-1CL-4 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus altitudinis strain C-1W-5 | Magnaporthe oryzae | ||
Lysinibacillus fusiformis strain C-1WF-3 | Fusarium moniliforme | ||
Fictibacillus phosphorivorans strain C-1Y-9 | Fusarium graminearum and Rhizoctonia solani | ||
Fictibacillus phosphorivorans strain C-1Y-10 | Magnaporthe oryzae | ||
Fictibacillus phosphorivorans strain C-1Y-13 | Fusarium moniliforme | ||
Fictibacillus phosphorivorans strain C-1Y-16 | Fusarium moniliforme | ||
Fictibacillus phosphorivorans strain C-1Y-17 | Fusarium graminearum, Fusarium moniliforme and Rhizoctonia solani | ||
Bacillus altitudinis strain C-2B-2 1 | Rice (Oryza sativa L.) cultivar Y-003 | Rhizoctonia solani | |
Bacillus altitudinis strain C-2D-1 1 | Rhizoctonia solani | ||
Bacillus aryabhattai strain C-2HW-1 | Fusarium graminearum and Rhizoctonia solani | ||
Lysinibacillus mangiferihumi strain C-2HW-3 | Fusarium moniliforme | ||
Bacillus marisflavi strain C-2LY-2 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus marisflavi strain C-2LY-5 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus aryabhattai strain C-2LY-6 | Fusarium graminearum, Fusarium moniliforme and Rhizoctonia solani | ||
Bacillus altitudinis strain C-2RO-1 | Fusarium graminearum, Rhizoctonia solani and Magnaporthe oryzae | ||
Bacillus altitudinis strain C-2RO-3 | Fusarium graminearum, Rhizoctonia solani and Magnaporthe oryzae | ||
Bacillus altitudinis strain C-2RO-4 | Rhizoctonia solani | ||
Bacillus altitudinis strain C-2S-1 | Rhizoctonia solani | ||
Bacillus altitudinis strain C-2SN-3 | Fusarium moniliforme | ||
Bacillus cereus strain C-2W-1 | Fusarium moniliforme | ||
Bacillus tequilensis strain C-2W-3 | Rhizoctonia solani | ||
Bacillus indicus strain C-2Y-1 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus marisflavi strain C-2Y-2 | Fusarium graminearum, Fusarium moniliforme and Rhizoctonia solani | ||
Bacillus marisflavi strain C-2Y-6 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus cereus strain C-3CL-6 | Rice (Oryza sativa L.) cultivar CO-39 | Fusarium moniliforme | |
Bacillus toyonensis strain C-3CL-7 | Rhizoctonia solani | ||
Bacillus wiedmannii strain C-3CL-8 | Fusarium graminearum and Rhizoctonia solani | ||
Lysinibacillus mangiferihumi strain C-3F-5 | Fusarium moniliforme | ||
Bacillus altitudinis strain C-3R-1 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus altitudinis strain C-3R-3 | Fusarium graminearum, Rhizoctonia solani and Magnaporthe oryzae | ||
Bacillus altitudinis strain C-3R-8 | Fusarium graminearum and Rhizoctonia solani | ||
Bacillus cereus strain C-3R-9 | Fusarium moniliforme | ||
Bacillus altitudinis strain C-3R-10 | Fusarium graminearum, Rhizoctonia solani and Magnaporthe oryzae | ||
Cupriavidus metallidurans strain C-3SP-3 | Magnaporthe oryzae | ||
Paenibacillus cucumis strain C-3T-7 | Fusarium moniliforme | ||
Bacillus altitudinis strain C-3WA-8 | Rhizoctonia solani and Magnaporthe oryzae | ||
Bacillus marisflavi strain C-3Y-2 | Fusarium graminearum and Fusarium moniliforme | ||
Bacillus marisflavi strain C-3Y-5 | Fusarium graminearum, Fusarium moniliforme and Rhizoctonia solani | ||
Fictibacillus phosphorivorans strain C-3Y-10 | Magnaporthe oryzae | ||
Bacillus sp. (in: Bacteria) strain CPS003 | Rice Oryza sativa L. var. indica cv. RD41 | Bipolaris sp. isolate KPS3, Bipolaris sp. isolate KPS5, Curvularia sp. isolate KPS41, Nigrospora sp. isolate KPS45, Fusarium sp. isolate KPS91 and Curvularia sp. isolate KPS102 | [176] |
Bacillus sp. (in: Bacteria) strain CZR007 | |||
Bacillus sp. (in: Bacteria) strain CZS004 | |||
Bacillus sp. (in: Bacteria) strain CZS006 | |||
Streptomyces endus strain OsiSh -2 | Rice (Oryza sativa L.) cultivar Gumei 4 | Magnaporthe oryzae, Colletitrichum karstii, Colletitrichum siamense, Colletitrichum camelliae, Colletitrichum frocticola, Colletitrichum glosporioides, Valsa mali, Guignardia bidwellii, Physalospora piricola, Botryosphaeria ribis, Rhizopus nigricans, Phomopsis vexans, Cladosporium fulvum, Stempblium consortiale, Botrytis cinerea, Colletrichum orbiculare, Helminthosporium maydis, Nigrospora oryzae and Rhizoctonia solani | [140,145] |
Bacillus velezensis strain YC7010 | Rice (Oryza sativa L.) | Fusarium fujikuroi | [177] |
Bacillus velezensis strain YC7007 | Fusarium fujikuroi KACC 44022, Magnaporthe grisea isolate KACC 40415, Bipolaris oryzae isolate KACC 40853, Rhizoctonia solani isolate KCTC 40101, Sclerotinia sclerotiorum isolate GSCC 50501, Botrytis cinerea isolate KCTC 6973, Fusarium oxysporum isolate KCTC 16909, Botryosphaeria dothidea isolate GSCC 50201, Pythium ultimum isolate GSCC 50651 and Alternaria panax isolate KACC 42461 | ||
Enterobacter asburiae strain VWB1 | Rice (Oryza sativa L.) cultivar rex | Fusarium oxysporum | [178] |
Pantoea dispersa strain VWB2 | Fusarium oxysporum | ||
Pseudomonas putida strain VWB3 | Fusarium oxysporum | ||
Pantoea agglomerans strain CT1 | Rice (Oryza sativa L.) variety CT6919 | Pythium ultimum | [179] |
Pantoea agglomerans strain CT2 | Curvularia sp and Fusarium oxysporum var. radicis-lycopersici strain 22 | ||
Pantoea ananatis strain CT10 | Pythium ultimum, Curvularia sp and Fusarium oxysporum var. radicis-lycopersici strain 27 | ||
Paenibacillus sp. CT14 | Curvularia sp | ||
Microbacterium sp. CT28 | Pythium ultimum | ||
Curtobacterium sp.CT30 | Pythium ultimum | ||
Paenibacillus kribbensis strain HS-R01 | Rice cultivars (Oryza sativa var. Japonica c.v. Chilbo, Chuchung, Haiami, Ilpum | Fusarium oxysporum and Rhizoctonia solani | [83] |
Paenibacillus kribbensis strain HS-R14 | Fusarium oxysporum and Rhizoctonia solani | ||
Bacillus aryabhattai strain HS-S05 | Fusarium oxysporum | ||
Bacillus megaterium strain KW7-R08 | Fusarium oxysporum | ||
Klebsiella pneumoniae strain KW7-S06 | Fusarium oxysporum and Rhizoctonia solani | ||
Klebsiella pneumoniae strain KW7-S22 | Fusarium oxysporum and Rhizoctonia solani | ||
Klebsiella pneumoniae strain KW7-S27 | Fusarium oxysporum and Rhizoctonia solani | ||
Klebsiella pneumoniae strain KW7-S33 | Fusarium oxysporum and Rhizoctonia solani | ||
Bacillus subtilis strain CB-R05 | Fusarium oxysporum and Rhizoctonia solani | ||
Microbacterium binotii strain CB-S18 | Fusarium oxysporum and Rhizoctonia solani | ||
Microbacterium trichotecenolyticum strain SW521-L21 | Fusarium oxysporum and Rhizoctonia solani | ||
Microbacterium trichotecenolyticum strain SW521-L37 | Fusarium oxysporum and Rhizoctonia solani |
6.2. Antibiosis
Antibiotics producing bacteria are largely identified and characterized for antibiotic biosynthesis and regulation under different environments and they are designated as the best biological control agents (BCAs). Antibiotic biosynthesis is regulated by many environmental factors, such as high or low temperature, pH variations, the concentration of different metal ions, etc. [180]. Even so, different bacterial strains require different environmental factors [181]. Therefore, the signaling mechanism and interaction between pathogens, plants and bacteria for antifungal traits’ modulation acquire tripartite interaction systems [182]. Previous literature revealed that a strong colonization interaction between bacterial strains and plant tissues is the key to antibiotic production [183]. The primary and secondary metabolites production is related to the bacterial-strain growth rate, it is reported by Haas and Défago [184], that bacterial growth rate boosts the secondary metabolites production. Bacteria also have unique features, such as biofilms, that play an important role in quorum sensing. The biofilm-containing bacteria play a vital role in plant protection against pathogen attack by forming a skin-like cover around plant roots and releasing antimicrobial compounds that abandon pathogen infestation [185].
6.3. Signal Interference
Primarily, many pathogens attack the plant cell wall to carry out their action. During this interaction, different kinds of exo-enzymes were detected by quorum sensing. Pathogens act very smartly to inactivate these exo-enzymes with N-Acyl homoserine lactones (AHL) molecules, and this whole process is known as signal interference [186]. There are only two kinds of classes of AHLs, which have been identified as successful activators, designated as AHL-acylase, which play an important role in breaking amide linkage and promoting abiotic factors [187]. It was revealed that AHL generates signals to release volatile organic compounds (VOCs) and suppress disease attacks in oilseed rape crops during pathosystem investigation of Verticillium dahlia and production of VOCs and antifungal metabolite (AFMs) demonstrated by Müller et al. [188] in Serratia plymuthica strain HRO-C48. Dandurishvili et al. [189] demonstrated that S. plymuthica strain IC1270 and P. fluorescens strain B-4117 generate VOC compounds which might help to control pathogenic Agrobacterium and suppress the tomato crown gall disease infestation. Moreover, Chernin et al. [190] reported that these strains produce VOC compounds and inhibit the transcription of AHL synthase genes.
6.4. Predation and Parasitism
The endophytic bacterial strains might adopt a predation and/or parasitism mechanism to control fungal pathogen infestation. The microorganisms or endophytes can synthesize or release cell-wall degrading enzymes such as chitinase, glucanase, and cellulose [191,192]. The endophytic bacteria kill fungal pathogens via disrupting fungal cell-wall with the excretion of cell-wall degrading enzymes, this mechanism is known as predation and parasitism. A similar mechanism was also found in Serratia marscens to control the pathogen attack described by Ordentlich et al. [193]. The Curtobacterium flaccumfaciens strain was isolated from the citrus plant and showed predation and parasitism mechanisms to prevent Xylella fastidiosa pathogen infestation [194].
6.5. Induced Systemic Resistance
The discovery of many PGPR free-living or endophytes in soil and those associated with compartments of plants such as leaves, roots, and plant reproductive parts, triggers induced systemic resistance (ISR) in the immune system of plants [195]. The chemical and pathogen application induces systematic-acquired resistance (SAR) during the plant defense system and SAR induction is responsible for fluctuations in salicylic acid (SA) and pathogenesis-resistance protein (PP) production [196]. Plant basal resistance is enhanced via ISR under different environmental conditions against many pathogens of the plant [197]. For instance, the P. fluorescens strains WCS365 and WCS417R are well-known as the inducers of broad-spectrum resistance in plants [198,199]. Previous studies have reported that inoculated plants are more efficient in defense and respond rapidly to insects as well as pathogen attacks, leading to improved protection ability of plants. They have also described how ISR microbes activate systematically induced resistance in plants and their distant parts, such as leaves.
Furthermore, it has been well documented by Van Loon and Bakker [200] that Pseudomonas strains release a few types of compounds, such as psuedomanine, SA, and siderophore, which ultimately increase the defense system in radish plants. Inoculated Arabidopsis with Actinobacteria endophytes strains upregulated the defense pathways and protected the plants against pathogens F. oxysporium and E. caratovora. The resistance pathway against F. oxysporium is dependent on SAR and against E. caratovora resistance driven through ET or SA [196]. In order to colonize with their host plant, bacteria must defeat their host defiance response [101].
7. Implementation of Bioinformatics in Endophytes Diversity Analysis
Applications of new bioinformatics tools help to analyze the microbiome diversity and interpret the results perfectly and meaningfully. Quantitative Insights Into Microbial Ecology (QIIME 2) is a bioinformatics pipeline that uses decentralized microbiome diversity analysis with different packages’ plug-ins [201]. QIIME 2 is a completely open-source package that starts the analysis of raw DNA sequence data and finishes with high-quality figures and statistics for publications. Each plug-in package has its function in QIIME 2, such as UCLUST, Python Nearest Alignment Space Termination (PyNAST), q2-feature-classifier, and PyNAST, which are used for aligning the sequences [202]; then UCLUST can cluster the millions of sequences and clusters them into Operational taxonomic units (OTUs) based on sequence similarity. Taxonomic can be assigned by using q2-feature-classifier by running the Greengene or Ribosomal Database Project (RDP) Classifier [203]. These tools are practically well applied to several rhizosphere microbes of plants and the earth microbiome [204,205], but no one has applied them to culture-dependent rice endophytic bacteria diversity. Most researchers cluster sequence at 97% into OTUs [204,206,207], which was proposed by Edgar Robert [206], but a new study proposed [208] to enhance the accuracy of taxonomic affliction at the species level by increasing the optical identity level of sequence clustering at 99–100% into OTUs for the V4 hypervariable region of 16S rRNA gene. Applications of these tools are a very simple and rapid way to assign taxonomic. For the application of beneficial bacteria for plant-growth-promoting assays, firstly we need to characterize their plant-growth-promoting traits under in vitro conditions in order to provide a clue about their growth-promoting potential. To characterize these traits is a laborious and time-consuming task to analyze the beneficial bacteria for applications in the form of synthetic applications. One possible track to predict these traits by using a bioinformatics tool was experimentally proved by Zhang et al. [205]. One study predicted the nitrogen-fixation bacteria via a FAPROTAX bioinformatics package [209] and further designed their synthetic communities based on nitrogen-fixation bacteria and inoculated them into rice roots for growth promotion. Applications of these communities increase the rice growth parameters compared to un-inoculated plants. Application of these tools is possible and reliable for finding beneficial bacteria.
8. Endophytes-Induced Bioactive Compounds
The endophytic bacteria play a very essential role in bioactive compounds’ (BCs) production. Various kinds of BCs have been produced by endophytic bacteria, such as alkaloids, flavonoids, quinols, polyketones, phenols, peptides, and terpenoids [210,211], and they have been applied in industrial, medical, and agricultural fields for the production of drugs to treat numerous diseases [212,213]. Several endophytes also release specialized biologically and metabolite active compounds [214]. Moreover, endophytic bacteria associated with ethnomedicinal plants act as a possible origin of bio-products, and their applications under oxidative stress play a role in producing a new bioactive agent [215]. More than 80% of the natural drugs as a source of BCs and secondary metabolites are produced by the endophytes of medicinal plants [216]. Endophytic microorganisms are the depot of precious secondary metabolites that may act as a unique and excellent provenance of drugs for antimicrobial, antidiabetic, anti-arthritic, anti-insect, anticancer, and immunosuppressant action [210]. Up until now, just a few plants have been studied for their endophytes microbial diversity and capacity to produce bioactive compounds and secondary metabolites. The exposing of these compounds’ and metabolites’ properties by various endophytes is a significant alternative source to defeat by enhancing the level of drug resistors in several pathogenic communities [210].
9. Conclusions and Prospects
The current article retires the compressive data of endophyte communities associated with rice plants. Metadata analysis insightfully proposed that 4 phyla, 6 classes, 22 orders, 46 families, and 74 genera of endophytic bacterial communities have been identified from rice parts based on culture-dependent and culture-independent methods. This tiny portion of identified endophytes diversity creates a huge gap between known endophytes communities. Traditional culture-independent methods need to be combined with advanced techniques, such as NGS, which is a rapid technique for the identification of microbes. The application of this method needs to increase at a broad level and its results are comparatively better than old methods.
Moreover, the culture-dependent method needs to be revised with their advanced materials, such as media composition, or the use of different types of media at the same time for microbe’s diversity to explore their diverse microbes’ communities. The 16S rRNA marker gene is sufficient to allot the taxonomic profile for most bacterial phyla, but it is not reliable for the Actinobacteria phylum taxonomic profile due to its division into subclasses and suborders. The whole genomic sequence is the best way to allot the taxonomic profile of the Actinobacteria phylum. Moreover, the next-generation sequence raises more interest in taxonomic classification, and this method increases the accuracy of the taxonomic classification of microbes. Implementation of bioinformatics tools in endophytic bacterial diversity may enhance the results speed and quality, allot the true taxonomic profiles, and reduce time consumption.
The application of endophytes with plant-growth-promoting traits and with inhibitory potential against phytopathogens have been a primary purpose of sustainable agriculture. The application of endophytic bacteria in the form of bio-fertilizers and bio-pesticides can be improved if we elaborate on the mechanism of endophytic bacteria interact with their host plant. How endophytes colonize with their host plant, and which kind of substrate is provided by the host plant and how endophytic bacteria utilize them as a source of nutrients, etc., need to explored for a better understanding and for their bio-fertilizer application at the commercial level for organic agricultural production. This can be achieved when we have clear and vast details about the bacterial genes uttered in the plant rhizosphere. A few studies have been performed in this field, but their collected information is not enough.
Hence, a compressive analysis of bacterial transcriptomes expressed in the plant will focus on their endophytic bacterial communities’ lifestyle, which is hidden in the plant endo-sphere parts. Attaining these arguments in the form of a challenging task, we notes that it is incredibly hard to find eminent attributes of RNA transcripts from growing bacteria in their host plant. This job is further elaborated by the low cell density of these endophytic bacteria sustained in their host-plant parts, which react to activating plant defense responses. Therefore, it is very hard to obtain adequate high-quality bacterial RNA for transcriptome analysis. However, using advanced techniques, such as RNA-seq, which can efficiently recognize both rich and rare transcripts, these kinds of analyses are now possible but need to be implemented for these analyses at broad levels. In addition, meta-transcriptome analysis of bacteria, using advanced techniques, provides a clue about their gene abundances and their profiles and would be stronger to expose their endophytic communities’ activity, which attracts their host plants for their development and nutritional benefits.
Lastly, as the rice endophytic bacterial diversity and their taxonomic afflictions have been poorly analyzed, there is the prospect of discovering novel endophytic bacterial strains with beneficial traits from unexplored genotypes of rice islands. Climatic conditions highly affect rice plants, and changing weather conditions develop abiotic and biotic stress that has an extreme effect on endophytes diversity. The identification of these novel bacteria with unique features would require an amalgamation of culture-dependent and culture-independent methodologies.
Supplementary Materials
The following are available online at https://www.mdpi.com/article/10.3390/ijms221810165/s1, Figure S1: Relative abundance of rice endophytic bacterial.
Author Contributions
M.A., Q.A. and L.Z. planned and designed this review manuscript; M.A. and Q.A. wrote this review paper; M.A., M.A.S. and M.F.A. helped draw the figures; S.H. and M.H.S. helped to improve the manuscript writing; L.Z. and Q.A. contributed to the critical revising of the manuscript. All authors have read and agreed to the published version of the manuscript.
Funding
This work was supported by the China Postdoctoral Science Foundation NO (2014M561669). The high-talent introduction and continuous training fund supported by Zhejiang Academy of Agricultural Sciences (Grant No: 10300000021LL05).
Conflicts of Interest
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.
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Funding
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China Postdoctoral Science Foundation (1)
Grant ID: Grant No (2014M561669).