Introduction
Gaultheria pumila (L.f.) D.J. Middleton (Ericaceae) is a wild berry species native to Chile. G. pumila is a low bush (up to 80 cm height), and it is commonly known as chaura or mutilla del zorro due to its fleshy fruits that are eaten by small mammals and other animals. In addition, G. pumila has several characteristics, such as high diversity of fruits, morphometric traits, adaptability to several ecological conditions and high content of polyphenols (Middleton, 1992; Villagra et al., 2014). All these properties make this species very attractive for cultivation as a commercial plant, particularly taking advantage of its nutritional potential as a functional food (Lasekan, 2014) as well as its ecological plasticity. Currently, specific biotechnological tools, such as SSR markers have been developed (Garcia-Gonzales et al., 2018) for genetic diversity studies (Pico-Mendoza et al., 2020).
Similar to many other Chilean native fruits, G. pumila has a rich and diversified composition of bioactive compounds with potential health benefits (Schreckinger et al., 2010; Ruiz et al., 2013). G. pumila has been used as a food and medicinal plant by indigenous people in Chile, such as the Aónikenk, Selk’nam, Kawésqar, Yagan, and Haush people from southern Chilean Patagonia (Dominguez, 2010). Several compounds have been identified, such as polyphenols (Middleton, 1992), anthocyanins (Villagra et al., 2014) essential oils (Bantawa et al., 2011), and high contents of methyl salicylate-rich essential oils (Apte et al., 2006). They have pharmacological characteristics such as anti-inflammatory, antioxidant, antibacterial, analgesic (Liu et al., 2013), and potential anticancer activities (Luo et al., 2018).
G. pumila is mainly reproduced by seeds in the wild. The seeds are small, and each fruit contains approximately 50 seeds per fruit or more. The species can also be propagated asexually by underground stems forming shoots during the warmer seasons, producing new clusters of plants around the original mother plant.
No information has been generated for the asexual propagation of G. pumila. However, there are publications for the Indian Wintergreen (Gaultheria fragrantissima Wall.), which is normally propagated by seeds or via rooted cuttings, but both methods are very slow (Ranyaphi et al., 2012). Micropropagation through shoots was reported for G. fragrantissima (Bantawa et al., 2011; Ranyaphi et al., 2012). Media used for in vitro culture include woody plant medium (WPM) supplemented with different concentrations of thidiazuron (TDZ) alone or in combination with 6 benzyl-amino purine (BAP); kinetin (Kin) alone or in combination with auxin indole-3-acetic acid (IAA), indole-3-butyric acid (IBA), or α-naphthalene acetic acid (NAA) (Bantawa et al., 2011) and semisolid rhododendron medium (RM), Murashige and Skoog medium (MSM) and WPM supplemented with N-6-benzyladenin (BA), kinetin (Kin) and 2-iso-pentenyladenine (2iP) (Ranyaphi et al., 2012).
In vitro culture offers other advantages, such as developing disease-free plants of the species under study and rapidly scaling up for commercial production (García-Gonzáles et al., 2010). Considering the efficiency of in vitro propagation techniques, their application in G. pumila would ideally provide a fast and efficient propagation system while maintaining high health status. One of the more relevant applications of tissue culture in plants is the support of domestication projects of noncultivated plants (Gepts, 2004a, 2004b) since it is necessary to produce enough plants from selected genotypes in a limited period of time to evaluate the agronomic performance under cultivated conditions. This study aimed to develop the first micropropagation protocol for G. pumila, addressing the different steps of the tissue culture process.
Materials and methods
Plant material
Plants of G. pumila were selected in actively growing areas at Villarrica National Park, Araucanía Region (S: 39°34’463, W: 71°28’509). The plants were transported to the greenhouse with soil in a humid cooler box. Once in the greenhouse, the plants were planted in five liter pots containing soil brought from the sampling location. These mother plants were watered daily with 200 ml of water. No fertilizer or pesticides were used during the preparation of the plants. Light pruning was performed to eliminate older branches as well as dead leaves to stimulate shoot formation. After new shoot production, healthy 10 cm explants were collected and prepared in 1.0 cm nodal pieces containing two to three vegetative buds.
General environmental conditions
For all experiments in this study, the basal media was supplemented with 3% (w/v) sucrose and 8% (w/v) agar. The pH of the media was adjusted to 5.7 before sterilization by autoclaving for 20 minutes at 1 kg cm−2 and 121 °C. For all the experiments described above, the cultures were transferred into a culture room at 24 ± 1 °C and a 12/12 photoperiod under cool white fluorescent lamps (60 μmol m−2 s−1).
Disinfection and in vitro initiation
Nodal explants of 1.0 cm containing two to three vegetative buds were used. The selected explants were washed using distilled water and common detergent for twenty minutes, followed by a deep wash using sterile distilled water (500 ml) with three drops of Tween 20 for 20 min, and then rinsed three times with sterile distilled water to eliminate any detergent residues. These steps were performed under a laminar flow chamber. Once rinsed, the disinfection treatments were applied to the nodal explants. After disinfection, the explants were rinsed three times with sterile distilled water. Oxidized tissues were removed from the explants before planting them on semisolid Murashige and Skoog (MS) medium (Murashige & Skoog 1962) supplemented with three concentrations of 2-iP: 0.5, 1.0, and 2.0 mg L−1. The final evaluation of the experiment was performed five weeks after initiation. For the disinfection procedure, six treatments were tested (Table 1). Each treatment had twenty-one replicates planted in a single jar. The effects of each treatment on the number of contaminated explants and the number of regenerated plants were evaluated to choose the best disinfection protocol.
Plant formation and stabilization of in vitro plantlets
After selecting the best disinfection and in vitro initiation conditions, it was necessary to stabilize the development of the established explants. The effect of the type of cytokinin (2 isopentenyl adenine, 2-iP; 6-bencil aminopurine, BAP; Zeatin, Zea) and their concentration (0.5, 1.0, and 2.0 mg L−1) on the morphogenic response of established explants was evaluated. Each growth regulator at its test concentration was added to four different basal media: full-strength MS (MS100), half-strength MS medium (MS50), full-strength WPM (WPM100), and half-strength WPM medium (WPM50). Only explants coming from the selected disinfection and in vitro establishment protocol were used in this experiment. The medium preparation and sterilization were developed as described above. To successfully establish the tissue cultures, the effects of the basal medium, cytokinin type, and concentration on plantlet recovery were studied. Twenty-four multifactorial treatments were assayed with fifteen repetitions (Table 2). To select the best treatment, morphogenic responses were evaluated, such as the percentage of explants, the number of shoots, shoot length per explant, and the number of leaves.
Treatments | Basal Medium | Dilution of basal medium (%) | Growth regulator | Plant growth regulator concentration (mg L−1) |
---|---|---|---|---|
T1 | MS | 100 | 2-iP | 1.0 |
T2 | MS | 100 | 2-iP | 2.0 |
T3 | MS | 100 | BAP | 1.0 |
T4 | MS | 100 | BAP | 2.0 |
T5 | MS | 100 | Zeatin | 0.5 |
T6 | MS | 100 | Zeatin | 1.0 |
T7 | MS | 50 | 2-iP | 1.0 |
T8 | MS | 50 | 2-iP | 2.0 |
T9 | MS | 50 | BAP | 1.0 |
T10 | MS | 50 | BAP | 2.0 |
T11 | MS | 50 | Zeatin | 0.5 |
T12 | MS | 50 | Zeatin | 1.0 |
T13 | WP | 100 | 2-iP | 1.0 |
T14 | WP | 100 | 2-iP | 2.0 |
T15 | WP | 100 | BAP | 1.0 |
T16 | WP | 100 | BAP | 2.0 |
T17 | WP | 100 | Zeatin | 0.5 |
T18 | WP | 100 | Zeatin | 1.0 |
T19 | WP | 50 | 2-iP | 1.0 |
T20 | WP | 50 | 2-iP | 2.0 |
T21 | WP | 50 | BAP | 1.0 |
T22 | WP | 50 | BAP | 2.0 |
T23 | WP | 50 | Zeatin | 0.5 |
T24 | WP | 50 | Zeatin | 1.0 |
Effect of plant growth regulator interaction on the in vitro multiplication of G. pumila
For the multiplication step, all in vitro plants were grown in the best medium of the previous phase for two cycles of four weeks each. The plants selected were prepared as nodal explants harboring at least one bud. The explants were then planted on WPM100 medium with different concentrations of IBA combined with zeatin or 2-iP. Twelve treatments were replicated four times combining the interaction between auxins and cytokinin and tested to determine the best multiplication rate (Table 3). The effect of the different treatments was considered to choose the best micropropagation condition. After six weeks of culture, the effect of the different treatments on shoot number, shoot length, explant contamination and oxidation rate were evaluated.
Evaluation of auxins on the in vitro rooting
In vitro rooting and preparation of individual plantlets is critical in obtaining plantlet survival during the ex vitro phase. The effects of auxins, such as indolbutiric acid (IBA), indol-3-acetic acid (IAA), and naftalenacetic acid (NAA), added at different concentrations (1, 2, 3, and 4 mg L−1) to the basal WPM medium on rooting and plant development were tested. Twelve treatments and thirty replicates were evaluated. The percentages of roots, roots per explant, and callus formation were evaluated to select the best in vitro rooting conditions.
Ex vitro acclimation of individual plantlets
For the ex vitro acclimation stage, several factors were considered, such as light intensity, substrate quality, and relative humidity in the adaptation tunnel. The variable measured for this stage was the number of surviving active plants. The substrate used had a mixture of 50% organic matter, 25% vermiculite, and 25% sand. The explants came from the previous rooting phase, using ten explants for each treatment. Before being planted, the plantlets were immersed in a 1 g L−1 IBA solution for two minutes. The temperature conditions in the greenhouse were 5 °C low 20 °C high during the winter months, and 15 °C low and 35 °C high during the summer months. The humidity inside the greenhouse ranged between 55–60% year-round.
Statistical analysis
Random block design (RBD) was used for all the experiments. Statistical analyses were performed using InfoStat statistical software (Balzarini et al., 2008). The normality of the data was determined by the Q-Q plot graphic and corroborated with the Shapiro–Wilks test of residues. To detect the best treatment, an analysis of variance (ANOVA) and Tukey HSD test with a 95% confidence level were performed if the data had a normal distribution of variance. For those not complying with the normality assumptions, a Kruskal–Wallis test with a level of significance of 95% was performed.
Results
Effect of the disinfection protocol and plant growth regulators on explant decontamination and plantlet development during in vitro establishment
Disinfection and initiation
The highest disinfection efficiency (p=0.01) was obtained when the explants were exposed to treatment T3, disinfection with 1% sodium hypochlorite for 40 minutes, followed by a second wash with 2% sodium hypochlorite for 25 minutes, and cultivation on MS medium. Using this treatment, only 5% of contaminated explants were observed (Fig. 1). Fungi and bacteria were the main contaminants in this stage. However, the highest morphogenic response was observed in treatment T2, where the 2-iP concentration was reduced to 1 mg L−1 compared to T3. This combination of plant growth regulators in the disinfection phase helped the explants to be stimulated and to have enough material for the next stages of micropropagation. Using this 2-iP concentration produced an increase in shoot production per explant of up to 56%, which was significantly different from the rest of the treatments (p=<0.01).
Plantlet formation and stabilization in vitro
The stabilization of the explants after disinfection was necessary to homogenize their morphogenic response. It was found that the cultivation of the disinfected explants in treatment 24 (WPM50 + 1.0 mg L−1 Zeatin) produced more shoots than the rest of the treatments. In second place was treatment 18 (WPM100 + 1.0 mg L−1 zeatin), followed by treatments 14 and 13. However, treatment 16 (WPM100% + BAP 2.0 mg L−1) presented the longest shoots and the highest number of leaves. In general, the treatments that were supplemented with 2iP and zeatin showed the best-developed shoots (Table 4).
Treatments | Shoot formation (number) | Shoot formation (%) | Shoots formation per explant | Average of shoot length (mm) | Number of leaves/shoots |
---|---|---|---|---|---|
T13 (WPM100%+2-iP 1.0 mg L-1) | 2 | 4 | 2.0±1.0a | 7.5±6.3b | 4.5±6.3b |
T14 (WPM100%+2-iP 2.0 mg L-1) | 7 | 16 | 2.1±1.4a | 13.8±4.4b | 6.7±1.9ab |
T16 (WPM100%+BAP 2.0 mg L−1) | 3 | 7 | 1.0±0.0a | 24.3±10a | 11.0±6.5a |
T18 (WPM100%+Zeatin 1.0 mg L−1) | 21 | 47 | 2.1±1.0a | 8.3±2.9b | 4.2±2.2b |
T23 (WPM50%+Zeatin 0.5 mg L−1) | 7 | 16 | 1.1±0.3a | 9.7±3.3b | 1.7±1.7b |
T24 (WPM50%+Zeatin 1.0 mg L−1) | 13 | 29 | 2.5±1.0a | 11.5±3.9b | 6.0±2.6ab |
p = value | >0.05 | <0.01 | <0.01 |
Effects of the interaction of auxin and cytokinins on the morphogenic response during in vitro multiplication
Micropropagation was significantly influenced by the different treatments tested (p≤0.05). When placed on treatment T1 (WPM100 + 1.0 mgL−1 Zeatin), an average of six shoots per explant was obtained with an average shoot length of 4.8 cm (Table 5). Treatment 2 (WPM100 2.0 mgL−1 Zeatin) produced an average shoot length of 3.3 cm per explant, with 4.3 shoots per explant. After six weeks of culture, the regenerated shoots showed expanded leaves and grew vigorously (Fig. 2). Oxidation of the explants was very low in all the experiments, with no significant differences between treatments (p≥0.05).
Treatments | Average shoot length (cm) | Shoots formation per explant (number) |
---|---|---|
T1(WPM100+1 mgL−1 Zeatin) | 4.8±1.0 a | 6.0±0.8 a |
T2(WPM100+2 mgL−1 Zeatin) | 3.3±1.0 b | 4.3±0.5 b |
T3(WPM100+1 mgL−1 Zeatin +0.25 mg L−1 IBA) | 2.3±0.5 b | 3.3±0.5 c |
T4(WPM100+2 mgL−1 Zeatin +0.25 mg L−1 IBA | 1.5±0.6 c | 2.8±1.0 c |
T5(WPM100+1 mgL−1 Zeatin +0.5 mg L−1 IBA) | 2.5±0.6 b | 3.0±0.0 c |
T6(WPM100+2 mgL−1 Zeatin +0.5 mg L−1 IBA) | 2.5±0.6 b | 3.5±1.3 c |
T7(WPM100+2 mgL−1 2-iP) | 3.0±0.8 b | 4.5±0.6 b |
T8(WPM100+3 mgL−1 2-iP) | 2.8±0.6 b | 4.8±1.0 b |
T9(WPM100+2 mgL−1 2-iP + 0.25 mgL−1 IBA) | 1.3±1.0 c | 3.3±0.5 c |
T10(WPM100+3 mgL−1 2-iP + 0.25 mgL−1 IBA) | 1.0±0.0 c | 2.8±0.5 c |
T11(WPM100+2 mgL−1 2-iP +0.5 mgL−1 IBA) | 0.8±0.5 c | 2.5±0.6 c |
T12(WPM100+3 mgL−1 2-iP +0.5 mgL−1 IBA) | 0.8±0.5 c | 2.8±0.5 c |
p value | <0.01 | <0.01 |
Evaluation of auxins on the in vitro rooting and preacclimatization of individualized plantlets
The addition of auxins to the basal medium significantly increased the efficiency of root formation. At the same time, the addition of 3 mg L−1 NAA induced the highest rooting efficiency (47% rooted explants, p=0.01), followed by the addition of 4 mg L−1 NAA, which produced 40% explant rooting, with means of 1.23 and 1.13 roots per explant in treatments T11 (WPM + 3 mg L−1 NAA) and T12 (WPM + 4 mg L−1 NAA), respectively. However, treatments T1, T2, T3, T4, T5, T6, and T8, despite having been supplemented with auxins, did not produce roots (Table 6). Callus formation was induced more efficiently when media were supplemented with NAA and IBA.
Treatments | Percentage of roots | Roots per explant | Calli formation (means+SE) |
---|---|---|---|
T1(WPM +1 mgL−1 IBA) | nr | nr | 0.40±0.50bc |
T2 (WPM +2 mgL−1 IBA) | nr | nr | 0.17±0.38c |
T3(WPM +3 mgL−1 IBA) | nr | nr | 0.47±0.51b |
T4(WPM +4 mgL−1 IBA) | nr | nr | 0.40±0.50bc |
T5(WPM +1 mgL−1 IAA) | nr | nr | nr |
T6(WPM +2 mgL−1 IAA) | nr | nr | nr |
T7(WPM +3 mgL−1 IAA) | 3 | 0.03 ±0.18b | nr |
T8(WPM +4 mgL−1 IAA) | nr | nr | nr |
T9(WPM +1 mgL−1 NAA) | 23 | 0.43± 0.9ab | 0.83±0.38a |
T10(WPM +2 mgL−1NAA) | 27 | 1.0±1.86ab | 0.93±0.25a |
T11(WPM +3 mgL−1 NAA) | 47 | 1.23±1.5a | 0.97±0.18a |
T12(WPM +4 mgL−1 NAA) | 40 | 1.13±1.96a | 1.00±0.00a |
Ex vitro acclimation
Of the explants exposed to ex vitro conditions, only 50% survived when moved to greenhouse conditions. The explants that were planted showed a good root system after 45 days of sowing (Fig. 3).
Discussion
Any explants to be introduced in vitro need a surface disinfection process that has to be nondamaging to the plant tissue but efficient in controlling microorganisms (García-Gonzáles et al., 2010). This phase is paramount and one of the most important phases for the establishment of the species. Surface cleaning of explants repeated prior to disinfection decreases the presence of contaminants, and this decrease is greater when explants are sterilized more than twice. Sodium hypochlorite, calcium hypochlorite, ethanol, and mercuric chloride are the most common disinfectants used during this initial step (Garcia et al., 1999; Husain & Anis, 2009; Singh & Gurung, 2009; Tilkat et al., 2009).
In this study, two cycles of disinfection (1% sodium hypochlorite for 40 minutes and 2% sodium hypochlorite for 25 minutes) and establishment in MS medium with low concentrations of salts were performed. Ninety five percent explant disinfection gave the best results for in vitro disinfection and morphogenesis during the establishment stage. Shoot formation and elongation were improved under this protocol of disinfection. Studies on in vitro micropropagation carried out in Rhododendron ponticum L (Almeida et al., 2005) using commercial bleach 25% (v/v) (5% sodium hypochlorite) for 20 minutes reported 43% contaminated explants; in other words, these explants still showed a high rate of contamination compared with our results. The combination of sterilization products is often used with the intention of increasing asepsis in explants, especially in the Ericaceae family. In Vaccinium arctostaphylos L. and Vaccinium myrtillus L., surface sterilization with 70% ethanol for 1 minute followed by disinfection for 15 min with 3% sodium hypochlorite showed positive disinfection results (Cüce et al., 2013; Cüce & Sökmen, 2015).
In Rhododendron ledebourii, explants were submerged in 70% ethanol for 30 seconds, and then their surface was sterilized for 15 min by 0.15% (w/v) HgCl2 with a drop of Tween-80. Using that method, 40% and 20% survival was obtained in two genotypes after surface sterilization (Erst et al., 2014). Other methods of sterilization have been used for the in vitro propagation of other berry species, such as strawberry (Fragaria vesca L.) (96% ethanol for 30 sec and 0.1% HgCl2 for 3 min), raspberry (Rubus idaeus L.), (70% ethanol for 60 sec and 0.1% HgCl2 for 5 min), bilberry (Vaccinium myrtillus L.) and lingonberry (Vaccinium vitis-idaea L.) (70% ethanol for 30 sec and 0.1% HgCl2 for 3 min), with results showing over 80% efficiency in decontamination, with the exception of bilberry (Georgieva et al., 2016). All these results for different species and sterilization protocols are below the levels reported in this study. The difference in results is probably because we used a two-phase sterilization process, with a lower concentration of sodium hypochlorite, but increased the time that we treated the explants, which may be the key to success in the sterilization of explants for this species.
Likewise, with the intention of verifying the effect of the culture medium, different concentrations and types of cytokinins on the growth of in vitro plantlets of G. pumila were studied. In this case, the best results were obtained using WPM100 medium supplemented with zeatin at 1.0 mg L−1, which produced 47% explants with shoots, showing the best homogeneity of explants, both in number and height. In Vaccinium arctostaphylos, WPM supplemented with 1.0 mg L−1 zeatin and 0.1 mg L−1 IBA appeared to be the best basal medium in terms of shoot formation, where 74% of the explants developed shoots, where the combination of WPM and zeatin showed better homogeneity in explant formation (Cüce et al., 2013) than that in G. pumila. The application of zeatin showed that a concentration of 1.0 mg L−1 promotes the induction and stabilization of shoots. Zeatin very effectively stimulates shoot multiplication, leaf formation, and the development of shoot length, as has happened in species of the Vaccinium genus (Gajdosová et al., 2006; Cüce et al., 2013). In the multiplication stage, the addition of cytokinin to the WPM100 medium produced higher axillary propagation rates and shoot elongation, which were also significantly higher in these conditions.
On the other hand, supplementing the media with auxins did not have any significant effect on plant morphogenesis during the multiplication stage. Despite the importance of the interaction between auxin and cytokinin in the formation and maintenance of meristems for establishing the whole plant body (Su et al., 2011) in G. pumila that was not significant, this treatment showed the lowest value on multiplication rate. Only the effect of the cytokinin in the G. pumila explants showed a higher number of shoots and elongation. These results differ from the results obtained in Fragaria chiloensis, where the interaction of auxins and cytokinins is an important factor in the formation and improvement of new shoots and the number of leaves per shoot, even in the induction of roots in other species (Quiroz, 2014; Aremu et al., 2016). Regarding other studies in the Ericaceae family, the use of 2-iP in Vaccinium macrocarpon during the multiplication of the species induced longer shoots (approximately 4 cm) in different clones (Debnath & McRae, 2001). Additionally, it has been demonstrated that the morphogenic response to cytokines could depend strongly on genotype, as has been shown in Arbutus unedo L. (Gomes et al., 2010) and raspberry (Gajdošová et al., 2006).
In the in vitro root formation stage, the explants showed a low response in terms of root formation. Root induction was greater in treatments that were supplemented with naphthalene acetic acid (NAA), where 47% of explants produced roots. In contrast to these results, in related species such as Vaccinium corymbosum L. cv. ‘Elliot’, the addition of BAP produced more than 90% rooted explants (Vescan et al., 2012). In the case of blueberry in vitro plantlets, the effects of IBA at different concentrations produced over 75% rooted explants (Guang-Jie et al., 2008). At this stage, in addition to the production of roots, the induction of calli and shoots are also stimulated. In Casuarina cunninghamiana Miq., first, the callus is formed, and later, the adventitious roots are formed from the callus (Shen et al., 2010). The formation of new organs in the rooting stage allows the survival of the explant, giving opportunity for the formation of roots in the longer term, especially in species difficult to root, as in the Ericaceae family. Finally, as in many Ericaceae species, in vitro rooting in G. pumila was very hard to induce. The addition of auxins, in general, produced some roots, but the efficiency was still low (47%).
The acclimatization of the in vitro plants in this study was lower (50%) than that reported in G. fragrantissima, which varied between 70% (Bantawa et al., 2011) and 80% (Ranyaphi et al., 2012). This difference could be due to the type of substrate used, since the highest percentage of survival reported occurred using 100% sand (Ranyaphi et al., 2012), followed by a 9:1:1 (v/v/v) mixture of virgin soil (upper layer of black jungle soil collected from a deep forest area), sand and manure (Bantawa et al., 2011). In the current study, the substrate was a mixture of 50% organic matter, 25% vermiculite, and 25% sand. The substrate probably did not have a sufficient proportion of sand, which allows better aeration and better development of the root system (Abul Soad et al., 2012).
Conclusions
The use of a little-explored genetic resource with high potentialities, such as G. pumila, has become an option as a horticultural crop. The micropropagation of G. pumila will allow mass production of plants, especially in genotypes of interest with desirable characteristics, which allows us to advance in a selection and breeding process. The intention is to turn the species into an alternative for the production of nontraditional crops for the horticultural sector. The results of this research provide an efficient in vitro protocol that guarantees the multiplication of this species at different scales. This study contributes to laying the initial foundations for the domestication of G. pumila and, in a relatively short period, we could benefit from its attributes in a sustainable way.