In Vitro Culture of Jewel orchids (Anoectochilus setaceus Blume)

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1 In Vitro Culture of Jewel orchids (Anoectochilus setaceus Blume) PHI THI CAM MIEN 1,2, PHAM LUONG HANG 1, NGUYEN VAN KET 3, TRUONG THI LAN ANH 3, PHUNG VAN PHE 4, NGUYEN TRUNG THANH 1* 1 Faculty of Biology, VNU University of Science, 334 Nguyen Trai, Hanoi, Vietnam 2 Faculty of Biotechnology, Hanoi University of Agriculture, Trau Quy, Gia Lam, Hanoi, Vietnam 3 Faculty of Agriculture Forestry, Dalat University, 01 Phu Dong Thien Vuong, Da Lat, Vietnam 4 Faculty of Silviculture, Vietnam Forestry University, Xuan Mai, Chuong My, Hanoi, Vietnam *Corresponding author: thanhntsh@gmail.com The effect of basal media, BAP, Kn and sugars to the growth and development of Anoectochilus setaceus multiple shoot were reported in this study. The basal ½ MS, MS and Knud medium were tested and shown to be equally suitable of them for shoot culture after 8 weeks. The maintaining of culture until 12 weeks, growth of protocorms was superior in MS to that in ½ MS and Knud medium. Other cultures were initiated from shoots inoculated onto MS medium supplemented individually with six different concentrations of 6-Benzylaminopurine (BAP) and Kinetin (Kn). The highest number of shoots was obtained on medium supplemented with 0.6 mg l -1 BAP (4.4 ± 0.5 shoot/explant). Out of all the investigated concentrations of Kn, the best result was obtained on medium supplemented with 1.0 mg l -1 Kn (3.3 ± 0.3 shoot/explant). In sugar study, results show that the shoot, root and leaf formation was significantly enhanced as the sugar concentration was decreased. Medium supplemented with 2% (w/v) sucrose was the best compared to the other treatments and sugar at a concentration of 5% (w/v) induced the formation of large size seedlings. Keywords: In vitro culture, Jewel orchids (Anoectochilus setaceus), plant hormones, the multiple shoot induction. Introduction Anoectochilus is a genus of about 50 orchids (family Orchidaceae) belonging to Research report submitted by Nguyen Trung Thanh, a participant in the 25th UNESCO International Post-Graduate University Course in Microbiology,

2 the subfamily Orchidoideae [1]. They are sometimes called "Jewel orchids" because of their attractive foliar venation. Found in Yunnan China, Assam India, Bangladesh, eatern Himalayas, Nepal, western Himalayas, Sri Lanka, Myanamar, Thailand, Vietnam. This genus distributed at elevations of 800 to 1800 meters as a creeping, ascending, warm to cool growing terrestrial orchid in rich humus in damp crevasses with subcordate to ovate-acute, velvety, dark lime-green reticulated with gold leaves that are puple black on the underside [2, 3]. The damaging effect of human activities on natural habitats has resulted in great loss of the species. In addition, intensive and illegally collection leading to alternated of this species and recorded to the Vietnamese Red List [4]. Therefore, there is an urgent need to conserve this medicinal species. Numerous studies on efficient propagation of orchid plants have been published [5, 6] and suggested that method is species-specific oriented. Optimization of medium compositions was an important approach to fasten the propagation process and improve the quality of regenerated plantlets [7-9]. Among them, different carbon sources such as sucrose, glucose, maltose, fructose and sorbitol also were proven to have effects on protocorm-like bodies (PLBs) growth [10, 11]. Beside, plants can be regenerated and mass propagated in vitro either by shoot morphogenesis or somatic embryogenesis. Many important Chinese traditional medicinal herbs have been successfully regenerated in vitro. Each has a particular group of bioactive compounds. Taxol (plaxitaxol), a complex diterpene alkaloid found in the bark of Taxus tree is one of the most promising anticancer agents due to its unique mode of action on microtubular cell system [12]. The root of Panax ginseng C.A.Mayer, has been widely used as a tonic and preciousmedicine since ancient times [13]. The primary bioactive constituents of ginseng are ginsenosides, a group of triterpenoid saponins [14]. Berberine is an isoquinoline alkaloid found in roots of Coptis japonica [15]. In the economic importance of view, the need for formulation of simple culture media is important to reduce the cost of production. This study reports the influence of basal media, and some attempts have been made to increase the number of adventitious shoots in vitro culture. Materials and Methods Plant material Jewel orchids (Anoectochilus setaceus) plants were collected at Tam Dao National Park, Vinh Phuc province (Fig. A). The samples were first soaked in 70% (v/v) ethanol for 30 seconds and then treated with 10% (w/v) sodium hypochlorite (NaOCl) for 15 min, followed by 3-4 rinses with sterile water for surface sterilization. The sterilized samples were grown on MS basal medium [16] without growth regulators to produce plantlets. The subcultures were carried in our laboratory as stock plants. Shoot elongation and rooting After culture for 8 weeks, the adventitious shoots regenerated from explants were transferred to hormone-free MS medium for shoot elongation. Three basal media 437

3 were assessed for growth and development efficiency: Murashige and Skoog (MS), ½ MS and Knudson C (KC) [17]. When the shoots reached cm in height, they were transferred onto basal MS medium supplemented with mg l -1 BAP (6- Benzylaminopurine) and Kn (Kinetin or 6- Furfurylaminopurine) [18]. For the effect of sucrose at concentrations of 1%, 2%, 3%, 5% or 7% (w/v) were separately added into the MS medium for shooting and rooting. Culture conditions and data analysis Uniform culture conditions were applied in all experiments. All experiments were conducted 3 replicates with 500 ml conical flasks in each (containing 80 ml medium) and 7-14 explants were cultured in every 500 ml conical flask. The ph of the media was adjusted to 5.7 before autoclaving. The media was autoclaved for 15 min at 121 C. Cultures were incubated at 25 ± 2 C under a 16 h photoperiod with cold white fluorescent light mixed with incandescent light at 55.6 mol m -2 s -1. All data were analyzed using standard applied method. Results and Discussion Effect of different basal media on growth of Jewel orchids (A. setaceus Blume) The basal ½ MS, MS and Knud medium were tested and the results were shown to be equally suitable of them for shoot tip culture of A. setaceus (Table 1). The culture of shoots in these media showed good growth after 8 weeks culture. Shoot length was about cm with 5 to 10 leaves per shoot (Fig. C). Shoot tips of A. setaceus cultured on MS or Knud without PGRs developed 2-5 additional shoots within 8 weeks of culture. Table 1. The effects of different basal media on growth of Jewel orchids Medium Number of shoot/explants Avg length of shoots (cm) ½ MS 3.0 ± ± 0.7 MS 3.1 ± ± 0.9 Knud 3.2 ± ± 0.5 Basically, a nutrient medium consists of all of the essential major and minor plant nutrient elements, vitamins, plant growth regulators, and a carbohydrate as carbon source with other organic substances as optional additives [19]. The medium described by [16] (MS medium) is most commonly used. The growth response of A. setaceus also showed the best result on the MS medium. The maintaining of culture until 12 weeks, growth of protocorms was superior in MS to that in ½ MS and Knud medium (Fig. C) (data not shown). This might perhaps 438

4 be due to its richness in micro element regime [20] and organic and inorganic nitrogen sources [21]. The mineral requirement of orchids is generally not high, and salt poor medium is usually recommended. Beside the MS medium, the modified [16] also often used for micropropagation of orchids such as Cattleya, and Cymbidium [22]. Knud medium frequently used for the growth of orchids performed very poorly in this experiment when compared to MS medium. Probably salt poor in Knud medium is also further suitable for growth of A. setaceus. For further experiments on shoot growth and proliferation, we used MS media because it is commonly, commercially and available. The effects of different concentrations of BAP on growth of Jewel orchids (A. setaceus Blume) The application of molecular approaches with medicinal plants would also benefit from the development of cell, tissue and organ culture systems for in vitro growth and regeneration of medicinal plants. In addition, such tissue culture systems could also prove useful for large-scale biotechnological production of medicinal plant phytochemicals [23]. Furthermore, uniform plant growth with consistent plant material can be achieved, plants can be grown in sterile, standardized conditions and are free from biotic and abiotic contamination. This study describes the basic procedures for the establishment on multiple shoot induction of A. setaceus. Samples ( cm in stem length) were separately transferred to MS medium supplemented with mgl -1 of BAP and Kn. The formation of new shoots was observed in all media studied except in the control group (hormon-free medium), indicating that A. setaceus is highly responsive to plant growth regulators. Regeneration frequency, mean number and length of shoots per explant were recorded after all hormone experiments. In the first stage of our experiment, the number of shoots changed, depending on the different concentrations of BAP. When the number Table 2. The effects of different concentrations of BAP on growth of Jewel orchids Concentrations of BAP (mg l -1 ) Avg No of shoots/explant Avg length of shoots (cm) Control 1.0 ± ± ± ± ± ± ± ± ± ± ± ± ± ±

5 of shoot was compared, there were statistically significant differences among the concentrations of BAP tested (Table 2). The highest and the lowest number of shoots were obtained on the medium supplemented with 0.6 mg l -1 (Fig. D, E) and 0.1 mg l -1 of BAP (4.4 ± 0.5 shoot/explant, and 6.6 ± 0.4 cm length of shoots, respectively). The effects of different concentrations of Kinetin on growth of Jewel orchids (A. setaceus Blume) All the investigated concentrations of Kn showed shoot production. However, the best result was obtained on the medium supplemented with 1.0 mg l -1 Kn. From the results presented in Table 3, it appears that the number of shoot rises by increasing the concentration of Kn. However, smaller and shorter shoots were formed as the concentration of Kn increased in the culture medium. Excessive shoot length and root formation were observed on the medium containing low concentrations of Kn (from 0.6 to 1.5 mg l -1 ) (Fig. F, G). Table 3. The effects of different concentrations of Kn on growth of Jewel orchids. Concentrations of Kn (mg l -1 ) Avg No of shoots/explant Avg length of shoots (cm) Control 1.2 ± ± ± ± ± ± ± ± ± ± ± ± ± ± 0.1 The results indicated that the highest shoot number formed on the medium supplemented with 2.0 mg l -1 of Kn (3.3 ± 0.2 shoots/explant). However, the morphological characteristics of shoots in this medium were not similar to plants growing in a natural environment and led to vitrification in shoots. Therefore, a culture medium with 1.0 mg l -1 of Kn was sufficient to produce multiple shoot and an average of 3.2 shoots formed from each explant in this medium within eight weeks (Table 3). In the morphological observations, Kn concentrations surpassed other media (BAP concentrations) in terms of mean shoot length, leaf width and root formation. In comparison of all treatments of two cytokinins with control group (Tables 2, 3), it was determined that the medium should be supplemented with exogenous hormones (PGRs) for new shoot formation. 440

6 In conclusion, shoots were successfully propagated after two subcultures in the presence of BAP or Kn. Among the cytokinins (BAP, Kn concentrations), BAP was reported to be more efficient than Kn in promoting shoot formation. Our findings are compatible with those of [24], who reported that in H. perforatum, BAP was found to be the most efficient in shoot formation when excised parts of seedlings were used. Also, for H. perforatum L., BAP was found to be the most efficient in promoting shoot regeneration when leaves [25] were used as the explant. Figure. In vitro propagation via shoot morphogenesis: (A) Plants were collected at Tam Dao National Park, Vinh Phuc province; (B), (C) Multiple shoot induction after 4 and 12 weeks culture on ½ MS, MS, Knud medium; (D), (E) Multiple shoot induction on MS medium with 0.6 mg l -1 BAP after of 2 and 4 weeks culture; (F), (G) Multiple shoot induction on MS medium with 1.0 mg l -1 Kn after 6 and 8 weeks culture; (H) Multiple shoot induction on MS medium with 2 % sucrose; (I) Elongated shoots on MS medium with sucrose concentrations: 0, 1, 2, 3, 5, 7% (w/v). Effect of different sugars on growth of Jewel orchids (A. setaceus Blume) Protocorms growth and development were greatly affected by source and concentration of sugars added in the culture media (Fig. H). The shoot, root and leaf 441

7 formation was significantly enhanced as the sugar concentration was decreased. Medium supplemented with 2% (w/v) sucrose was the best compared to the other treatments with 4.1 ± 0.4 shoots/explants and length of shoots is 3.9 ± 0.3 cm, respectively. Beside that sugar at a concentration of 5 % (w/v) induced the formation of large size seedlings (data not shown) (Fig. I). Sugar has a great potential effect on the physiology, growth and differentiation of the cultured cells and tissues [26]. Table 4. Effect of sucrose concentration on growth of Jewel orchids Sucrose (%) Avg No of shoots/explants Avg length of shoots (cm) ± ± ± ± ± ± ± ± ± ± ± ± 0.3 Conclusion In conclusion MS medium, 0.6 mg l -1 BAP, and 2% (w/v) sucrose were the best factors for the growth and development of multiple shoot induction of Jewel orchids (Anoectochilus setaceus Blume) cultured in vitro. Acknowledgments This work was supported by grants from Vietnam National University, Hanoi, Code: QGTD as the sponsor of the research project. We also wish to thank the Manage Board of Tam Dao National Park, Department of Forest Vinh Phuc province for help during our sample collecting. References Ban N.T. (Editor) (2005). The list of plant in Vietnam. Vol. 3, pp , Publisher of Agriculture, Hanoi. (In Vietnamese). Constable F. (1990). Medicinal plant biotechnology. Planta Med. 56: Ensminger A.H., Ensminger, M. E., Konlande, J.E., and J.R.K. Robson, J.R.K. (1983). Food & Nutrition Encyclopedia. Vol. 2, pp , Pegus Press, Clovis, California, U.S.A. 442

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