In vitro conservation of some threatened and economically important ferns belonging to the Indian subcontinent.
Pteridophytes constitute an important part of the plant kingdom, as they are worldwide in distribution, with 12,000 species distributed in a wide range of habitats. Pteridophytes have enormous economic potentiality
as medicine, sources of food, fodder, fibre, flavouring agents, aromatic oil, perfume, dyes, and folk remedies [1-3]. In recent times ferns have also proved themselves valuable as pollution indicators, as well as insect repellents, and some species have the ability to hyperaccumulate noxious metals and metalloids, making them good phytoremediators [4-6]. In addition to their popularity as ornamental plants in the cut flower industry, pteridophytes have been employed in Ayurvedic, Homoeopathic, and Unani systems of medicine since the times of Charaka and Sushruta. The aesthetic appeal and exquisite foliage patterns make them popular plants for landscaping. According to a recent agricultural and industrial survey , the world floriculture trade of cut flowers, green plants, and cut greens in 1995 was US $ 6.8 billion, of which 55 percent were cut flowers, 37 percent green plants, and 8 percent cut greens.
Due to overexploitation, habitat destruction, and other biotic interferences, numerous pteridophytic species are threatened and some are critically endangered. Bir  identified 100 species as threatened from throughout India, but little is known about the conservation status of many of the ferns, and only 33 of those species have been categorized in red books. Chandra and Khare  enumerated 58 species as threatened, out of which 18 taxa are endangered from the Kumaon Himalayas (India) region only.
Ferns are conventionally propagated both by sexual as well as vegetative methods. The sexual method of propagation involves raising plants from spores, whereas the vegetative method involves propagation of specialized vegetative organs, such as bulbils, proliferous frond tip, aerial growths, stolon and tubers, offsets, gemmae, stipules, and root buds. These methods require more time and are comparatively slow. In India, in comparison to angiosperms, few attempts have been made on in vitro studies in ferns and fern-allies. Vascular cryptogams, especially ferns, have not been very favourable material for tissue culture because their vascular system is made up of highly differentiated tissues that are difficult to proliferate into cell masses capable of growth in vitro . Although different workers have tried to initiate in vitro studies on ferns, very little work on tissue culture of pteridophytes is reported 11].
The present investigation deals with collection and in vitro and ex situ conservation of eight economically important and threatened taxa of pteridophytes belonging to different biodiversity zones of the Indian subcontinent. These ferns are economically important, and C. spinulosa, P. calomelanos, and M. punctatum are listed in Red Data Book as threatened species, so the work presented here would be beneficial for the biological conservation of threatened ferns as well as commercial production of ornamental ferns through in vitro techniques.
2. Materials and Methods
2.1. Collection of Plant Material and Type of Explants Used. In vitro studies were undertaken on the following fern species: Pteris vittata L., Nephrolepis biserrata (Sw.) Schott., N. cordifolia cv. duffii (L.) Presl., N. exaltata cv. bostoniensis (L.) Schott., Cyathea spinulosa Wall. ex Hook., Microsorum punctatum (L.) Copel., Cyclosorus dentatus Link., and Pityrogramma calomelanos (L.) Link. Among these fern species, P. vittata, N. biserrata, N. cordifolia cv. duffii, N. exaltata cv. bostoniensis, M. punctatum, and C. dentatus were collected from different phytogeographic region of India and successfully grown in the Fern House of CSIR-NBRI, Lucknow. Spores of C. spinulosa and P. calomelanos were collected from Didihat, in the Pithoragarh district of Kumaon Himalayas (Uttaranchal), Northeast region and Kodaikanal, Tirunelveli Tamilnadu, respectively (Figure 1; Table 1).
In the present study, explants from leaf primordia (0.51 cm.) from the fresh plant of P. vittata, N. cordifolia cv. duffii, N. exaltata cv. bostoniensis, M. punctatum, and C. dentatus were used, whereas, in case of C. spinulosa and P. calomelanos, leaf primordium (0.5 cm) of in vitro-raised sporophyte was used as explants. In the case of N. biserrata, stolon explants obtained from the live plant population growing in the Fernery of CSIR-NBRI, Lucknow.
2.2. Raising Aseptic Cultures and Multiplication. Explants were first washed thoroughly for 1-2 hours under tap water. The explants were then disinfected with 50-75% ethanol for a few seconds (depending upon the nature of explant) and subsequently surface was sterilized with Hg[Cl.sub.2] solution (0.1% w/v). Finally, repeated rinsing of the explants was done with sterile double distilled water. Treatment time varied from plant to plant and from explant to explant. Stolon parts were treated for 5-10 min, spore, leaf primordium, circinate part of young fronds and leaf primordium, procured from in vitro-raised sporophytes, were treated for 2-5, 2-10, 5-10, and 1-2 min, respectively. The explants were then thoroughly washed with sterile double distilled water (3-4 times). Sterilized explants were inoculated into the P&T, MS, and KnD media with at full, half, and one-fourth strength with different combinations of growth hormones along with various percentages of agar and sugar. More than 50 media combinations were tested for raising aseptic cultures of all the fern species. According to the morphogenetic response required, medium recipes were made by using basal media fortified with different ranges of 2, 4-D, IBA, IAA, KN, and NAA. Three replicate cultures for each treatment were incubated in a culture room under 38 [micro] mol [m.sup.-2] [s.sup.-1] fluorescent light for 15hrs per day. Temperature and humidity of the culture room were maintained at 25 [+ or -] 2[degrees]C and about 60-70 percent RH, respectively. The period of incubation usually varied from 30 to 45 days according to the need of the experiment. Cultures were raised in 19.5 cm long x 3.5 cm diameter and 15 cm long x 2.5 cm diameter culture tubes as well as in Petri dishes of 100 mm x 17 mm and 80 mm x 17 mm size.
2.3. Fern House Hardening. In vitro regenerated plantlets, growing in aseptic cultures, were rooted successfully in the liquid P&T media . The rooted plantlets were acclimatized in a solution consisting of only the inorganic salts of the same P&T media, before their final transplantation to potted soil. The plantlets along with their roots were carefully taken out of the Petri dishes with the help of forceps. Roots of the plantlets were thoroughly washed under running tap water to remove the entire adhering nutrient agar. After rinsing with distilled water, they were acclimatized in inorganic salt solution at least for a period of ca. 20 days. The nutrient solution was periodically changed every 5 days while the root system of plantlets was also thoroughly washed with double distilled water.
The acclimatized plants were transplanted in small earthen pots containing a mixture of soil and leaf mould in the ratio of 2: 1. The earthen pots along with the potting mixture were sterilized by autoclaving at 0.7 kg/[cm.sup.2] pressures for 10 min. before transplantation. The plants were initially covered with polyethylene chambers for a period of 4 to 8 days after transfer in liquid as well as in potted soil to prevent them from desiccation. Plants of two species (C. spinulosa and N. biserrata) were later grown under Fern House conditions to observe their performance (Table 2).
3. Results and Discussion
Eight threatened and economically important ferns were successfully established in vitro at various morphogenic levels. Details pertaining to optimized media combination and morphogenic levels are given in Table 2. C. spinulosa and P vittata showed both induction and proliferation of callus as well as shoots. P. calomelanos and M. punctatum were established only at the callus level, while N. exaltata cv. "bostoniensis" and C. dentatus were maintained only at shoot level. An efficient in vitro protocol has been standardized for the commercial production of an ornamental fern, N. biserrata through stolon explants. A threatened tree fern, C. spinulosa, has been multiplied by two methods: through caulogenesis from leaf primordium explants procured from in vitro-raised sporophyte and direct spore culture (; Figure 2). Leaf primordium explants obtained from fresh plants growing in Fernery of NBRI, Lucknow, were used and evaluated for their regenerative potentiality in vitro in case of P vittata, M. punctatum, and C. dentatus. In case of P vittata leaf primordium explants showed better response for the callusing with GGBs and multiple shoots, which had been tried for the first time.
All the shoot cultures showed first bud break within 20-30 days, except for C. spinulosa, which required a longer time (three months) to show first bud emergence. Out of these cultures, friable callus of only C. spinulosa and P vittata gave rise to differentiation of multiple shoots. Cultures of N. cordifolia cv. "duffii" and N. exaltata cv. "bostoniensis" showed excessive leaching of phenolics in the medium; therefore, they were subcultured frequently. Supplementation of 40 mg/I ascorbic acid in the respective media of N. cordifolia cv. "duffii" and N. exaltata cv. "bostoniensis" was able to control the leaching and browning to certain extent, but frequent subculturing was the only feasible option observed in these plant species. Characteristic GGBs formation was observed within 15 days in P. vittata cultures.
The shoots of N. biserrata, P vittata, and C. spinulosa were highly proliferating. P. vittata and C. spinulosa showed 100% germination rate of spore culture while only 50% and 70% spore germination was observed in M. punctatum and P. calomelanos, respectively. Rooting was observed in N. biserrata, N. cordifolia cv. "duffii," C. spinulosa, and P. vittata. Rooted plants were successfully transferred to the fern house with a success rate of 60-80% (N. cordifolia cv. "duffii" and C. spinulosa) and 100% (N. biserrata and P. vittata) Table 2).
In the present study, the morphogenetic potentialities of vegetative explants of three Nephrolepis species, namely, N. biserrata, N. cordifolia cv. duffii, and N. exaltata cv. bostoniensis were studied with a view to primarily develop methods of organogenesis and, subsequently, production of plantlets. In the case of N. biserrata, the explants of stolons were employed to induce differentiation of regenerants in them. In the course of investigation, the proper combinations and balances of growth hormones with appropriate inorganic salt media were enumerated for direct differentiation of regenerants from explants. Regeneration of plants from explants without intervening callus formation was reported to mostly produce genetically identical plants, in contrast with the formation of plants via callus, in which case, the genetically variable plants may be produced [14-17]. The three Nephrolepis species differed in their regenerative potentialities, which depended on the nature of explants used. The stolon explants used in the case of N. biserrata were highly regenerative, whereas leaf primordium explants of N. cordifolia cv. "duffii" and N. exaltata cv. "bostoniensis" were comparatively less regenerative. This may be due to higher meristematic tissue activity in stolon explants in comparison to leaf primordium explants. Survey of the literature revealed very few reports of economically important ferns that have been multiplied through in vitro method. The most prominent example of mass multiplication of an economically important fern is N. exaltata  in which callus induction was reported from provascular tissue of terminal and lateral buds of stolon tips. Some other reports are available on other species of Nephrolepis, N. cordifolia [19-21], and N. exaltata [14, 22-25], on morphogenetic studies pertaining to the micropropagation on a small scale. In vitro-regenerated plants had to be acclimatized in an inorganic salt solution for about two weeks in order to get 100 percent transplantation success in soil. The liquid culture phase for acclimatization of in vitro-raised plants was also necessary before transplantation in soil in case of N. biserrata , whereas in case of Cheilanthes viridis and Diplazium cognatum and Matteuccia struthiopteris direct plantlet transplantation in soil was successful [27, 28], which maybe due to tropical rain condition of the area, which was not prevailing in other areas including the present study, where a liquid culture phase was essential for acclimatization. In N. biserrata, when NAA was substituted with BAP with 2,4-D (2 [mgL.sup.-1]), shoot regeneration in stolon explants was augmented, and this was also more effective than other synthetic auxin. Reports are available on the effects of Kn and NAA on in vitro shoot multiplication and rooting in N. exaltata cv. "bostoniensis" through runner tip culture . These reports clearly indicated that Kn in combination with low concentration of NAA (0.5-1 [mgL.sup.-1]) produced shoots. The present investigation was carried out to identify the most appropriate culture media for in vitro mass propagation of three species of Nephrolepis, namely, N. biserrata, N. cordifolia cv. "duffii," and N. exaltata cv. "bostoniensis," because no such investigation has been reported to date. Some cultivars of this taxon are sterile , and economically very significant; thus, propagation through tissue culture technique is required.
Callus was induced from explants of leaf primordial of P. vittata in order to utilize it for morphogenetic studies. In ferns generally the nutritional requirements for callus induction and differentiation have been reported to be simple 31]. Callus production and its differentiation from leaf primordium is a comparatively difficult task because the percentage of contamination is high in the explants of young circinate fronds owing to their coiled pubescent nature. Kshirsagar and Mehta  reported induction and growth of callus from rhizome segments of P. vittata on "W" medium supplemented with 2, 4-D alone. In the present study, 2, 4-D used alone at various concentrations failed to induce callusing from explants of leaf primordia. However, 2, 4-D used with BAP was most effective for induction and fast growth of callus at its higher concentration, whereas its low concentration produced a green, compact, and globular callus indicating formation of GGBs. In vitro callusing was achieved in in vitro-raised frond tip explants of P calomelanos and M. punctatum on full-strength of KnD medium supplemented with 2,4-D (1 [mgL.sup.-1]) and one-fourth strength of MS medium without hormone, but differentiation of callus was not achieved, whereas, in the cases of N. exaltata cv. bostoniensis and C. dentatus, regeneration of shoots took place on full-strength MS medium supplemented with 2,4-D (2[mgL.sup.-1]) and BAP (0.5 [mgL.sup.-1]) and full-strength P&T medium supplemented with BAP (1[mgL.sup.-1]) and IAA (0.5 [mgL.sup.-1]), respectively. During the course of investigation these taxa showed recalcitrant characteristics on in vitro studies (Figure 2).
In vitro studies on ferns and fern-allies are very meagre in comparison to angiospermic plants. Through the present study, economically valuable and endangered ferns were assessed for in vitro studies, which may help for mass-multiplication. Several pteridophytic plants are under the threat of overexploitation and biodiversity depletion. There is urgent need of their ex situ conservation. Collection and in vitro cloning and conservation of the 8 economically important ferns in the present study open fresh avenues towards the conservation and resource management of the overexploited pteridophytic plants.
CSIR: Council of Scientific and Industrial Research
2,4-D: 2,4-dichlorophenoxy acetic acid
GGBs: Green globular bodies
GR: Growth regulator
Hg[Cl.sub.2]: Mercuric chloride
IAA: Indole-3-acetic acid
IBA: Indole-3-butyric acid
KnD: Knudson medium
MS: Murashige and Skoog medium
NAA: [alpha] Naphthalene acetic acid
NBRI: National Botanical Research Institute
P&T: Parker & Thompson's media
W: White medium.
Conflict of Interests
The authors declare that they have no conflict of interests.
Shastri P. Shukla conceptualized and wrote the first draft of the paper; P. B. Khare helped in maintaining in vitro cultures.
The authors thank the Director of CSIR-NBRI, Lucknow, for providing the necessary facilities to carry out this work. Shastri P. Shukla is particularly thankful to the Department of Biotechnology, Government of India, New Delhi, for providing the fellowship in the form of Senior Project Fellow during the course of study (2003-2006).
 R. N. Chopra, I. C. Chopra, K. L. Handa, and L. D. Kapur, Chopra's Indigenous Drugs of India, U. N. Dhur and Sons Pvt. Ltd., Calcutta, India, 1958.
 L. Rymer, "The history and ethnobotany of bracken," Botanical Journal oftheLinnean Society, vol. 73, no. 1-3, pp. 151-176,1976.
 L. W. May, "The economic uses and associated folklore of ferns and fern allies," The Botanical Review, vol. 44, no. 4, pp. 491-528, 1978.
 S. Devi and P. B. Khare, "Environmental significance of fern spores," Biological Memoirs, vol. 6, pp. 62-66,1981.
 S. Kaur, "Economic exploitation and conservation: emerging areas in the study of ferns and fern allies," Indian Fern Journal, vol. 6, pp. 23-29, 1989.
 L. Q. Ma, K. M. Komar, C. Z. Tu, C. Y. Weihua, and E. D. Kennelley, "A fern that hyperaccumulates arsenic," Nature, vol. 409, article 579, 2001.
 UNCTAD/WTO (1996) United Nations Comtrade Database, ITC, October 1996.
 S. S. Bir, "Pteridophytic flora of India. Rare and endangered elements and their conservation," Indian Fern Journal, vol. 4, pp. 95-101,1987.
 S. Chandra and P. B. Khare, "Diversity and distribution of pteridophytic flora of Kumaon Himalayas with special reference to threatened taxa," Project Completion Report, Department of Science and Technology, Government of India, New Delhi, India, 2003.
 G. Morel and M. R. Wetmore, "Tissue culture of monocotyledons," American Journal of Botany, vol. 38, pp. 138-140,1951.
 F. E. George, "Micropropagation in practice. Ferns and glub mosses," in Plant Propagation by Tissue Culture. Part I. The Technology, pp. 909-916, Exegetic, Wiltshire, UK, 1993.
 E. J. Klekowski, "Reproductive biology of the Pteridophyta. II. Theoretical consideration," Botanical Journal of the Linnean Society, vol. 62, pp. 347-359,1969.
 S. P. Shukla and P. B. Khare, "In-vitro mass multiplication of a threatened tree fern, Cyathea spinulosa Wall.ex Hook," International Journal of Genetic Engineering and Biotechnology, vol. 3, no. 1, pp. 15-23, 2012.
 T. Murashige, "Plant propagation through tissue culture," Annual Review of Plant Biology, vol. 25, pp. 135-166, 1974.
 J. I. Kunisaki, "Tissue culture of tropical ornamental plants," Horticultural Science, vol. 12, pp. 141-142,1977
 I. K. Vasil and V. Vasil, "Clonal propagation," in Perspectives in Plan Cell and Tissue Culture, I. K. Vasil, Ed., vol. 11 of Int. Rev. Cytol. Suppl., pp. 145-173, Academic Press, London, UK, 1980.
 G. S. Hicks, "Patterns of organ development in plant tissue culture and the problem of organ determination," The Botanical Review, vol. 46, no. 1, pp. 1-23,1980.
 E. B. Thomas and J. D. Caponetti, "Morphogenesis in three cultivars of boston fern III. Callus production and plantlet differentiation from cell suspensions," The American Fern Journal, vol. 82, no. 1, pp. 12-22,1992.
 D. S. Sulklyan and P. N. Mehra, "In-vitro morphogenetic studies in Nephrolepis cordifolia," Phytomorphology, vol. 27, pp. 396-407, 1977.
 H. Higuchi, W. Amaki, and S. Suzuki, "In vitro propagation of Nephrolepis cordifolia Prsel," Scientia Horticulturae, vol. 32, no. 1-2, pp. 105-113,1987
 W. Amaki and H. Higuchi, "A possible propagation system of Nephrolepis, Asplenium, Pteris, Adiantum and Rumohra (Arachniodes) through tissue culture," Acta Horticulturae, vol. 300, pp. 237-243, 1991.
 K. L. Harper, A sexual multiplication of leptosporangiate ferns through tissue culture [M.S. thesis], University of California, Riverside, Riverside, Calif, USA, 1976.
 M. A. Padhya, "Mass propagation of ferns through tissue culture," Acta Horticulturae, vol. 212, pp. 645-649,1987
 M. A. Padhya and A. R. Mehta, "Propagation of fern (Nephrolepis) through tissue culture," Plant Cell Reports, vol. 1, no. 6, pp. 261-263, 1982.
 M. Camloh, N. Gogala, and R. Ruzic, "The micropropagation of Nephrolepis exaltata," Bioloski Vestnik, vol. 37, no. 3, pp. 23-32, 1989.
 P. B. Khare and S. P. Shukla, "In vitro shoot regeneration in stolon explant of an ornamental fern, Nephrolepis biserrata," Phytomorphology, vol. 53, no. 3-4, pp. 229-233, 2003.
 V. S. Manickam, S. Vallinayagam, and M. Johnson, "Micropropagation and conservation of rare and endangered ferns of the southern western Ghats through in vitro culture," in Pteridology in the New Millennium, pp. 497-504, Kluwer Academic Publishers, 2003.
 P. von Aderkas, "Enhancement of apospory in liquid culture of Matteuccia struthioptens," Annals of Botany, vol. 57, no. 4, pp. 505-510, 1986.
 M. J. Beck and J. D. Caponetti, "The effects of kinetin and NAA on in-vitro shoot multiplication and rooting in the fishtail fern," The American Journal of Botany, vol. 70, no. 1, pp. 1-7, 1983.
 C. V. Morton, "Observations on cultivated ferns. V. The species and forms of Nephrolepis" American Fern Journal, vol. 48, pp. 18-27, 1958.
 P. N. Mehra and D. S. Sulklyan, "In vitro studies on apogamy, apospory and controlled differentiation of rhizome segments of the fern, Ampelopteris prolifera (Retz.) Copel," Botanical Journal of the Linnean Society, vol. 62, no. 4, pp. 431-443, 1969.
 M. K. Kshirsagar and A. R. Mehta, "In-vitro studies in ferns: growth and differentiation in rhizome callus of Pteris vittata" Phytomorphology, vol. 28, pp. 50-58, 1978.
Shastri P. Shukla (1) and P. B. Khare (2)
(1) Plant Tissue Culture Laboratory, Plant Biotechnology Division, Central Institute of Medicinal and Aromatic Plants (CIMAP), Council of Scientific and Industrial Research, P.O. CIMAP, Lucknow 226015, India
(2) Pteridology Laboratory, National Botanical Research Institute (NBRI), Council of Scientific and Industrial Research, Rana Pratap Marg, Lucknow 226001, India
Correspondence should be addressed to Shastri P. Shukla; email@example.com
Received 1 May 2014; Revised 17 June 2014; Accepted 26 June 2014; Published 10 July 2014
Academic Editor: Curtis C. Daehler
TABLE 1: Details of the pteridophytic plants collected, importance, and their site of collection for in vitro conservation. S. number Pteridophytic taxa Family Part used 1 Nephrolepis Nephrolepidaceae Whole plant biserrata 2 N. cordifolia cv. Nephrolepidaceae Whole plant, L duffii young leaves 3 N. exaltata cv. Nephrolepidaceae Whole plant, bostoniensis young leaves 4 Cyathea Cyatheaceae Trunk and spinulosa pith 5 Pityrogramma Hemioitidaceae Whole plant calomelanos 6 Microsoium Polypodiaceae Fronds punctatum 7 Pteris vittata Pteridaceae Whole plant 8 Cyclosorus Thelypteridaceae Whole plant dentatus Conservation Zone of S. number status Importance collection 1 -- Ornamental fern, much Gangetic plain demand in nursery trait and cut flower industry. Cultivated in the botanical gardens as ornamentals and as potted plants for indoor decoration. 2 -- Ornamental fern. Young Gangetic plain leaves are cooked as vegetable by the tribals. 3 -- Ornamental fern, much Gangetic plain demand in nursery trait and cut flower industry. Cultivated in the botanical gardens as ornamentals and as potted plants for indoor decoration. 4 Threatened A threatened tree fern Kumaon, listed in Red-Data Book. Northeast Trunk is extensively Himalaya using in the orchid cultivation. Pith from the trunks is used as a food product 5 Threatened A threatened tree fern Tamilnadu listed in Red-Data Book. It is hyperaccumulator of arsenic 6 Threatened A threatened tree fern Western listed in Red-Data Book Himalayas and a popular houseplant. Much demand in nursery trait as an economically important fern due to its edible value in Asia and Pacific region.The cooked fronds of this fern are consumed in New Guinea. 7 -- An ornamental fern. Gangetic plain Hyperaccumulator of arsenic. In Florida, USA it is using as a phytoremediator in arsenic-enriched soil. 8 -- An ornamental fern Gangetic plain TABLE 2: Morphogenic level along with the optimised medium and glasshouse hardening status of 8 plant species processed for in vitro conservation. Callus (GR in S. No Plant species Explant used mg [L.sup.-1]) 1 Nephrolepis Stolon -- biserrata 2 N. cordifolia cv. Leaf primordium -- duffii 3 N. exaltata cv. Leaf primordium -- bostoniensis 4 Cyathea Leaf primordium KnD + 2,4-D (2.0) spinulosa procured from in vitro-raised sporophytes Spore -- 5 Pityrogramma Circinate part of KnD + 2,4-D (1.0) calomelanos young fronds Spore -- 6 Microsorum Leaf 1/4 strength of MS punctatum primordium medium (Hormone- free) Spore -- 7 Pteris vittata Leaf primordium MS + 2,4-D (2.0) + BAP (0.5) GGBs- MS + 2,4-D (0.5) + BAP (0.5) 8 Cyclosorus Leaf primordium -- dentatus Cultures established at the level of axillary/multiple Rooted plants S. No shoots (GR in mg [L.sup.-1]) (GR in mg [L.sup.-1]) 1 P&T + 2,4-D (2.0) + NAA (2.0) P&T + IAA (1.0) 2 P&T + 2,4-D (2.0) + BAP (2.0) P&T + NAA (2.0) + Kn (1.0) 3 MS + 2,4-D (1.0) + BAP (0.5) -- 4 P&T + BAP (2.0) + NAA (1.0) P&T + IBA (1.0) P&T basal media P&T basal media 5 -- -- P&T basal media P&T basal media 6 -- -- P&T basal media P&T basal media 7 MS + IAA (0.5) P&T + NAA (1.0) + BAP (2.0) + BAP (0.5) 8 P&T + BAP (1.0) + IAA (0.5) Time taken/ Number success rate of during S. No replicates hardening 1 10 2 wks/100% 2 10 3-4 wks/60% 3 10 -- 4 10 3-4 wks/100% 10 3-4wks/80% 5 10 -- 10 5-7 wks/70% 6 10 -- 10 5-7 wks/50% 7 10 3-4 wks/100% 8 10
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|Title Annotation:||Research Article|
|Author:||Shukla, Shastri P.; Khare, P.B.|
|Publication:||Journal of Botany|
|Date:||Jan 1, 2014|
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