|Year : 2013 | Volume
| Issue : 2 | Page : 86-92
Regeneration of multiple shoots from petiole callus of Viola serpens Wall
Umashankar Radheshyam Vishwakarma, Arun Manohar Gurav, Prakash Chandra Sharma
Department of Botany, National Research Institute of Basic Ayurvedic Sciences, Kothrud, Pune, MH, India
|Date of Submission||20-Aug-2012|
|Date of Decision||27-Sep-2012|
|Date of Web Publication||15-Apr-2013|
Arun Manohar Gurav
National Research Institute of Basic Ayurvedic Sciences, Kothrud, Pune, MH
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Experiments were conducted to develop methodology for in vitro propagation and rapid multiplication of Viola serpens Wall. using petiole explant. The MS medium supplemented with 2, 4-D (6.78 μm) was found most suitable for callus induction in petiole explant. The best growth response and higher rate of shoot regeneration from petiole callus was observed on MS medium containing BAP (11.10 μm) as the average number of shoots could be increased to 36.4 on fourth successive subculturing. Higher rooting response with larger number of roots were observed in shoots inoculated on the half-strength MS medium supplemented with IBA (19.68 μm).
Keywords: Callus, growth regulators, multiple shoots, petiole, Viola serpens
|How to cite this article:|
Vishwakarma UR, Gurav AM, Sharma PC. Regeneration of multiple shoots from petiole callus of Viola serpens Wall. Phcog Res 2013;5:86-92
|How to cite this URL:|
Vishwakarma UR, Gurav AM, Sharma PC. Regeneration of multiple shoots from petiole callus of Viola serpens Wall. Phcog Res [serial online] 2013 [cited 2020 May 25];5:86-92. Available from: http://www.phcogres.com/text.asp?2013/5/2/86/110533
| Introduction|| |
Viola serpens Wall. belongs to family Violaceae and commonly known as "Banafsha." It is a small glabrous, perennial herb, which is found throughout India in moist woods and hilly districts. It is also found in China, Java, Ceylon, Philippines, and Thailand up to an altitude of 2000 m. In India, it is distributed in the Himalayan region, hills of Meghalaya, Nagaland, and Manipur. ,,, It is also found in Ganjam hills of Orissa, , Himachal Pradesh, Tehri Garhwal in Uttar Pradesh,  Karnataka,  and Tamilnadu. 
The whole plant is medicinally useful. It is aperients, antiseptic, antipyretic, cooling, demulcent, diaphoretic, diuretic, emetic, emollient, expectorant, febrifuge, and purgative in action. It is useful in asthma, bleeding piles, cancer of throat, constipation, cough, fever, headache, and skin diseases. , This species also yields "Banafsha" of the bazaars and is considered to have medicinal properties similar to those of Viola odorata L. A decoction of flowers is administered for improving the complexion. It is also used in bilious and pulmonary affections. In Unani system of medicine, this plant is the main ingredient of "Joshanda" consisting mixture of drugs, used mainly for cough and cold in the form of decoction. A medicinal oil called "Raughan -e- banafsha", "Banafshadi-kwath," "Gulkand banafsha", and "Banafsha syrups" are prepared fromit. , The plant is propagated by divisions, cuttings or seeds. It grows well in a cool and moist climate, but exposure to heavy or frequent rains is fatal for its blooming. The soil and climatic conditions of Tehri-Garhwal (Uttar Pradesh), Shimla, Kullu, Kinnaur, Sirmour, and Chamba (Himachal Pradesh) are conducive for large-scale cultivation of this plant. However, commercial cultivation of this species has not been taken up so far. The localities traditionally known as rich are exploited heavily and this has adversely affected the natural regeneration, the result being that the plant is facing much depletion in nature. Further regular collection of the drug in an area without periodical resting time and lack of maintenance have increased their cost of collection. The quantity of Viola serpens Wall. exported from Himachal Pradesh has declined from 1991 to 1992.  Therefore, it is necessary to provide protection to these areas and to permit natural regeneration and simultaneously to bring out the plant under cultivation. Department of Indian Systems of Medicine and Homeopathy of the Ministry of Health and Family Welfare, Government of India has formulated a scheme for cultivation and development of medicinal plants wherein they have identified some species, Viola serpens Wall. being one of them, for promoting their cultivation in order to reduce pressure on their natural habitat and to meet the demand of the industry involved in producing the Indian Systems of Medicine. 
There is no report on tissue culture studies of Viola serpens Wall., though such studies on other species of Viola have been reported, such as Viola odorata L.,  Viola patrinii DC.,  and Viola wittrockiana.  Therefore, efforts were made to develop methodology for in vitro propagation of Viola serpens Wall.
| Materials and Methods|| |
Young plants of Viola serpens Wall. (Banafsha) were procured from Ranikhet and grown at Jawaharlal Nehru Ayurvedic Medicinal Plants Garden and Herbarium, Pune, in green house were used for in vitro propagation experiments. The excised leaf petioles of 1 cm length were washed in tap water for 15 min, then soaked in 5% Teepol solution for 5 min and washed again with tap water. The explants were then treated with 0.1% HgCl 2 solution for 1 min followed by several times washing with sterile water under aseptic conditions. These petiole explants were ruptured in the groove region by taking sharp cut with the surgical blade and inoculated on MS medium with varying concentrations of Kn, BAP, IAA, IBA, NAA and 2, 4-D, for induction of callus. The pH of medium was adjusted to 5.7 with 1N NaOH/1N HCl, before addition of 0.8% agar and autoclaved at 15 lb/inch 2 pressure and 121°C temperature for 20 min. The callus was subcultured on MS medium supplemented with BAP and Kn, singly, in varying concentrations for differentiation. Well-developed shoots (2-3 cm) from regenerating explants were excised and rooted on half- and full-strength MS plain medium and medium supplemented with IAA and IBA, singly, in different concentrations. The cultures were maintained at 25°C ± 2°C with 8/16-h (light/dark) photoperiod provided through white fluorescent tubes with light intensity of 3000 lux.
Observations were made every day. A mean of three replicates was taken for each explant, to see the callus growth under different nutritive conditions. The callus cultures were harvested and weighed after a growth period of 28 days. Dry weight was determined after 7 days drying in an incubator at 40°C. In differentiation studies, the number of shoots developed in a particular treatment was used as an index for comparison. Data obtained from the experiments were analyzed for mean and standard error using software SYSTAT 11(Stat Soft Inc.).
| Results|| |
Effect of phytohormones on callus induction and growth
Petiole explants inoculated on MS plain medium and MS medium supplemented with Kn, BAP, IAA, IBA, and NAA, singly, in different concentrations, did not show any positive response toward callusing (data not given). However, the petiole explants inoculated on MS medium supplemented with 2, 4-D (6.78 and 9.05 μm) alone and in combination with BAP (6.66-15.53 μm) or Kn (6.97-16.26 μm) inducing the callus in petiole explants. Initially, petiole explants showed swelling after 4 days of inoculation [Figure 1]. After subculturing on the same medium, callus formation was observed within 7 days. The callus was initially developed at the ruptured portion in the groove and finally in the middle part of the explant. This callus was negligible, whitish and crystalline in nature [Figure 2]. On subsequent subculture on the same medium, callus grew in size [Figure 3]. MS medium with 2, 4-D (6.78 μm) was found best for callus induction from in vitro petiole explants with higher induction percentage (71%) [Table 1]. The quantity of dry callus (harvested after 28 days growth period) obtained on MS+2, 4-D (6.78 μm) and MS+2, 4-D (9.05 μm) was 142 mg and 127 mg per explant, respectively [Table 2]. Although the callus induction was observed in petiole explants inoculated on MS medium supplemented with 2, 4-D (6.78 μm) in combination with BAP (6.66-15.53 μm) or Kn (6.97-16.26 μm), the frequency of callus induction and dry weights of callus obtained decreased as compared to MS medium supplemented with 2, 4-D alone. It means 2, 4-D alone was very effective in inducing callus in petiole explants of Viola serpens Wall.
|Table 1: Effect of phytohormones on petiole explant of Viola serpens wall|
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|Table 2: Effect of phytohormones on growth of petiole callus of Viola serpens wall|
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Effect of phytohormones on callus differentiation
The whitish and crystalline callus obtained from aforesaid trials was subcultured on MS medium supplemented with BAP (6.66, 11.10, and 15.53 μm) and Kn (6.97, 11.61, and 16.26 μm), singly. The regeneration of multiple shoots from petiole callus was observed in all the concentrations tried. The callus subcultured on MS+BAP (6.66-15.53 μm) and MS+Kn (6.97-16.26 μm) increased in size and developed fibrous roots within 7 days, which turned greenish in color in next 9-10 days, and these roots did not show any growth further [Figure 4]. 100% callus explants showed development of fibrous roots. When these cultures were maintained further, formation of active green callus was observed after 2-3 weeks [Figure 5]. Subculturing the active callus on the same medium, i.e., MS+BAP (6.66-15.53 μm) and MS+Kn (6.97-16.26 μm), it increased in size and formation of shoot buds was observed, followed by regeneration of multiple shoots (4-6 per explant) explants within 7-10 days. The formation of shoot buds and regeneration of multiple shoots was observed from upper and lower surfaces of the callus [Figure 6]. When the cluster of multiple shoots with callus was subcultured on the same medium, the number of shoots were increased. Among different concentrations of BAP tried, BAP (11.10 μm) found highly effective in multiple shoot regeneration, as after fourth subsequent subculture, the average number of shoots (2.6 cm height) per explants increased up to 36.4 [Figure 7]. Kinetin was found less effective compared to BAP, since after fourth subsequent subculture the average number of shoots (1.7 cm height) could be increased up to 22, on MS medium supplemented with Kn (11.61 μm) [Table 3].
|Table 3: Effect of phytohormones on regeneration of multiple shoots from petiole callus of Viola serpens wall|
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Effect of phytohormones on in vitro rooting
To obtain the complete plantlet, in vitro grown shoots were separated and subcultured on full- and half-strength MS medium with or without auxins (IAA and IBA) in various concentrations. No rooting was observed in shoots inoculated on full strength and half- strength MS plain media. Rooting was observed in shoots inoculated on full strength as well as half strength MS media supplemented with IBA in all concentrations tried after 10-14 days, whereas on full strength MS medium it took 3 weeks [Figure 8]. Highest percentage of rooting (73.01%) was observed on half strength MS medium supplemented with 19.68 μm IBA, the average number of roots per shoot being 4.1. Whereas on full strength MS medium, maximum percentage was 17.44% in the medium containing 19.68 μm IBA with an average of two roots per shoot [Table 4]. All the shoots inoculated on half strength MS medium supplemented with IAA showed rooting, in all concentrations used. Highest rooting percentage (30.15%) and average number of roots per shoot (4.3) were obtained on medium containing 22.83 μm IAA [Table 5].
| Discussion|| |
Effect of phytohormones on callus induction and growth
The cytokinins, i.e., BAP and Kn, and auxins, i.e., IAA, IBA and NAA, did not show any effect on petiole explant when added in MS medium individually, but the BAP and Kn showed callus induction when added in combination with 2, 4-D (6.78 μm). The 2, 4-D (6.78 and 9.05 μm) alone also induced callusing in petiole explant of Viola serpens Wall. It means that addition of 2, 4-D in the medium is necessary to induce callusing. The best results in terms of callus induction and growth were obtained on MS+2, 4-D (6.78 μm) medium. On MS medium, there was a gradual increase in growth with 2, 4-D alone as well as in combination with BAP and Kn. However, MS medium supplemented with 2, 4-D alone showed better growth. In the present studies, supplementation of merely 2, 4-D (6.78 μm) in the medium gave satisfactory results. In Trifolium pratense L., callus induction was observed in petiole explant on B5 medium fortified with Kn in combination with NAA and 2, 4-D.  In Viola wittrockiana, callus induction in petiole explants was reported when inoculated on half-strength MS medium supplemented with 2, 4-D and BAP in combination. In poplar species, also callus initiation from the petioles took place on N 6 medium containing 2, 4-D.  It indicates that 2, 4-D is necessary to induced callusing. Murashige (1974) and Razdan (1993) had reported that 2, 4-D is a strong auxin for stimulating callus. This study supports their findings. ,
Effect of phytohormones on callus differentiation
It has been observed from earlier reports that in vitro propagation is possible through callus in Viola species. Regeneration of shoots from 5 years friable callus derived from petiole tissues of Viola patrinii DC occurred most effectively on MS medium containing two-folds diluted basal salts, 5 × 10 -6 M 1-naphthalene acetic acid and 10 -6 Kinetin.  In Viola wittrockiana multiple shoot regeneration from petiole callus was observed on half-strength MS medium when supplemented with BAP in combination with TDZ and NAA.  In this study, it has been observed that multiple shoot regeneration is possible through petiole callus in Viola serpens Wall. on MS medium supplemented with BAP (6.66, 11.10, and 15.53 μm) and Kn (6.97, 11.61, and 16.26 μm), alone. In Viola serpens Wall., BAP was found more effective than Kn in shoot regeneration. Highest rate of shoot induction was observed with 11.10 μm BAP as compared to other concentrations. The superiority of BAP over Kn in multiple shoot induction was also reported in a number of medicinal plants such as Centella asiatica (L.) Urban,  Bacopa monneri L., ,31,32 Psidum guajava L.,  Piper sp.,  Citrus sp.,  Zingiber officinale Rosc.,  Desmodium gangeticum (L.) DC.,  and Arachis hypogea L. 
Effect of phytohormones on in vitro rooting
Root initiation was observed in shoots of Viola serpens Wall. inoculated on full-strength and half-strength MS media supplemented with IAA and IBA. However, the half-strength MS medium supplemented with IBA (19.68 μm) was found better for rooting, it gave 73.01% rooting response with 3.6 average number of roots having average length of 1.3 cm. Although IAA also induced rooting, percentage of rooting was less as compared to that obtained with IBA.
| Conclusion|| |
The cytokinins and auxins failed to induce callusing in petiole explant, when added to MS medium singly except 2, 4-D (6.78 and 9.05 μm). The MS medium supplemented with 2, 4-D (6.78 μm) was found most suitable for callus induction and growth. The hormone free medium and medium supplemented with BAP, Kn, IAA, IBA, and NAA singly did not support the induction of callus. However, the BAP and Kn showed callus induction when added in combination with 2, 4-D (6.78 μm). Thus, the results show that the presence of 2, 4-D in the medium is necessary for callus induction from the petiole of Viola serpens Wall. Although the formation of active green callus and regeneration of multiple shoots were observed on MS+BAP (BAP; 6.66, 11.10, and15.53 μm) and (Kn; 6.97, 11.61, and 16.26 μm), media, the best growth response, and higher rate of shoot multiplication were observed on MS medium containing BAP (11.10 μm) as the average number of shoots could be increased to 36.4 on fourth successive subculturing and shoots attained 2.6 cm average height after 3-4 weeks of the growth period. Although root initiation was observed in shoots inoculated on both full-strength and half-strength MS medium supplemented with IAA and IBA, the half-strength MS medium supplemented with IBA (19.68 μm) was found better as there was higher rooting response with larger number of roots.
This efficient and simple protocol reported herein could be useful for rapid multiplication of this medicinally important plant.
| Acknowledgments|| |
The authors thank Central Council for Research in Ayurveda and Siddha, New Delhi, India, for providing working facilities and encouragement for the present work.
| References|| |
|1.||Hooker JD. The Flora of British India, Ranunculceae to Sapindaceae. Kent, England: L. Reeve and Co. Ltd; 1875. p. 134. |
|2.||Bal SN. Catalogue of Medicinal Plant Exhibits. The Industrial Section of the Indian Museum. Calcutta: Botanical Survey of India, Govt. of India, Central Publication Branch; 1932. p. 118-9. |
|3.||Dhar U, Kachroo P. Alpine Flora of Kashmir Himalaya. Jodhpur, India: Scientific Publishers; 1983. p. 86-7. |
|4.||Santapau H, Henrry AN. A Dictionary of the Flowering Plants in India. New Delhi: Publication and Information Directorate, CSIR; 1973. p. 82. |
|5.||Gamble JS. Flora of the Presidency of Madras. Reprinted edition. Calcutta: Botanical Survey of India; 1967.p. 244. |
|6.||Collett H. Flora of Simlensis- A Hand Book of the Flowering Plants of Simla and the Neighbourhood, Third impression. Deharadun, India: Reprinted by M/S Bishen Singh Mahendrapal Singh; 1971. p. 133. |
|7.||Chawdhary HJ, Wadhawa BM. Flora of India, Series 2, Flora of Himachal Pradesh. Calcutta: Botanical Survey of India;, Dept. of Environment; 1984. p. 80. |
|8.||Sharma BD, Singh NP, Raghwan RS, Deshpande UR. Flora of India, Series 2, Flora of Karnataka. Calcutta: Analysis, Botanical Survey of India; 1984. p. 72. |
|9.||Nair NC, Henrry AN, Kumari CR, Chithra V. Flora of India, Seris 1, Analysis, Flora of Tamilnadu. Vol. 1. Southern Circle, Coimbtore: BSI, Dept. of Environment; 1983. p. 106. |
|10.||Kurup PN, Ramadas VN, Joshi P. Hand Book of Medicinal Plants. New Delhi: Central Council for Research in Ayurveda and Siddha; 1979. p. 188-9. |
|11.||Shastri AD. Bhaishajya Ratnavali of Govindadasa. Varanasi: Chawkhambha Sanskrit Sansthan; 2001. p. 858. |
|12.||Kirtikar KR, Basu BD. Indian Medicinal Plants. Second edition. India: Lalit Mohan Basu and Co; 1935. p. 758-60. |
|13.||Singh D. Unani Dravyagun Vigyan, Part-2. Lucknow: Ayuvedic and Tibbi Academy (U. P);1974. p. 491-2. |
|14.||Nadkarni KM. Nadkarni's Indian Materia Medica. Bombay: Popular Prakashan Pvt. Ltd; 1976. p. 1274-5. |
|15.||Chauhan NS. Medicinal and Aromatic Plants of Himachal Pradesh. New Delhi: Indus Publihing Company; 1999. p. 431-173. |
|16.||Rawat GS, Sharma AK. Strategies for the conservation of medicinal plants in the Himalayas. In Prospects of Medicinal Plants. New Delhi: Indian Society of Plant Genetic Resources; 1998. p. 29-36. |
|17.||Tadahiko S, Kwon OC, Miyake H, Taniguchi T, Maeda, E. Regeneration of Plantlets from petiole callus of wild Viola ( DC.). Plant Cell Rep1995;14:768-72. |
|18.||Bao MZ, Wang JX, Dorman JS, Trucco M. HLA-DQ beta non-ASP-57 allele and incidence of diabetes in China and the USA. Lancet1989;;2:497-8. |
|19.||Nancy LM, Jerzy N. Plant regeneration from hypocotyl and petiole callus of Trifolium pratense L. Plant Cell Rep1989;8:395-8. |
|20.||Jafari MA, Kiss J, Gergacz J, Heszky LE. High efficiency callus induction and plant regeneration in petiole culture of four poplar genotypes. Acta Biol Hung1995;46:51-9. |
|21.||Murashige T. Plant propagation through tissue cultures. Annual Review of Plant Physiology 1974;25:135-66. |
|22.||Razdan MK. An Introduction to Plant Tissue Culture. New Delhi: Oxford and IBH Publishing Co. Pvt. Ltd; 1993. p. 34. |
|23.||Banerjee S, Mehar Z, Kumar SS. In vitro multiplication of Centella asiatica, a medicinal herb from leaf explant. Curr Sci1999;76:147-8. |
|24.||Tiwari V, Singh BD, Tiwari KN. Shoot bud regeneration from different explants of Bacopa monniera (L.) Wettst. by trimethoprim and bavistin. Plant Cell Rep2006;25:629-35. |
|25.||Loh CS, Rao AN. Clonal propagation of guava (Psidum guajava L.) from seedlings and grafted plants and adventitious shoot formation in vitro. Scientia Horticulture1989;39:31-9. |
|26.||Bhat SR, Chandel KP, Malik SK. Plant regeneration from various explants of cultivated Piper species. Plant Cell Rep 1995;14:398-402. |
|27.||Maggon R, Singh BD. Promotion of adventitious bud regeneration by ABA in combination with BAP in epicotyl and hypocotyl explants of sweet orange (Citrus sinensis L. Osbeck). Scientia Horticulture1995;63:123-8. |
|28.||Balachandran SM, Bhat SR, Chandel, KP. In vitro clonal multiplication of turmeric (Curcuma spp.) and ginger (Zingiber officinale Rosc.). Plant Cell Rep 1990;8:521-4. |
|29.||Vishwakarma UR, Gurav AM, Sharma PC. In vitro propagation of Desmodium gangeticum (L.) DC. From cotyledonary nodal explants. Pharmacogn Mag 2009;5:145-50. |
|30.||Venkatachalam P, Geetha N, Rao KS, Jayabalan N, Sarvanababu S. BAP-regulated direct shoot organogenesis from cultured seedling explants of ground nut (Arachis hypogea L.). Indian J Exp Biol 1999;37:807-12. |
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6], [Figure 7], [Figure 8]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]