Research Article

Split Viewer

J Plant Biotechnol 2021; 48(3): 173-178

Published online September 30, 2021

https://doi.org/10.5010/JPB.2021.48.3.173

© The Korean Society of Plant Biotechnology

Silver nitrate and silver-thiosulphate mitigates callus and leaf abscission during Shisham clonal micro-propagation

Manoj Kumar Raturi ・Ajay Thakur

Genetics and Tree Improvement Forest Research Institute, PO: New Forest Dehradun, India 248006
Head and Scientist F, Genetics and Tree Improvement Forest Research Institute, PO: New Forest Dehradun, India 248006

Correspondence to : e-mail: thakura@icfre.org

Received: 13 September 2021; Revised: 22 September 2021; Accepted: 22 September 2021

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Basal callus formation and leaf abscission is a problem in clonal micropropagation. We have described an in vitro clonal propagation protocol of Dalbergia sissoo Roxb (shisham) ‘FRI-14’ in which AgNO3 played important role not only in mitigating problem of leaf abscission and basal callus, but also improved shoot induction and multiplication. Best induction and shoot multiplication was obtained on MS media with 1.5 mg/l 6-BAP and 10 mg/l AgNO3 and half-strength MS media with 0.5 mg/l 6-BAP, 2 mg/l AgNO3 and 50 mg/l Adenine sulphate whereas best ex vitro rooting was obtained with 200 mg/l IBA in pulse treatment.

Keywords Clonal propagation, Ethylene inhibitors, Tissue-culture, Tahli, Shisham, Callus

Dalbergia sissoo is a fast growing, nitrogen fixing, multipurpose timber yielding tree species which belongs to family Fabaceae. This perennial tree is indigenous to India, Bangladesh, Pakistan, Nepal and Afghanistan can thrive in diverse range of soil types, elevations, climate and pHlevels (Majeed et al. 2019; Orwa et al. 2009). This is pioneer tree of primary serale so excellent for land restoration and afforestation programs (Tiwari 1994). Though it is largely being grown in agroforestry, lately the genus Dalbergia declared endangered by IUCN (Chauhan et al. 2021). Moreover, it is a known indigenous therapeutic plant as it contains many bioactive compounds such as isoflavones, coumarins, flavones, and quinines, dalbergin etc. (Majeed et al. 2019). A clonal highly productive and disease resistant variety of this species FRI 14 has been released for cultivation under farm and agroforestry system in northern India (Chauhan et al. 2021). Clonal varieties are propagated through either macro or micro propagation. Micro propagation has some distinct advantages over other conventional method of vegetative propagation as it has the potential to grow thousands of infection free plants of desirable genetic material, also maintain vigour by producing virus free plants through apical meristem (Shahzad et al. 2017). There are many reports of micropropagation of D. sissoo by using explants derived from seedlings (Chand and Singh 2004, 2005; Das et al. 1997; Pattnaik et al. 2000; Singh and Chand 2003) and mature explants (Datta and Datta 1983; Joshi et al. 2003; Thirunavoukkarasu et al. 2010; Vibha et al. 2014).

The most important challenges reported in the micropropagation of D. sissoo are basal callus formation, leaf fall, shoot tip necrosis (Datta and Datta 1983; Joshi et al. 2003; Thirunavoukkarasu et al. 2010; Vibha et al. 2014). Often, premature leaf fall, reduced growth and developmenthave been associated with excess amount of ethylene produced in in vitro culture vessels. Callus can be a spoilsport, as regeneration through this pathway may produce genetically dissimilar plantlets instead of clones due to somaclonal variation (Bairu et al. 2011; Currais et al. 2013). Chemical compounds like AgNO3 are known to block the action of ethylene, consequently promote the growth of plant cultures and reduce the leaffall in shoots (Lemos and Jennet 2015; Ravi et al. 2019). Moreover, AgNO3 hastens in vitro callus formation.

This study was an attempt to develop a complete micropropagation protocol for an elite variety of D. sissoo ‘FRI 14’ alongwith mitigating problem of premature leaf fall, shoot tip necrosis and basal callus formation using ethylene inhibitors like AgNO3 and silver thiosulphate during clonal micropropagation.

The clonal variety of ‘FRI 14’ is being grown in a vegetative multiplication garden of D. sissooand branches from rejuvenated shoots were collected as explant in the month of March to Junefor in vitro propagation. Nodal segments were wiped with 70% alcohol followed by soaking of nodal cutting in aqueous solution of Citramide® (3~4 ml in 100 ml distilled water) for 15 minutes. Nodal segments were washed thoroughly with sterile distilled water followed by treatment with a fungicide 0.2% Nativo® for another 15 minutes. Finally, explants were surface sterilized with 0.1% mercuric chloride (HgCl2) for 8~10 minutes in aseptic condition and washed thoroughly with sterile water to remove traces of mercuric chloride.

Axillary bud induction

Sterilized nodal segments were cultured on MS (Murashige and Skoog 1962) media supplemented with different concentration and combination of 6-Benzylaminopurine (BAP), Kin (Kinetin), AgNO3 and silver thiosulphate (STS). Prior to adding 7 % (w/v) agar, the pH was adjusted to 5.6 with the help of a pH meter. Equal amount of media prepared was aliquoted into glass tubes (25×150 mm) and autoclaved for 15 minutes. Cultures were maintained at a uniform condition throughout experiments with 26°C temperature and 50 μ mol m-2 s -1 photosynthetic photon flux density (PPFD) and photoperiod of 16/8 (light/dark).

Shoot multiplication

In vitro raised shoots were sub-cultured on MS media augmented with different concentrations and combinations of 6-Benzylaminopurine (BAP), Ads (adinine sulphate) and AgNO3 (silver nitrate). MS Media without any plant growth regulators was considered as control. Cultures were repeatedly transferred on fresh media with same combination of plant growth regulators after every two weeks. After six weeks of subculturing, data in terms of shoot length (in cm), shoot number (≥ 0.5 cm) and leaf fall percentage was recorded.

Ex vitro rooting

Healthy in vitro grown microshoots (3~4 cm) were trimmed at their basal end and washed with sterile water in septic condition. Microshoots were pulse treated with different concentrations of NAA (100~300 mg/l) and IBA (100~300 mg/l). The shoots treated with auxins for root induction were transferred into jam bottles containing autoclaved vermiculite. Thereafter, properly caped jam bottles were placed inmost humid section of green house. Once rooting initiated, the caps of the bottles were loosened to reduce the humidity and were moved near fan section. Finally, the plantlets were planted on a mixture containing equal amount of soil and sand. Root length and root number were calculated after four weeks.

Statistical analysis

Experiment conducted were set up in a completely randomized design (CRD). Each experiment had nine replicates. Shoot number, shoot length, leaf fall, root number and root length calculated were analysed statistically. The analysis of variance (ANOVA) was determined by using SPSS. Tukey’s HSD test was used for post hoc and mean were compared at p ≤ 0.05.

Effect of different combination of hormones on in vitro bud induction is shown (Table 1). Shoot bud initiation was observed in all media combinations. However, of both the cytokinins (6-BAP and Kin) tested, 6-BAP was found more effective than Kin. Our results are in conformity with earlier report on the micropropagation of D. sissoo (Vibha et al. 2014). BAP is a synthetic cytokinin which helps in inducing bud break, help in axillary shoot development and shoot multiplication (Sadeghi et al. 2015). The best response was noted in MS media fortified with 1.5 mg/l BAP and 10 mg/l AgNO3 (Fig. 1b) with maximum shoot number (2.6) and shoot length (4.4 cm) followed by MS media containing 1.5 mg/l BAP and 15 mg/l AgNO3. However, the further increase in the concentration of BAP resulted in basal callus formation and reduction in the overall development of shoots (Fig 1c). Similar observations were reported in Moringa oleifera (Ravi et al. 2019; Riyathong et al. 2010).

Table 1 Effect of different cytokinin (BAP & Kin) and different additives (Silver nitrate and Silver thiosulphate on axillary bud induction and shoot growth of D. sissoo

BAP (mg/l)Kin (mg/l)AgNO3 (mg/l)STS (mg/l)Shoot No. (± SD)Shoot Length (± SD) (cm)
000000
0.51.5±0.74de2.5±0.37e
1.52.0±0.38bcd3.3±0.27d
2.51.5±0.52de1.4±0.52g
1.552.4±0.74ab3.9±0.38bc
1.5102.6±0.83a4.4±0.41a
1.5152.4±0.63ab4.1±0.55ab
1.551.7±0.70cde3.9±0.36bc
1.5102.2±0.56abc3.8±0.62c
1.5151.9±0.35cde2.5±0.35e
0.51.4±0.51e1.7±0.33fg
1.51.9±0.70bcd2.0±0.38f
2.51.9±0.70bcd1.9±0.61f

Where Kin = Kinetin, STS = Silver thiosulphate

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test


Fig. 1. Micropropagation of D. sissoo. (a) Shoot bud induction on media supplemented with 1.5 mg/L BAP (bShoot bud induction on media supplemented with 1.5 mg/L BAP and 10 mg/L AgNO3. (c) leaf fall in 2.5 mg/L BAP. (d) Shoot multiplication on ½ MS media supplemented with 0.5 mg/L BAP + 2 mg/L AgNO3 + 50 mg/L Ads (e) Shoot cultured in Vermiculite for root induction (f) ex vitro rooting on ½ strength MS supplemented with 0.5 mg/L IBA (g) Plantlets transferred in pots

Both AgNO3 and STS showed a synergetic effect with BAP on the recorded parameters. Growth of in vitro cultures is often inhibited by excess amount of accumulated ethylene which leads to leaf fall (Burg 1968; Kao and Yang 1983), cultures deterioration and browning of medium and explants. AgNO3 is known to restrict the effect of ethylene hormone on plant. In this study, addition of 10 mg/l AgNO3 had a significant effect on shoot number and shoot length. It was also observed that the leaf fall, basal callus formation and necrosis of shoot tips reduced drastically in shoots treated with AgNO3. Hassanein et al. (2018) reported that the shoot multiplication of M. oleifera was improved by addition of AgNO3 in the culture media. Similar results have been observed in other species such as pomegranate (Naik and Chand 2003), black gram (Mookkan and Andy 2014), banana (Tamimi 2015), sunflower (Mirzai et al. 2015) and cherry (Sarropoulou et al. 2016).

Shoot multiplication

In vitro grown shoots were transferred repeatedly on fresh half strength MS media with different concentration of BAP, AgNO3 and adenine sulphate (Ads). The maximum number of shoots was observed after fourth passage of subculturing. Of all the media combinations used, the best result was noted on half strength MS Media supplemented with 0.5 mg/l BAP, 2 mg/l AgNO3 and 50 mg/l Ads. Maximum number of shoots (10.7) was recorded on this media combination. Ads was added to multiplication media as adinine in Ads is known to induce cell growth and shoot bud formation (Ahmad et al. 2018). For shoot multiplication, half strength MS media was found superior to full strength MS media. There was an increase in both the number of shoots and shoot length with the addition of AgNO3. Moreover, it was observed that AgNO3 reduced the premature leaf fall of in vitro grown shoot cultures (Table 2, Fig. 1d). In cultures of Annona squamosa, silver nitrate was found to be an effective inhibitor of abscission of leaves (Lemos and Jennet 2015). Similarly, silver nitrate is reported to block the action of ethylene which stimulates the leaf abscission in cotton species (Beyer 1975; 1976a; 1976b; 1979). Ravi et al. (2019) noticed that application of silver nitrate (2.5 µM) reduced the leaf fall (20.6%) significantly in cultures of M. oleifera.

Table 2 Effect of different concentrations of plant growth regulators and additives (BAP, Ads and AgNO3) on multiplication of shoots of D. sissoo

Media combinationsShoot length (cm) (± SD)Shoot number (± SD)Leaf fall (%) (± SD)
0000
0.5 BAP mg/l (MS) + 50 mg/l Ads4.5±0.23d5.7±0.46c37.64±1.57bc
0.25 mg/l BAP (1/2 MS) + 50 mg/l Ads5.0±0.30c7.6±0.64b35.65±0.76c
0.5 mg/l BAP (1/2 MS) + 50 mg/l Ads4.1±0.45e4.8±0.70cd39.10±1.33b
1 mg/l BAP (1/2 MS) + 50 mg/l Ads3.8±0.40e3.9±1.03d41.26±1.46a
0.25 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads5.5±0.50b7.8±0.46b28.75±0.98e
0.5 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.0±0.54a10.7±0.64a30.57±2.05de
1 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.1±0.34a7.8±0.91b32.07±1.39d

Where, Ads = Adenine sulphate

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test



Ex vitro rooting

Effect of different concentrations of different auxins on ex vitro root initiation in shoots of Dalbergia sissoo is shown in Table 3. Ex vitro rooting helps in reducing cost, rooting time and acclimatization during micropropagation of plants and therefore it is a very effective method of inducing rooting in vitro cultures (Phulwaria et al. 2012b; Yan et al. 2010).

Table 3 Effect of different concentrations of auxins (IBA, NAA) on Ex vitro rooting initiation for in vitro raised shoots

IBA (mg/l)NAA (mg/l)Root Number (± SD)Root Length (cm) (± SD)
0000
1004.56±0.527a4.1±0.10b
2004.89±0.782a5.1±0.25a
3004.67±0.866a3.8±0.16c
1001.67±0.500c2.1±0.31e
2003.00±0.500b2.4±0.27d
3002.22±0.833c2.3±0.20d

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test



Furthermore, ex vitro differentiated roots are more adapted to the anchoring medium. The shoots multiplied and established in vitro conditions were treated with auxins (IBA and NAA) of different concentration for root induction. The effect of different rooting hormones in terms of root length and root number were analysed after four weeks of treatment. IBA was found better than NAA for rooting of cultured shoots. Earlier studies on in vitro propagation of D sissoo also suggest that IBA is superior rooting hormone than other hormones tested (Thirunavoukkarasu et al. 2010; Vibha et al. 2014). IBA in woody species, has been reported to stimulate strong rooting response (Eeswara et al. 1998; Husain et al. 2008). The best result was observed with 200 mg/l IBA which produced an average of 4.89 roots per shoot which was significantly higher than NAA treated shoots (Fig. 1e and 1f). However, there was no significant difference in the number of roots between different concentration of IBA. The lowest number of roots (2.2) was found in 1 mg/l NAA treated shoots. It was observed that the lateral roots developed were without callus formation at the basal ends of in vitro raised shoots, which is another advantage of ex vitro rooting over in vitro rooting.

In summary, an efficient protocol was developed for direct organogenesis and multiplication of an elite germplasm of D. sissoo. Best result for axillary bud induction and shoot development was observed on MS media containing 1.5 mg/L BAP and 10 mg/l AgNO3. Different media combinations were used for multiplication of in vitro raised shoots and the maximum number of shoots (10.7) were noted in MS media supplemented with 0.5 mg/l BAP, 2 mg/l AgNO3 and 50 mg/l Ads. Further, the shoots obtained after four weeks of subculturing, shoots obtained were pulse treated with different auxins (NAA, IBA) for ex vitro root induction. Finally, the rooted shoots were transferred in pots for the hardening of the plantlets. Results of present study also suggest that addition of AgNO3 not only played a positive role in growth and maintenance of shoots but also helped in reduction of premature leaf fall. The protocol is suitable for commercial production of D. sissoo variety ‘FRI-14’.

Author MR acknowledges the support of University Grant Commission (UGC), New Delhi for the award of Junior Research Fellowship (JRF) and facilities provided by Forest Research Institute (Deemed to be University).

MR and AT has jointly conceptualized the study, AT guided and facilitated the study and MR executed research work, MR and AT has jointly analysed data and written manuscripts.

Authors declare that this manuscript has not be submitted fully or partially anywhere.

  1. Ahmad Z, Shahzad A, Sharma S, Parveen S (2018) Ex vitro rescue, physiochemical evaluation, secondary metabolite production and assessment of genetic stability using DNA based molecular markers in regenerated plants of Decalepis salicifolia (Bedd. ex Hook. f.) Venter. Plant Cell Tissue Organ Cult 132: 497-510
    CrossRef
  2. Bairu MW, Aremu AO, Staden JV (2011) Somaclonal variation in plants: causes and detection methods. Plant Growth Regul 63: 147-173
    CrossRef
  3. Beyer EM (1975) Abscission: the initial effect of ethylene is in the leaf blade. Plant Physiol 55: 322-327
    Pubmed KoreaMed CrossRef
  4. Beyer EM (1976a) A potent inhibitor of ethylene action in plants. Plant Physiol 58: 268-271
    Pubmed KoreaMed CrossRef
  5. Beyer EM (1976b) Silver ion: a potent anti-ethylene agent in cucumber and tomato. HortScience 11: 175-196. Beyer EM (1979) [14C] Ethylene metabolism during leaf abscission in cotton. Plant Physiol 64:971-974. https://doi.org/10.1104/pp.64.6.971
  6. Burg SP (1968) Ethylene, plant senescence and abscission. Plant Physiol 43: 1503-1511
    Pubmed KoreaMed CrossRef
  7. Chand S, Singh AK (2004) Plant regeneration from encapsulated nodal segments of Dalbergia sissoo Roxb., a timber-yielding leguminous tree species. J Plant Physiol 161: 237-243
    Pubmed CrossRef
  8. Chand S, Singh AK (2005) Plant regeneration from semi-mature zygotic embryos of Dalbergia sissoo Roxb. Indian J Biotech 4: 78-81
  9. Chauhan M., Thakur A., Singh YSingh Y et al (2021) Gnotobiotic evaluation of Dalbergia sissoo genotypes for resistance against Fusarium solani via dual culture set up. In: J Genet Eng Biotechnol, pp 35. https://doi.org/10.1186/s43141-021-00132-3
    Pubmed KoreaMed CrossRef
  10. Currais L, Loureiro J, Santos C, Canhoto JM (2013) Ploidy stability in embryogenic cultures and regenerated plantlets of tamarillo. Plant Cell Tissue Organ Cult 114: 149-159
    CrossRef
  11. Das P, Samantaray S, Roberts AV, Rout GR (1997) In vitro somatic embryogenesis of Dalbergia sissoo Roxb.-a multipurpose timber yielding tree. Plant Cell Rep 16: 578-582
    Pubmed CrossRef
  12. Datta SK, Datta K (1983) Auxin induced regeneration of forest treesDalbergia sissoo Roxb. through tissue culture. Curr Sci 52: 435-436
  13. Drisya Ravi R. S., Siril E. A., Nair B. R. (2019) The effect of silver nitrate on micropropagation of Moringa oleifera Lam. an important vegetable crop of tropics with substantial nutritional value. In: Physiology and Molecular Biology of Plants, pp 1311-1322. https://doi.org/10.1007/s12298-019-00689-x
    Pubmed KoreaMed CrossRef
  14. Eeswara JP, Stuchbury T, Allan EJ, Mordue AJ (1998) A standard procedure for the micropropagation of the Neem tree (Azadirachta indica A. Juss). Plant Cell Rep 17: 215-219
    Pubmed CrossRef
  15. Hassanein AM, Salem JM, Faheed FA, El-Nagish A (2018) Effect of anti-ethylene compounds on isoenzyme patterns and genome stability during long term culture of Moringa oleifera. Plant Cell Tissue Organ Cult 132: 201-212. https://doi.org/10.1007/s11240-017-1326-0
    CrossRef
  16. Husain MK, Anis M, Shahzad A (2008) In vitro propagation of a multipurpose leguminous tree (Pterocarpus marsupium Roxb.) using nodal explants. Acta Physiol Plant 30: 353-359
    CrossRef
  17. Joshi I, Bisht P, Sharma VK, Uniyal DP (2003) Studies on effect of nutrient media for clonal propagation of superior phenotypes of Dalbergia sissoo Roxb. through tissue culture. Silvae Genet 52: 143-147
  18. Kao CH, Yang SF (1983) Role of ethylene in the senescence of detached rice leaves. Plant Physiol 73: 881-885
    Pubmed KoreaMed CrossRef
  19. Lemos EEP, Jennet B (2015) Control of leaf abscission in nodal cultures of Annona squamosa L. J Hortic Sci Biotechnol 71: 721-728
    CrossRef
  20. Majeed F. A, Munir H, Rashid R, Zubair M. T. (2019) Antimicrobial, cytotoxicity, mutagenicity and anti-epileptic potential of ethanol extracts of a multipurpose medicinal plant Dalbergia sissoo. Biocatalysis and Agricultural Biotechnology 19: 101155. https://doi.org/10.1016/j.bcab.2019.101155
    CrossRef
  21. Mirzai F, Uliaie ED, Hagh AB (2015) Stimulation effect of AgNO3 and CoCl2 as ethylene inhibitors on in vitro organogenesis of sunflower (Helianthus annuus L.). J Agric Sci 25: 113-118
    CrossRef
  22. Mookkan M, Andy G (2014) AgNO3 boosted high-frequency shoot regeneration in Vigna mungo (L.) Hepper. Plant Signal Behav 9(10): 1-5. https://doi.org/10.4161/psb.32165
    Pubmed KoreaMed CrossRef
  23. Skoog F, Skoog F; Murashige T. (1962) A Revised Medium for Rapid Growth and Bio Assays with Tobacco Tissue Cultures. Plant Physiology 15: 473-497
    CrossRef
  24. Naik SK, Chand PK (2003) Silver nitrate and aminoethoxyvinylglycine promote in vitro adventitious shoot regeneration of pomegranate (Punica granatum L.). J Plant Physiol 160: 423-430
    Pubmed CrossRef
  25. Orwa C, Mutua A, Kindt R, Jamnadass R, Anthony S (2009). Agroforestree Database: A tree reference and selection guide version 4.0. Available online: http://www.worldagroforestry.org. accessed on 7 December 2018
  26. Pattnaik S, Pradhan C, Naik SK, Chand PK (2000) Shoot organogenesis and plantlet regeneration from hypocotyl-derived cell suspensions of a tree legume Dalbergia sissoo. In vitro. Cell Dev Biol - Plant 36: 407-411
    CrossRef
  27. Phulwaria M, Ram K, Harish, Gupta AK, Shekhawat NS (2012b) Micropropagation of mature Terminalia catappa (Indian almond)- a medicinally important forest tree. J Forest Res 17: 202-207
    CrossRef
  28. Pua EC, Chi GL (1993) De novo shoot morphogenesis and plant growth of mustard (Brassica juncea) in vitro in relation to ethylene. Physiol Plant 88: 467-474
    CrossRef
  29. Riyathong T, Dheeranupattana S, Palee J, Shank L (2010) Shoot multiplication and plant regeneration from in vitro cultures of drumstick tree (Moringa oleifera Lam.). In: The 8th international symposium on biocontrol and biotechnology. King Mongkut’s Institute of Technology Ladkrabang and Khon Kaen University, Nongkhai Campus, Thailand, pp 99-104
  30. Sarropoulou V, Dimassi-Theriou K, Therios I (2016) Effect of the ethylene inhibitors silver nitrate, silver sulfate, and cobalt chloride on micropropagation and biochemical parameters in the cherry rootstocks CAB-6P and Gisela 6. Turk J Biol 40: 670-683. https://doi.org/10.3906/biy-1505-92
    CrossRef
  31. Shahzad AShahzad A et al (2017) Plant Tissue Culture: Applications in Plant Improvement and Conservation. In: In Plant Biotechnology: Principles and Applications. Springer Singapore, pp 37-72
    CrossRef
  32. Singh AK, Chand S (2003) Somatic embryogenesis and efficient plant regeneration from cotyledon explants of a timber yielding legumi nous tree Dalbergia sissoo Roxb. J Plant Physiol 160: 415-421
    Pubmed CrossRef
  33. Tamimi SM (2015) Effects of ethylene inhibitors, silver nitrate (AgNO3), cobalt chloride (CoCl2) and aminooxy acetic acid (AOA), on in vitro shoot induction and rooting of banana (Musa acuminata L.). Afr J Biotechnol 14: 2511-2516. https://doi.org/10.5897/AJB2015.14788
    CrossRef
  34. Tewari D.N (1994). A Monograph on Dalbergia sissoo Roxb. International Book Distributors, Dehra Dun, India
  35. Thirunavoukkarasu M, Panda PK, Nayak P, Behera PR, Satpathy GB (2010) Effect of media type and explant source on micropropagation of Dalbergia sissoo Roxb. - an important multipurpose forest tree. In: Int Res J Plant Sci, pp 1155-1162
  36. Vibha J. B., Shekhawat N. S., Mehandru P., Dinesh R (2014) Rapid multiplication of Dalbergia sissoo Roxb.: A timber yielding tree legume through axillary shoot proliferation and Ex vitro rooting. In: Physiology and Molecular Biology of Plants, pp 81-87. https://doi.org/10.1007/s12298-013-0213-3
    Pubmed KoreaMed CrossRef
  37. Yan H, Liang C, Yang L, Li Y (2010) In vitro and Ex vitro rooting of Siratia grosvenori a traditional medicine plant. Acta Physiol Plant 32: 115-120
    CrossRef

Article

Research Article

J Plant Biotechnol 2021; 48(3): 173-178

Published online September 30, 2021 https://doi.org/10.5010/JPB.2021.48.3.173

Copyright © The Korean Society of Plant Biotechnology.

Silver nitrate and silver-thiosulphate mitigates callus and leaf abscission during Shisham clonal micro-propagation

Manoj Kumar Raturi ・Ajay Thakur

Genetics and Tree Improvement Forest Research Institute, PO: New Forest Dehradun, India 248006
Head and Scientist F, Genetics and Tree Improvement Forest Research Institute, PO: New Forest Dehradun, India 248006

Correspondence to:e-mail: thakura@icfre.org

Received: 13 September 2021; Revised: 22 September 2021; Accepted: 22 September 2021

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Basal callus formation and leaf abscission is a problem in clonal micropropagation. We have described an in vitro clonal propagation protocol of Dalbergia sissoo Roxb (shisham) ‘FRI-14’ in which AgNO3 played important role not only in mitigating problem of leaf abscission and basal callus, but also improved shoot induction and multiplication. Best induction and shoot multiplication was obtained on MS media with 1.5 mg/l 6-BAP and 10 mg/l AgNO3 and half-strength MS media with 0.5 mg/l 6-BAP, 2 mg/l AgNO3 and 50 mg/l Adenine sulphate whereas best ex vitro rooting was obtained with 200 mg/l IBA in pulse treatment.

Keywords: Clonal propagation, Ethylene inhibitors, Tissue-culture, Tahli, Shisham, Callus

Introduction

Dalbergia sissoo is a fast growing, nitrogen fixing, multipurpose timber yielding tree species which belongs to family Fabaceae. This perennial tree is indigenous to India, Bangladesh, Pakistan, Nepal and Afghanistan can thrive in diverse range of soil types, elevations, climate and pHlevels (Majeed et al. 2019; Orwa et al. 2009). This is pioneer tree of primary serale so excellent for land restoration and afforestation programs (Tiwari 1994). Though it is largely being grown in agroforestry, lately the genus Dalbergia declared endangered by IUCN (Chauhan et al. 2021). Moreover, it is a known indigenous therapeutic plant as it contains many bioactive compounds such as isoflavones, coumarins, flavones, and quinines, dalbergin etc. (Majeed et al. 2019). A clonal highly productive and disease resistant variety of this species FRI 14 has been released for cultivation under farm and agroforestry system in northern India (Chauhan et al. 2021). Clonal varieties are propagated through either macro or micro propagation. Micro propagation has some distinct advantages over other conventional method of vegetative propagation as it has the potential to grow thousands of infection free plants of desirable genetic material, also maintain vigour by producing virus free plants through apical meristem (Shahzad et al. 2017). There are many reports of micropropagation of D. sissoo by using explants derived from seedlings (Chand and Singh 2004, 2005; Das et al. 1997; Pattnaik et al. 2000; Singh and Chand 2003) and mature explants (Datta and Datta 1983; Joshi et al. 2003; Thirunavoukkarasu et al. 2010; Vibha et al. 2014).

The most important challenges reported in the micropropagation of D. sissoo are basal callus formation, leaf fall, shoot tip necrosis (Datta and Datta 1983; Joshi et al. 2003; Thirunavoukkarasu et al. 2010; Vibha et al. 2014). Often, premature leaf fall, reduced growth and developmenthave been associated with excess amount of ethylene produced in in vitro culture vessels. Callus can be a spoilsport, as regeneration through this pathway may produce genetically dissimilar plantlets instead of clones due to somaclonal variation (Bairu et al. 2011; Currais et al. 2013). Chemical compounds like AgNO3 are known to block the action of ethylene, consequently promote the growth of plant cultures and reduce the leaffall in shoots (Lemos and Jennet 2015; Ravi et al. 2019). Moreover, AgNO3 hastens in vitro callus formation.

This study was an attempt to develop a complete micropropagation protocol for an elite variety of D. sissoo ‘FRI 14’ alongwith mitigating problem of premature leaf fall, shoot tip necrosis and basal callus formation using ethylene inhibitors like AgNO3 and silver thiosulphate during clonal micropropagation.

Material and Methods

The clonal variety of ‘FRI 14’ is being grown in a vegetative multiplication garden of D. sissooand branches from rejuvenated shoots were collected as explant in the month of March to Junefor in vitro propagation. Nodal segments were wiped with 70% alcohol followed by soaking of nodal cutting in aqueous solution of Citramide® (3~4 ml in 100 ml distilled water) for 15 minutes. Nodal segments were washed thoroughly with sterile distilled water followed by treatment with a fungicide 0.2% Nativo® for another 15 minutes. Finally, explants were surface sterilized with 0.1% mercuric chloride (HgCl2) for 8~10 minutes in aseptic condition and washed thoroughly with sterile water to remove traces of mercuric chloride.

Axillary bud induction

Sterilized nodal segments were cultured on MS (Murashige and Skoog 1962) media supplemented with different concentration and combination of 6-Benzylaminopurine (BAP), Kin (Kinetin), AgNO3 and silver thiosulphate (STS). Prior to adding 7 % (w/v) agar, the pH was adjusted to 5.6 with the help of a pH meter. Equal amount of media prepared was aliquoted into glass tubes (25×150 mm) and autoclaved for 15 minutes. Cultures were maintained at a uniform condition throughout experiments with 26°C temperature and 50 μ mol m-2 s -1 photosynthetic photon flux density (PPFD) and photoperiod of 16/8 (light/dark).

Shoot multiplication

In vitro raised shoots were sub-cultured on MS media augmented with different concentrations and combinations of 6-Benzylaminopurine (BAP), Ads (adinine sulphate) and AgNO3 (silver nitrate). MS Media without any plant growth regulators was considered as control. Cultures were repeatedly transferred on fresh media with same combination of plant growth regulators after every two weeks. After six weeks of subculturing, data in terms of shoot length (in cm), shoot number (≥ 0.5 cm) and leaf fall percentage was recorded.

Ex vitro rooting

Healthy in vitro grown microshoots (3~4 cm) were trimmed at their basal end and washed with sterile water in septic condition. Microshoots were pulse treated with different concentrations of NAA (100~300 mg/l) and IBA (100~300 mg/l). The shoots treated with auxins for root induction were transferred into jam bottles containing autoclaved vermiculite. Thereafter, properly caped jam bottles were placed inmost humid section of green house. Once rooting initiated, the caps of the bottles were loosened to reduce the humidity and were moved near fan section. Finally, the plantlets were planted on a mixture containing equal amount of soil and sand. Root length and root number were calculated after four weeks.

Statistical analysis

Experiment conducted were set up in a completely randomized design (CRD). Each experiment had nine replicates. Shoot number, shoot length, leaf fall, root number and root length calculated were analysed statistically. The analysis of variance (ANOVA) was determined by using SPSS. Tukey’s HSD test was used for post hoc and mean were compared at p ≤ 0.05.

Result and Discussion

Effect of different combination of hormones on in vitro bud induction is shown (Table 1). Shoot bud initiation was observed in all media combinations. However, of both the cytokinins (6-BAP and Kin) tested, 6-BAP was found more effective than Kin. Our results are in conformity with earlier report on the micropropagation of D. sissoo (Vibha et al. 2014). BAP is a synthetic cytokinin which helps in inducing bud break, help in axillary shoot development and shoot multiplication (Sadeghi et al. 2015). The best response was noted in MS media fortified with 1.5 mg/l BAP and 10 mg/l AgNO3 (Fig. 1b) with maximum shoot number (2.6) and shoot length (4.4 cm) followed by MS media containing 1.5 mg/l BAP and 15 mg/l AgNO3. However, the further increase in the concentration of BAP resulted in basal callus formation and reduction in the overall development of shoots (Fig 1c). Similar observations were reported in Moringa oleifera (Ravi et al. 2019; Riyathong et al. 2010).

Table 1 . Effect of different cytokinin (BAP & Kin) and different additives (Silver nitrate and Silver thiosulphate on axillary bud induction and shoot growth of D. sissoo.

BAP (mg/l)Kin (mg/l)AgNO3 (mg/l)STS (mg/l)Shoot No. (± SD)Shoot Length (± SD) (cm)
000000
0.51.5±0.74de2.5±0.37e
1.52.0±0.38bcd3.3±0.27d
2.51.5±0.52de1.4±0.52g
1.552.4±0.74ab3.9±0.38bc
1.5102.6±0.83a4.4±0.41a
1.5152.4±0.63ab4.1±0.55ab
1.551.7±0.70cde3.9±0.36bc
1.5102.2±0.56abc3.8±0.62c
1.5151.9±0.35cde2.5±0.35e
0.51.4±0.51e1.7±0.33fg
1.51.9±0.70bcd2.0±0.38f
2.51.9±0.70bcd1.9±0.61f

Where Kin = Kinetin, STS = Silver thiosulphate.

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.


Figure 1. Micropropagation of D. sissoo. (a) Shoot bud induction on media supplemented with 1.5 mg/L BAP (bShoot bud induction on media supplemented with 1.5 mg/L BAP and 10 mg/L AgNO3. (c) leaf fall in 2.5 mg/L BAP. (d) Shoot multiplication on ½ MS media supplemented with 0.5 mg/L BAP + 2 mg/L AgNO3 + 50 mg/L Ads (e) Shoot cultured in Vermiculite for root induction (f) ex vitro rooting on ½ strength MS supplemented with 0.5 mg/L IBA (g) Plantlets transferred in pots

Both AgNO3 and STS showed a synergetic effect with BAP on the recorded parameters. Growth of in vitro cultures is often inhibited by excess amount of accumulated ethylene which leads to leaf fall (Burg 1968; Kao and Yang 1983), cultures deterioration and browning of medium and explants. AgNO3 is known to restrict the effect of ethylene hormone on plant. In this study, addition of 10 mg/l AgNO3 had a significant effect on shoot number and shoot length. It was also observed that the leaf fall, basal callus formation and necrosis of shoot tips reduced drastically in shoots treated with AgNO3. Hassanein et al. (2018) reported that the shoot multiplication of M. oleifera was improved by addition of AgNO3 in the culture media. Similar results have been observed in other species such as pomegranate (Naik and Chand 2003), black gram (Mookkan and Andy 2014), banana (Tamimi 2015), sunflower (Mirzai et al. 2015) and cherry (Sarropoulou et al. 2016).

Shoot multiplication

In vitro grown shoots were transferred repeatedly on fresh half strength MS media with different concentration of BAP, AgNO3 and adenine sulphate (Ads). The maximum number of shoots was observed after fourth passage of subculturing. Of all the media combinations used, the best result was noted on half strength MS Media supplemented with 0.5 mg/l BAP, 2 mg/l AgNO3 and 50 mg/l Ads. Maximum number of shoots (10.7) was recorded on this media combination. Ads was added to multiplication media as adinine in Ads is known to induce cell growth and shoot bud formation (Ahmad et al. 2018). For shoot multiplication, half strength MS media was found superior to full strength MS media. There was an increase in both the number of shoots and shoot length with the addition of AgNO3. Moreover, it was observed that AgNO3 reduced the premature leaf fall of in vitro grown shoot cultures (Table 2, Fig. 1d). In cultures of Annona squamosa, silver nitrate was found to be an effective inhibitor of abscission of leaves (Lemos and Jennet 2015). Similarly, silver nitrate is reported to block the action of ethylene which stimulates the leaf abscission in cotton species (Beyer 1975; 1976a; 1976b; 1979). Ravi et al. (2019) noticed that application of silver nitrate (2.5 µM) reduced the leaf fall (20.6%) significantly in cultures of M. oleifera.

Table 2 . Effect of different concentrations of plant growth regulators and additives (BAP, Ads and AgNO3) on multiplication of shoots of D. sissoo.

Media combinationsShoot length (cm) (± SD)Shoot number (± SD)Leaf fall (%) (± SD)
0000
0.5 BAP mg/l (MS) + 50 mg/l Ads4.5±0.23d5.7±0.46c37.64±1.57bc
0.25 mg/l BAP (1/2 MS) + 50 mg/l Ads5.0±0.30c7.6±0.64b35.65±0.76c
0.5 mg/l BAP (1/2 MS) + 50 mg/l Ads4.1±0.45e4.8±0.70cd39.10±1.33b
1 mg/l BAP (1/2 MS) + 50 mg/l Ads3.8±0.40e3.9±1.03d41.26±1.46a
0.25 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads5.5±0.50b7.8±0.46b28.75±0.98e
0.5 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.0±0.54a10.7±0.64a30.57±2.05de
1 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.1±0.34a7.8±0.91b32.07±1.39d

Where, Ads = Adenine sulphate.

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.



Ex vitro rooting

Effect of different concentrations of different auxins on ex vitro root initiation in shoots of Dalbergia sissoo is shown in Table 3. Ex vitro rooting helps in reducing cost, rooting time and acclimatization during micropropagation of plants and therefore it is a very effective method of inducing rooting in vitro cultures (Phulwaria et al. 2012b; Yan et al. 2010).

Table 3 . Effect of different concentrations of auxins (IBA, NAA) on Ex vitro rooting initiation for in vitro raised shoots.

IBA (mg/l)NAA (mg/l)Root Number (± SD)Root Length (cm) (± SD)
0000
1004.56±0.527a4.1±0.10b
2004.89±0.782a5.1±0.25a
3004.67±0.866a3.8±0.16c
1001.67±0.500c2.1±0.31e
2003.00±0.500b2.4±0.27d
3002.22±0.833c2.3±0.20d

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.



Furthermore, ex vitro differentiated roots are more adapted to the anchoring medium. The shoots multiplied and established in vitro conditions were treated with auxins (IBA and NAA) of different concentration for root induction. The effect of different rooting hormones in terms of root length and root number were analysed after four weeks of treatment. IBA was found better than NAA for rooting of cultured shoots. Earlier studies on in vitro propagation of D sissoo also suggest that IBA is superior rooting hormone than other hormones tested (Thirunavoukkarasu et al. 2010; Vibha et al. 2014). IBA in woody species, has been reported to stimulate strong rooting response (Eeswara et al. 1998; Husain et al. 2008). The best result was observed with 200 mg/l IBA which produced an average of 4.89 roots per shoot which was significantly higher than NAA treated shoots (Fig. 1e and 1f). However, there was no significant difference in the number of roots between different concentration of IBA. The lowest number of roots (2.2) was found in 1 mg/l NAA treated shoots. It was observed that the lateral roots developed were without callus formation at the basal ends of in vitro raised shoots, which is another advantage of ex vitro rooting over in vitro rooting.

Conclusion

In summary, an efficient protocol was developed for direct organogenesis and multiplication of an elite germplasm of D. sissoo. Best result for axillary bud induction and shoot development was observed on MS media containing 1.5 mg/L BAP and 10 mg/l AgNO3. Different media combinations were used for multiplication of in vitro raised shoots and the maximum number of shoots (10.7) were noted in MS media supplemented with 0.5 mg/l BAP, 2 mg/l AgNO3 and 50 mg/l Ads. Further, the shoots obtained after four weeks of subculturing, shoots obtained were pulse treated with different auxins (NAA, IBA) for ex vitro root induction. Finally, the rooted shoots were transferred in pots for the hardening of the plantlets. Results of present study also suggest that addition of AgNO3 not only played a positive role in growth and maintenance of shoots but also helped in reduction of premature leaf fall. The protocol is suitable for commercial production of D. sissoo variety ‘FRI-14’.

Acknowledgement

Author MR acknowledges the support of University Grant Commission (UGC), New Delhi for the award of Junior Research Fellowship (JRF) and facilities provided by Forest Research Institute (Deemed to be University).

Contribution

MR and AT has jointly conceptualized the study, AT guided and facilitated the study and MR executed research work, MR and AT has jointly analysed data and written manuscripts.

Conflict of interest

Authors have no conflict of interest

Announcement for submission

Authors declare that this manuscript has not be submitted fully or partially anywhere.

Fig 1.

Figure 1.Micropropagation of D. sissoo. (a) Shoot bud induction on media supplemented with 1.5 mg/L BAP (bShoot bud induction on media supplemented with 1.5 mg/L BAP and 10 mg/L AgNO3. (c) leaf fall in 2.5 mg/L BAP. (d) Shoot multiplication on ½ MS media supplemented with 0.5 mg/L BAP + 2 mg/L AgNO3 + 50 mg/L Ads (e) Shoot cultured in Vermiculite for root induction (f) ex vitro rooting on ½ strength MS supplemented with 0.5 mg/L IBA (g) Plantlets transferred in pots
Journal of Plant Biotechnology 2021; 48: 173-178https://doi.org/10.5010/JPB.2021.48.3.173

Table 1 . Effect of different cytokinin (BAP & Kin) and different additives (Silver nitrate and Silver thiosulphate on axillary bud induction and shoot growth of D. sissoo.

BAP (mg/l)Kin (mg/l)AgNO3 (mg/l)STS (mg/l)Shoot No. (± SD)Shoot Length (± SD) (cm)
000000
0.51.5±0.74de2.5±0.37e
1.52.0±0.38bcd3.3±0.27d
2.51.5±0.52de1.4±0.52g
1.552.4±0.74ab3.9±0.38bc
1.5102.6±0.83a4.4±0.41a
1.5152.4±0.63ab4.1±0.55ab
1.551.7±0.70cde3.9±0.36bc
1.5102.2±0.56abc3.8±0.62c
1.5151.9±0.35cde2.5±0.35e
0.51.4±0.51e1.7±0.33fg
1.51.9±0.70bcd2.0±0.38f
2.51.9±0.70bcd1.9±0.61f

Where Kin = Kinetin, STS = Silver thiosulphate.

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.


Table 2 . Effect of different concentrations of plant growth regulators and additives (BAP, Ads and AgNO3) on multiplication of shoots of D. sissoo.

Media combinationsShoot length (cm) (± SD)Shoot number (± SD)Leaf fall (%) (± SD)
0000
0.5 BAP mg/l (MS) + 50 mg/l Ads4.5±0.23d5.7±0.46c37.64±1.57bc
0.25 mg/l BAP (1/2 MS) + 50 mg/l Ads5.0±0.30c7.6±0.64b35.65±0.76c
0.5 mg/l BAP (1/2 MS) + 50 mg/l Ads4.1±0.45e4.8±0.70cd39.10±1.33b
1 mg/l BAP (1/2 MS) + 50 mg/l Ads3.8±0.40e3.9±1.03d41.26±1.46a
0.25 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads5.5±0.50b7.8±0.46b28.75±0.98e
0.5 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.0±0.54a10.7±0.64a30.57±2.05de
1 mg/l BAP + 2 mg/l AgNO3 (1/2 MS) + 50 mg/l Ads6.1±0.34a7.8±0.91b32.07±1.39d

Where, Ads = Adenine sulphate.

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.


Table 3 . Effect of different concentrations of auxins (IBA, NAA) on Ex vitro rooting initiation for in vitro raised shoots.

IBA (mg/l)NAA (mg/l)Root Number (± SD)Root Length (cm) (± SD)
0000
1004.56±0.527a4.1±0.10b
2004.89±0.782a5.1±0.25a
3004.67±0.866a3.8±0.16c
1001.67±0.500c2.1±0.31e
2003.00±0.500b2.4±0.27d
3002.22±0.833c2.3±0.20d

Means followed by the same letter within columns are not significantly different (p < 5%) using Tukey’s HSD test.


References

  1. Ahmad Z, Shahzad A, Sharma S, Parveen S (2018) Ex vitro rescue, physiochemical evaluation, secondary metabolite production and assessment of genetic stability using DNA based molecular markers in regenerated plants of Decalepis salicifolia (Bedd. ex Hook. f.) Venter. Plant Cell Tissue Organ Cult 132: 497-510
    CrossRef
  2. Bairu MW, Aremu AO, Staden JV (2011) Somaclonal variation in plants: causes and detection methods. Plant Growth Regul 63: 147-173
    CrossRef
  3. Beyer EM (1975) Abscission: the initial effect of ethylene is in the leaf blade. Plant Physiol 55: 322-327
    Pubmed KoreaMed CrossRef
  4. Beyer EM (1976a) A potent inhibitor of ethylene action in plants. Plant Physiol 58: 268-271
    Pubmed KoreaMed CrossRef
  5. Beyer EM (1976b) Silver ion: a potent anti-ethylene agent in cucumber and tomato. HortScience 11: 175-196. Beyer EM (1979) [14C] Ethylene metabolism during leaf abscission in cotton. Plant Physiol 64:971-974. https://doi.org/10.1104/pp.64.6.971
  6. Burg SP (1968) Ethylene, plant senescence and abscission. Plant Physiol 43: 1503-1511
    Pubmed KoreaMed CrossRef
  7. Chand S, Singh AK (2004) Plant regeneration from encapsulated nodal segments of Dalbergia sissoo Roxb., a timber-yielding leguminous tree species. J Plant Physiol 161: 237-243
    Pubmed CrossRef
  8. Chand S, Singh AK (2005) Plant regeneration from semi-mature zygotic embryos of Dalbergia sissoo Roxb. Indian J Biotech 4: 78-81
  9. Chauhan M., Thakur A., Singh YSingh Y et al (2021) Gnotobiotic evaluation of Dalbergia sissoo genotypes for resistance against Fusarium solani via dual culture set up. In: J Genet Eng Biotechnol, pp 35. https://doi.org/10.1186/s43141-021-00132-3
    Pubmed KoreaMed CrossRef
  10. Currais L, Loureiro J, Santos C, Canhoto JM (2013) Ploidy stability in embryogenic cultures and regenerated plantlets of tamarillo. Plant Cell Tissue Organ Cult 114: 149-159
    CrossRef
  11. Das P, Samantaray S, Roberts AV, Rout GR (1997) In vitro somatic embryogenesis of Dalbergia sissoo Roxb.-a multipurpose timber yielding tree. Plant Cell Rep 16: 578-582
    Pubmed CrossRef
  12. Datta SK, Datta K (1983) Auxin induced regeneration of forest treesDalbergia sissoo Roxb. through tissue culture. Curr Sci 52: 435-436
  13. Drisya Ravi R. S., Siril E. A., Nair B. R. (2019) The effect of silver nitrate on micropropagation of Moringa oleifera Lam. an important vegetable crop of tropics with substantial nutritional value. In: Physiology and Molecular Biology of Plants, pp 1311-1322. https://doi.org/10.1007/s12298-019-00689-x
    Pubmed KoreaMed CrossRef
  14. Eeswara JP, Stuchbury T, Allan EJ, Mordue AJ (1998) A standard procedure for the micropropagation of the Neem tree (Azadirachta indica A. Juss). Plant Cell Rep 17: 215-219
    Pubmed CrossRef
  15. Hassanein AM, Salem JM, Faheed FA, El-Nagish A (2018) Effect of anti-ethylene compounds on isoenzyme patterns and genome stability during long term culture of Moringa oleifera. Plant Cell Tissue Organ Cult 132: 201-212. https://doi.org/10.1007/s11240-017-1326-0
    CrossRef
  16. Husain MK, Anis M, Shahzad A (2008) In vitro propagation of a multipurpose leguminous tree (Pterocarpus marsupium Roxb.) using nodal explants. Acta Physiol Plant 30: 353-359
    CrossRef
  17. Joshi I, Bisht P, Sharma VK, Uniyal DP (2003) Studies on effect of nutrient media for clonal propagation of superior phenotypes of Dalbergia sissoo Roxb. through tissue culture. Silvae Genet 52: 143-147
  18. Kao CH, Yang SF (1983) Role of ethylene in the senescence of detached rice leaves. Plant Physiol 73: 881-885
    Pubmed KoreaMed CrossRef
  19. Lemos EEP, Jennet B (2015) Control of leaf abscission in nodal cultures of Annona squamosa L. J Hortic Sci Biotechnol 71: 721-728
    CrossRef
  20. Majeed F. A, Munir H, Rashid R, Zubair M. T. (2019) Antimicrobial, cytotoxicity, mutagenicity and anti-epileptic potential of ethanol extracts of a multipurpose medicinal plant Dalbergia sissoo. Biocatalysis and Agricultural Biotechnology 19: 101155. https://doi.org/10.1016/j.bcab.2019.101155
    CrossRef
  21. Mirzai F, Uliaie ED, Hagh AB (2015) Stimulation effect of AgNO3 and CoCl2 as ethylene inhibitors on in vitro organogenesis of sunflower (Helianthus annuus L.). J Agric Sci 25: 113-118
    CrossRef
  22. Mookkan M, Andy G (2014) AgNO3 boosted high-frequency shoot regeneration in Vigna mungo (L.) Hepper. Plant Signal Behav 9(10): 1-5. https://doi.org/10.4161/psb.32165
    Pubmed KoreaMed CrossRef
  23. Skoog F, Skoog F; Murashige T. (1962) A Revised Medium for Rapid Growth and Bio Assays with Tobacco Tissue Cultures. Plant Physiology 15: 473-497
    CrossRef
  24. Naik SK, Chand PK (2003) Silver nitrate and aminoethoxyvinylglycine promote in vitro adventitious shoot regeneration of pomegranate (Punica granatum L.). J Plant Physiol 160: 423-430
    Pubmed CrossRef
  25. Orwa C, Mutua A, Kindt R, Jamnadass R, Anthony S (2009). Agroforestree Database: A tree reference and selection guide version 4.0. Available online: http://www.worldagroforestry.org. accessed on 7 December 2018
  26. Pattnaik S, Pradhan C, Naik SK, Chand PK (2000) Shoot organogenesis and plantlet regeneration from hypocotyl-derived cell suspensions of a tree legume Dalbergia sissoo. In vitro. Cell Dev Biol - Plant 36: 407-411
    CrossRef
  27. Phulwaria M, Ram K, Harish, Gupta AK, Shekhawat NS (2012b) Micropropagation of mature Terminalia catappa (Indian almond)- a medicinally important forest tree. J Forest Res 17: 202-207
    CrossRef
  28. Pua EC, Chi GL (1993) De novo shoot morphogenesis and plant growth of mustard (Brassica juncea) in vitro in relation to ethylene. Physiol Plant 88: 467-474
    CrossRef
  29. Riyathong T, Dheeranupattana S, Palee J, Shank L (2010) Shoot multiplication and plant regeneration from in vitro cultures of drumstick tree (Moringa oleifera Lam.). In: The 8th international symposium on biocontrol and biotechnology. King Mongkut’s Institute of Technology Ladkrabang and Khon Kaen University, Nongkhai Campus, Thailand, pp 99-104
  30. Sarropoulou V, Dimassi-Theriou K, Therios I (2016) Effect of the ethylene inhibitors silver nitrate, silver sulfate, and cobalt chloride on micropropagation and biochemical parameters in the cherry rootstocks CAB-6P and Gisela 6. Turk J Biol 40: 670-683. https://doi.org/10.3906/biy-1505-92
    CrossRef
  31. Shahzad AShahzad A et al (2017) Plant Tissue Culture: Applications in Plant Improvement and Conservation. In: In Plant Biotechnology: Principles and Applications. Springer Singapore, pp 37-72
    CrossRef
  32. Singh AK, Chand S (2003) Somatic embryogenesis and efficient plant regeneration from cotyledon explants of a timber yielding legumi nous tree Dalbergia sissoo Roxb. J Plant Physiol 160: 415-421
    Pubmed CrossRef
  33. Tamimi SM (2015) Effects of ethylene inhibitors, silver nitrate (AgNO3), cobalt chloride (CoCl2) and aminooxy acetic acid (AOA), on in vitro shoot induction and rooting of banana (Musa acuminata L.). Afr J Biotechnol 14: 2511-2516. https://doi.org/10.5897/AJB2015.14788
    CrossRef
  34. Tewari D.N (1994). A Monograph on Dalbergia sissoo Roxb. International Book Distributors, Dehra Dun, India
  35. Thirunavoukkarasu M, Panda PK, Nayak P, Behera PR, Satpathy GB (2010) Effect of media type and explant source on micropropagation of Dalbergia sissoo Roxb. - an important multipurpose forest tree. In: Int Res J Plant Sci, pp 1155-1162
  36. Vibha J. B., Shekhawat N. S., Mehandru P., Dinesh R (2014) Rapid multiplication of Dalbergia sissoo Roxb.: A timber yielding tree legume through axillary shoot proliferation and Ex vitro rooting. In: Physiology and Molecular Biology of Plants, pp 81-87. https://doi.org/10.1007/s12298-013-0213-3
    Pubmed KoreaMed CrossRef
  37. Yan H, Liang C, Yang L, Li Y (2010) In vitro and Ex vitro rooting of Siratia grosvenori a traditional medicine plant. Acta Physiol Plant 32: 115-120
    CrossRef
JPB
Vol 51. 2024

Stats or Metrics

Share this article on

  • line

Related articles in JPB

Journal of

Plant Biotechnology

pISSN 1229-2818
eISSN 2384-1397
qr-code Download