Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system
<p>Experiment were carried out to establish the most optimum culture condition and to</p><p>identify the most responsive explants for regeneration Brassica oleraceae L. var</p><p>Capitata through plant tissue culture system. Accli...
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Q Science Noor Fara\'Ain Daud Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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<p>Experiment were carried out to establish the most optimum culture condition and to</p><p>identify the most responsive explants for regeneration Brassica oleraceae L. var</p><p>Capitata through plant tissue culture system. Acclimatization process for established</p><p>plantlets was also conducted. The experimental design of this study was Complete</p><p>Randomized Design (CRD) method. For shoot regeneration using different</p><p>concentrations of BAP and NAA, the most responsive explant was stem explants in</p><p>which MS medium supplemented with 1.5 mg/L BAP and 0.5 mg/L NAA produced</p><p>8.400 0.889 shoots per explant. Whereas, the combination auxin and cytokinin also</p><p>showed stem explants was the most responsive. Subsequently, for root regeneration</p><p>using different concentrations of BAP and NAA, the most responsive explant was</p><p>leave in which MS media supplemented with 0.5 mg/L BAP and 0.5 mg/L NAA</p><p>produced 51.133 2.929 roots per explant. While the combination of auxin and</p><p>cytokinin showed the most responsive was root. Next, for callus induction with</p><p>combination of BAP and NAA showed that petiole was the most responsive explant.</p><p>Callus was white in colour with friable structure. Meanwhile, for callus induction with</p><p>combination of auxin and cytokinin showed stem was the most responsive. Callus was</p><p>light brown and friable. In addition, synthetic seeds were produced when microshoots</p><p>were encapsulated with 4.0% sodium alginate solution added with 1.0 mg/L BAP and</p><p>0.5 mg/L NAA. The germination rate was 6.832 0.622 shoots per explant. Finally,</p><p>the acclimatization of this plantlet succeeded with combination of (black soil and red</p><p>soil at 2:1 ratio) with the survival rate of 86.67%. This research showed that</p><p>morphogenesis studies of Brassica oleraceae L. var Capitata through tissue culture</p><p>system was successfully achieved. Further studies on chemical such as secondary</p><p>metabolites contained in the callus and explants extract should be carried out.</p> |
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Noor Fara\'Ain Daud |
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Noor Fara\'Ain Daud |
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Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system |
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morphogenesis studies of brassica oleraceae l.var capitata through tissue culture system |
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oai:ir.upsi.edu.my:71612022-06-15 Morphogenesis studies of Brassica oleraceae L.var Capitata through tissue culture system 2021 Noor Fara\'Ain Daud Q Science <p>Experiment were carried out to establish the most optimum culture condition and to</p><p>identify the most responsive explants for regeneration Brassica oleraceae L. var</p><p>Capitata through plant tissue culture system. Acclimatization process for established</p><p>plantlets was also conducted. The experimental design of this study was Complete</p><p>Randomized Design (CRD) method. For shoot regeneration using different</p><p>concentrations of BAP and NAA, the most responsive explant was stem explants in</p><p>which MS medium supplemented with 1.5 mg/L BAP and 0.5 mg/L NAA produced</p><p>8.400 0.889 shoots per explant. Whereas, the combination auxin and cytokinin also</p><p>showed stem explants was the most responsive. Subsequently, for root regeneration</p><p>using different concentrations of BAP and NAA, the most responsive explant was</p><p>leave in which MS media supplemented with 0.5 mg/L BAP and 0.5 mg/L NAA</p><p>produced 51.133 2.929 roots per explant. While the combination of auxin and</p><p>cytokinin showed the most responsive was root. Next, for callus induction with</p><p>combination of BAP and NAA showed that petiole was the most responsive explant.</p><p>Callus was white in colour with friable structure. Meanwhile, for callus induction with</p><p>combination of auxin and cytokinin showed stem was the most responsive. Callus was</p><p>light brown and friable. In addition, synthetic seeds were produced when microshoots</p><p>were encapsulated with 4.0% sodium alginate solution added with 1.0 mg/L BAP and</p><p>0.5 mg/L NAA. The germination rate was 6.832 0.622 shoots per explant. Finally,</p><p>the acclimatization of this plantlet succeeded with combination of (black soil and red</p><p>soil at 2:1 ratio) with the survival rate of 86.67%. This research showed that</p><p>morphogenesis studies of Brassica oleraceae L. var Capitata through tissue culture</p><p>system was successfully achieved. Further studies on chemical such as secondary</p><p>metabolites contained in the callus and explants extract should be carried out.</p> 2021 thesis https://ir.upsi.edu.my/detailsg.php?det=7161 https://ir.upsi.edu.my/detailsg.php?det=7161 text eng closedAccess Masters Universiti Pendidikan Sultan Idris Fakulti Teknikal dan Vokasional <p>Amir, H.M., Shamsudin, M.N., Hussein, M.A., & Radam, A. (2007). An Economic</p><p>Evaluation of IPM Practices in Cabbage Production in Cameron Highlands,</p><p>Pahang. Economic and Technology Management Review. Vol. 2, 11-21.</p><p></p><p>Babbar, S.B., Agarwal, P.K., Sahay, S. & Bhojwani, S.S. (2004). Isolated Microspore</p><p>Culture of Brassica : An Experimental Tool for Developmental Studies and Crop</p><p>Improvement. Indian Journal of Biotechnology, Vol. 3, 185-202.</p><p></p><p>Bapat, V.A. (2000). Synthetic seeds: a novel concept in seed biotechnology. Retrieved</p><p>from http://www.barc.gov.in/publications/nl/index.html ( accessed on 18 January</p><p>2019 )</p><p></p><p>Chandra, S., Bandopadhyay, R., Kumar, V. & Chandra, R. (2010). Acclimatization of</p><p>tissue cultured plantlets : from laboratory to land. Biotechnol Lett. 32,1199-1205.</p><p>https://doi: 10.1007/s10529-010-0290-0</p><p></p><p>Chauffour, F., Bailly, M., Perreau, F., Cueff, G., Suzuki, H., & Collet, B. (2019).</p><p>Multi-omics Analysis Reveals Sequential Roles for ABA during Seed Maturation.</p><p>Retrieved from http://www.plantphysiol.org/content/180/2/1198 ( accessed on 18</p><p>January 2019 )</p><p></p><p>Chooi, H.O. (2008). Vegetables for Health & Healing. Kuala Lumpur: Utusan</p><p>Publications and Distributors Sdn. Bhd, pp: 58-59.</p><p></p><p>Cristea, T.O. (2013). The Influence of pH on Microspore Embryogenesis of White</p><p>Cabbage (Brassica oleraceae L.). Not Sci Biol, 5 (4) : 485-489.</p><p></p><p>Cseke, L.J., Kaufman, P. B., Podila, G.K., & Chung J.T (2004). Handbook of</p><p>Molecular and Cellular Methods in Biology and Medicine, Second Ed. New York:</p><p>CRC Press</p><p></p><p>Dixon, R.A., & Gonzales, R.A. (1994). Plant Cell Culture: A Practical Approach 2nd</p><p>Edition. Oxford University Press. Oxford.</p><p></p><p>Dixon, R.G. (2007). Vegetables Brassicas and Related Crucifers. United Kingdom:</p><p>CABI Head Office Nosworthy Way.</p><p></p><p>El-Esawi, M.A. (2018). Brassica Germplasm : Characterization, Breeding and</p><p>Utilization : British Library Cataloguing, pp : 1-2</p><p></p><p>Evans, D.E., Coleman, J. & Keavns, A. (2003). Plant Cell Culture. London & New</p><p>York: BIOS Scientific Publishers, pp : 7-8</p><p></p><p>Fowke, L.C. (1995). Transmission and Scanning Electron Microscopy for Plant</p><p>Protoplasts, Cultured Cells and Tissues. New York ; Springer, Berlin Heidelberg.</p><p></p><p>Frusciante, L., Barone, A., Carputo, D., Ereolano, M.R., Della Rocca, F., & Esposito,</p><p>S. (2000). Evaluation and Use of Plant Biodiversity for Food and Pharmaceutical.</p><p>Fitoterpia, 71 : 66-S72.</p><p></p><p>Gana, A.S. (2010). The Role Of Synthetic Growth Hormones In Crop Multiplication</p><p>And Improvement. African Journal of Biotechnology Vol. 10(51), pp. 10330-</p><p>10334.</p><p></p><p>Hajam, M.A., Hassan, G.I., Bhat, T.A., Bhat, I.A., Rather, A.M., Parray, E.A., et al</p><p>(2017). Understanding Plant Growth Regulators, Their Interplay : for Nursery</p><p>Establishment in Fruits. International Journal of Chemical Studies, 5(5), 905-910.</p><p></p><p>Hamid, A.U. (2018). A Beginners Guide to Scanning Electron Microscopy. Center</p><p>for Engineering Research. https://doi:org/10.1007/978-3-319-98482-7</p><p></p><p>Hussein, N. (2012). Effects of Nutrient Media Constituents on Growth and</p><p>Development of Banana (Musa spp.) Shoot Tips Cultured in Vitro. African</p><p>Journal of Biotechnology. 11(37), pp. 9001-9006</p><p></p><p>Ibrahim, M.A. (2015, 26 March). FAMAS Helping Hand for Cabbage Growers,</p><p>BERNAMA.</p><p></p><p>Ichsan, M. (2018). In vitro regeneration and acclimatization of Carica papaya L.</p><p>Retrieved from</p><p>http://www.malrep.uum.edu.my/rep/Record/oai:ir.upsi.edu.my:3811 ( accessed on</p><p>20 March 2019 )</p><p></p><p>Ikeuchi, M., Sugimoto, K. & Iwase, A. (2013). Plant Callus : Mechanisms of</p><p>Induction and Repression. The Plant Cell, 25(9), 3159-3173.</p><p>https://doi:10.1105/tpc. 113.116053</p><p></p><p>ISAAA (2004). Tissue Culture Technology. Retrieved from http://www.isaaa.org/kc.</p><p>(accessed on 24 March 2019)</p><p></p><p>Jamilah Syafawati Yaacob., Noraini Mahmad., Rosna Mat Taha., Normadiha</p><p>Mohamed., Anis Idayu Mad Yussof., & Azani Saleh. (2014). Optimization of</p><p>Culture Conditions (Sucrose, pH, and Photoperiod) for In Vitro Regeneration and</p><p>Early Detection of Somaclonal Variation in Ginger Lime (Citrus assamensis).</p><p>https://doi:10.1155/2014/262710</p><p></p><p>Jusoff, K. (2009). Estimating Cabbage Production in Cameron Highlands, Malaysia</p><p>Using IKONOS Data. Canadian Research & Development Center of Sciences and</p><p>Cultures, Vol. 2 (2).</p><p></p><p>Kadhimi, A. A., Alhasnawi, A. N., Isahak, A., Ashraf, M. F., Mohamad, A., Doni, F.,</p><p>et al (2014). Use of biotechnology to improve the tolerance in rice (Oryza sativa)</p><p>to drought stress. Journal of Pure and Applied Microbiology, 8(5), pp : 4001-</p><p>4010.</p><p></p><p>Kamada, H., Kobayashi, K., Kiyosue, T., & Harada, H. (1989). Stress induced</p><p>somatic embryogenesis in carrot and its application to synthetic seed production.</p><p>In Vitro Cellular & Development Biology. 25(12), pp : 1163-1166.</p><p></p><p>Lohry, R. (2007). Micronutrients : Functions, Sources and Application Methods.</p><p>Retrieved from https://www.agry.purdue.edu/CCA/2007/2007/Proceedings</p><p>(accessed on 24 March 2019)</p><p></p><p>Marschner, P. (2012). Marschners Mineral Nutrition of Higher Plants (Third</p><p>Edition) : School of Agriculture, Food and Wine, The University of Adelaide,</p><p>Australia, p.p : 135-189</p><p></p><p>Mastuti, R., Munawarti, A. & Firdiana, E.R. (2017). The Combination Effect of</p><p>Auxin and Cytokinin on in vitro Callus Formation of Physalis angulate L. A</p><p>Medicinal Plant. International Conference on Global Resources Conservation;</p><p>https://doi:org/10.1063/ 1.5012721</p><p></p><p>McDonald, M.R., Warland, J., & McKeown, A.W. (2006). Long-Term Climate And</p><p>Weather Patterns In Relation To Crop Yield: A Minireview. Botany, Vol 84 (7).</p><p></p><p>Min, B. C., Omar, K., & Lin, O. C. (2006). 1001 Garden Plants in Singapore.</p><p>Singapore : National Parks Publication.</p><p></p><p>Muhammad, Z.A., Iqbal, H., Sohaib R., Muhammad A.Z., Muhammad, S.Z., Zaheer,</p><p>A., & Sabir H.S. (2012). In vitro Response of Cytokinin and Auxin to Multiple</p><p>Shoot Regeneration in Solanum tuberosum L. American-Eurasian J. Agric. &</p><p>Environ. Sci., 12 (11): 1522-1526.</p><p></p><p>Mumo, N.N., Rimberia, F.K., Mamati, G.E., & Kihurani, A.W. (2013). In</p><p>vitro regeneration of selected Kenyan papaya (Carica papaya L.)</p><p>lines through shoot tip culture. African Journal of Biotechnology, Vol 12(49),</p><p>6826-6832</p><p></p><p>Murashige, T. & Skoog, F.A (1962). Revised Medium for Rapid Growth and Bio</p><p>Assays with Tobacco Tissue Cultures. Physiologia Plantarum. 15,pp: 473-497.</p><p></p><p>New World Encyclopedia, retrieved from</p><p>https://www.newworldencyclopedia.org/entry/Cabbage, ( accessed on 21 March</p><p>2017 )</p><p></p><p>Ngomuo, M., Mneney, E., & Ndakidemi, P. (2013). The Effects of Auxins and</p><p>Cytokinin on Growth and Development of (Musa sp.) Var. Yangambi Explants</p><p>in Tissue Culture. American Journal of Plant Sciences, 4(11), 2174</p><p></p><p>Ningappa, K. (2016). Evaluation of Cabbage (Brassica oleraceae L. var. capitata)</p><p>Genotypes for Compactness and Internal Tipburn Resistance Under Rain Shelter.</p><p>Department of Olericulture College of Horticulture Kerala Agricultural</p><p>University Vellanikkara, Thrissur-680 656 Kerala, India.</p><p></p><p>North, J., Ndakidemi, P., & Laubscher, C.P. (2010). The Potential of Developing an</p><p>in vitro Method for Propagating Strelitziaceae. African Journal Biotechnology.</p><p>9(45), pp. 7583-7588.</p><p></p><p>Panjaitan, S. B., Aziz, M. A., Rashid, A. A. and Saleh. N. M. (2007). In-Vitro Plantlet</p><p>Regeneration from Shoot Tip of Field-grown Hermaphrodite Papaya (Carica</p><p>papaya L. cv. Eksotika). International Journal of Agriculture and Biology. 9 (6),</p><p>827-832.</p><p></p><p>Pavlovic, S., Adzic, S., Cvikic, D., Zdravkovic, J., & Zdravkovic, M. (2012). In Vitro</p><p>Culture as a Part of Brassica oleraceae var. capitata L. Breeding. GENETIKA,</p><p>44(3) pp : 611-618.</p><p></p><p>Prakash, S. & Hoque, M.I. (2002). Culture Media and Containers. In: International</p><p>Atomic Energy Agency (ed.): Low Cost Options for Tissue Culture Technology in</p><p>Developing Countries. Proceedings of a technical meeting, 26-30 August,</p><p>Vienna, Austria.</p><p></p><p>Ranabhatt, H. & Kapor, R. (2017). Plant Biotechnology. Woodhead Publishing India,</p><p>pp : 4</p><p></p><p>Ravanfar, S.A., Aziz, M.A., Rashid, A.A., & Salim, S. (2014). In Vitro Adventitious</p><p>Shoot Regeneration from Cotyledon Explant of Brassica oleraceae subsp. Italic</p><p>& Brassica oleraceae subsp. Capitata using TDZ and NAA. Pak. J. Bot., 46(1):</p><p>329-335.</p><p></p><p>Rishla, K., Sithara, A., & Deepa, P. (2017). Effect of NaCl stress on callus induction</p><p>in centella asiatica (l.) urban. European Journal of Biomedical and</p><p>Pharmaceutical Sciences, 4 (9).</p><p></p><p>Roberta, H.S. (2000). Plant Tissue Culture Techniques and Experiments. California:</p><p>Academic Press, pp : 54-60</p><p></p><p>Rosna M.T. (2004). Kultur Tisu Tumbuhan Berbunga : Penerbit Universiti Malaya, pp</p><p>: 23</p><p></p><p>Rout, G.R. & Sahoo, S. (2015). Role of Iron in Plant Growth and Metabolism.</p><p>Reviews in Agricultural Science, 3: 1-24.</p><p></p><p>Saad, A.I.M. & Elshahed, A.M. (2012). Plant Tissue Culture Media : Department of</p><p>Botany and Microbiology, Faculty of Science, Sebha University, Libya, pp : 29-</p><p>39.</p><p></p><p>Safaryani, N., Haryanti, S., & Hastuti, E. (2007). Pengaruh Suhu dan Lama</p><p>Penyimpanan Terhadap Penurunan Kadar Vitamin C Brokoli (Brassica oleracea</p><p>L). Sellula, 15(2).</p><p></p><p>Saikia, M., Shrivastava, K., & Sureshkumar, S. (2013). Effect of culture media and</p><p>growth hormones on callus induction in Aquallaria malaccensis Lam., a</p><p>medicinally and commercially important tree species of north east india. Asia</p><p>Journal of Biological Sciences,6(2), 96-105.</p><p></p><p>Samir, C.D., & Usha, A. (2020). In Vitro Propagation Strategies of Medicinally</p><p>Important Berry Crop, Lingonberry (Vaccinium vitis-idaea L.). Agronomy 2020,</p><p>Vol 10, 744; https://doi:10.3390/agronomy10050744</p><p></p><p>Shamsudin, M.N., Amir, H.M. and Radam, A. (2010). Economic Benefits of</p><p>Sustainable Agricultural Production : The Case of Integrated Pest Management in</p><p>Cabbage Production. EnvironmentAsia 3 (special issue) 168-174.</p><p></p><p>Sharma, A., Lal, D., & Sutradhar, M. (2017). Effect of growth regulators on callus</p><p>morphology of rice anther culture. Journal of Applied Biology & Biotechnology,</p><p>Vol 5 (3), 068-071.</p><p></p><p>Shekhawat, M., & Manokari, M. (2017). Foliar Micromorphology of in Vitro -</p><p>Cultured Shoots and Field-Grown Plants of Passiflora Foetida. Horticultural Plant</p><p>Journal, Vol 3. https://doi:10.1016/j.hpj.2017.01.009.</p><p></p><p>Shekhawat, M., Manokari, M., & Kannan, N. (2017). Micromorphological response</p><p>towards altered environmental conditions in subsequent stages of in vitro</p><p>propagation of Morinda coreia. Environmental and Experimental Biology. Vol</p><p>15.https://doi:10.22364/eeb.15.06.</p><p></p><p>Siong, P.K., Mohajer, S. & Taha, R.M. (2012). Production of artificial seeds derived</p><p>from encapsulated in vitro micro shoots of cauliflower, Brassica oleracea var.</p><p>botrytis. Romanian Biotechnological Letter. 17(4), 7549-7556</p><p></p><p>Siong, P.K., Mohajer, S., Taha, R.M. (2012). Production of artificial seeds derived</p><p>from encapsulated in vitro micro shoots of cauliflower, Brassica oleraceae var.</p><p>botrytis. Romanian Biotechnological Letters, 17(4), 7549-7556.</p><p></p><p>Smith, H.R. (2000). Plant Tissue Culture Techniques and Experiments.California:</p><p>Academic Press.</p><p></p><p>Su, Y.H., Liu, Y.B, & Zhang, X.S. (2011). AuxinCytokinin Interaction Regulates</p><p>Meristem Development. Molecular Plant. https://doi:10.1093/mp/ssr007</p><p></p><p>Sutter, E.G., Shackel, K., & Diaz, J.C. (1992). Acclimatization of tissue cultured</p><p>plants. Acta Horticulturae 314. Propagation of Ornamental Plants, 115-119.</p><p></p><p>Swapp, S. (2019). What is Scanning Electron Microscopy (SEM). Retrieved from</p><p>https://serc.carleton.edu/research_education/geochemsheets/techniques/SEM.html</p><p>( accessed on 20 March 2019 )</p><p></p><p>Teo, C.H., & Seow, C.C. (1992). A Pulsed NMR Method for the Study of Starch</p><p>Retrogradation. Starch, Vol. 44 (8), 288-292</p><p></p><p>Tilaar, W. Sumeru, A., Bagyo, Y., Jeany, P., & Francien, H.T (2012). Shoot Induction</p><p>from Broccoli Explant Hypocotyls and Biosynthesis of Sulforaphane.</p><p>International Journal of Basic & Applied Sciences, Vol 12 (6), 44-48.</p><p></p><p>Touchell, D., Smith, J. and Ranney, T.G. (2008). Novel Applications of Plant Tissue</p><p>Culture : North Carolina State University, North Carolina, pp : 22-23</p><p></p><p>Tripathi, D.K., Singh, V.P., Chauhan, D.K., Prasad, S.M., and Dubey, N.K. (2014).</p><p>Improvement of Crops in the Era of Climatic Changes : Banaras Hindu</p><p>University, Varanasi, India, pp : 197-216</p><p></p><p>Volenikova, M. & Ticha, I. (2001). Insertion profiles in stomatal density and sizes in</p><p>Nicotiana tabacum L. plantlets. Biology plantarum. 44(2): 161-165</p><p></p><p>Wang, K.L.C., Li, H., & Ecker, J.R. (2002). Ethylene Biosynthesis and Signaling</p><p>Networks. American Society of Plant Biologists. https://doi:org/10.1105</p><p>/tpc.001768</p><p></p><p>Welsh, J.R. (1991). Dasar-dasar genetika dan pemuliaan tanaman. Jakarta: Penerbit</p><p>Erlangga.</p><p></p><p>White, R.P. (1997). Handbook of Plant Tissue Culture. New Delhi: Publications and</p><p>Information Division Indian Council of Agricultural Research, pp : 25</p><p></p><p>Wiart, C. (2002). Medicinal Plants of Southeast Asia. Petaling Jaya, Selangor:</p><p>Prentice Hall Pearson, pp: 111.</p><p></p><p>Willis, K.J. (ed.) ( 2017). State of the Worlds Plants 2017. Report. Royal Botanic</p><p>Gardens, Kew.</p><p></p><p>Yaacob, J.S., Saleh, A., Elias, H., Abdullah, S., Mahmad, N. & Mohamed, N. (2014).</p><p>In Vitro Regeneration and Acclimatization Protocols of Slected Ornamental Plants</p><p>(Agapanthus praecox, Justice betonica and Celosia cristata). Sains Malaysiana,</p><p>43(5) : 715-722.</p><p></p><p>Yaacob, J.S., Mahmud,N., Taha, R.M., Mohamed, N., Yussof, A.I.M., & Saleh, A.</p><p>(2014). Optimization of culture conditions (sucrose, pH, and photoperiod) for in</p><p>vitro regeneration and early detection of somaclonal variation in ginger lime</p><p>(citrus assamensis). The Scientific World Journal, articles ID 262710.</p><p></p><p>Yasmin, S., Nasiruddin, K.M., Begum, R., & Talukder, S.K. (2003). Regeneration</p><p>and establishment of potato plantlets through callus formation with BAP and</p><p>NAA. Asian Journal of Plant Sciences, 2(12). 936-940.</p><p></p><p>Yusnita. (2004). Kultur jaringan, cara memperbanyak tanaman secara efisien.</p><p>Jakarta: AgroMedia Pustaka.</p><p></p><p>Yussof, A.I.M., Wafa, S.N. & Taha, R.M. (2012). Plant regeneration and synthetic</p><p>seeds production of Brassica oleraceae var. italic. International Symposium on</p><p>Sustainable Vegetable Production in Southeast Asia.</p><p>https://doi:10.17660/ActaHortic.2012.958.21</p><p></p><p>Zazimalova, E., Petrasek, J., & Benkova, E. (2014). Auxin and Its Role in Plant</p><p>Development. London : Springer Wien HeidelbergNew York Dordrecht London,</p><p>pp : 171</p><p></p><p>Zheng, Y., Xu, M., Shen, R., Qiu, S., & Ouyang, Z. (2013). Effects of experimental</p><p>warming on stomatal traits in leaves of maize (Zea may L.). Ecology and</p><p>Evolution. 3(9) : 3095-3111. https://doi:10.1002/ece3.674.</p><p></p><p>Znidarcic, D., Valic, N., & Trdan, S. (2008). Epicuticular Wax Content in the Leaves</p><p>of Cabbage (Brassica oleraceae L.var Capitata) as a Mechanical Barrier against</p><p>Three Insect Pests. Acta Agriculturae Slovenica, 1-2.</p><p></p> |