Inisiasi, pertumbuhan, dan perkembangan kalus embriogenik tanaman stevia (Stevia rebaudiana)

Authors

  • Masna Maya SINTA Indonesian Research Institute for Biotechnology and Bioindustry (Scopus ID: 57193851063)
  • Rizka Tamania SAPTARI PPBBI
  • . SUMARYONO PPBBI

DOI:

https://doi.org/10.22302/iribb.jur.mp.v89i2.458

Keywords:

somatic embryogenesis, callus initiation, in vitro culture, callus proliferation, stevia

Abstract

The leaves of sweetener plant Stevia rebaudiana contain secondary metabolites of steviol glycosides which are very sweet, with no calorie and zero glycemic index. Propagation of stevia by seeds is ineffective due to its low germination rate and diverse progenies. The tissue culture of stevia can be used to mass propagate rapidly and is commonly conducted by shoot multiplication. Up to now, the technology of somatic embryogenesis (SE) in stevia has not been successful yet. SE is developed to increase the production scale, rejuvenate clonal-propagated plants, and plant genetic transformation. The research objective was to develop protocols for the initiation, proliferation, and development of embryogenic calli of stevia as potential materials for SE. The explants used were young leaves, nodes, and internodes of axenic plantlets of stevia BX clone. The explants were cultured on MS solid media containing different concentrations of auxin and cytokinin for callus initiation. Callus emerged after 2-3 weeks of culture. The calli obtained were proliferated by subculturing several times as material stocks for indirect SE. MS solid media added with 1 µM 3,4-D and 16 mM CaCl2 gave the highest callus multiplication rate (4.7 times in 3 weeks). The selection of embryogenic calli was made continuously to obtain a pure line of embryogenic calli. Three types of calli attained were friable, fast-growing, yellowish calli, shiny nodular calli, and greenish nodular calli. Histological studies revealed that cells of the nodular calli had been differentiated to potentially formed somatic embryos.

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References

Apio HB, T Alicai, Y Baguma, SB Mukasa, A Bua & N Taylor (2015). Production of friable embryogenic callus and regeneration of Ugandan farmer-preferred cassava genotypes. Afr J Biotechnol 14(22), 1854-1864.

Banerjee M & P Sarkar (2008). In vitro callusing in Stevia rebaudiana Bertoni using cyanobacterial media - a novel approach to tissue culture. Internat J Integrative Biol 8(3), 163-168.

Banerjee M & P Sarkar (2010). Somatic embryogenesis in Stevia rebaudiana Bertoni using different concentration of growth hormones. Internat J Plant Sci 5(1), 284-289.

Blanc G, N Michaux-Ferriere, C Teisson, L Lardet & MP Carron (1999). Effects of carbohydrate addition on the induction of somatic embryogenesis in Hevea brasiliensis. Plant Cell Tiss Organ Cult 59, 103-112.

Brandle JE & PG Telmer (2007). Steviol glycoside biosynthesis. Phytochem 68, 1855–1863.

Cailloux F, J Julien-Guerrier, L Linossier & A Coudret (1996). Long-term somatic embryogenesis and maturation of somatic embryos in Hevea brasiliensis. Plant Sci 120, 185-196.

Ceunen S & J Geuns (2013). Steviol glycosides: Chemical diversity, metabolism, and function. J Nat Prod 76, 1201-1228.

Cramer B & R Ikan (1986). Sweet glycosides from the stevia plant. Chem Br 22(10), 915−917.

Dafalla HM, AM Elsheikh, HA Ali & MM Khafalla (2019). Callus maintenance and cell line selection of Grewia tenax. J Herbs Spices Med Plants 25(3), 218-235.

Egertsdotter U, I Ahmad & D Clapham (2019). Automation and scale up of somatic embryogenesis for commercial plant production, with emphasis on conifers. Front Plant Sci 10, 109.

Gawel-Beben K, T Bujak, Z Niziol-Lukaszewska, B Antosiecwicz, A Jakubczyk, M Karas & K Rybcznska (2015). Stevia rebaudiana Bert. leaf extracts as a multifunctional source of natural antioxidants. Molecules 20, 5468-5486.

Goettemoeller J & A Ching (1999). Seed germination in Stevia rebaudiana, p. 510-511. In: J Janick (ed.) Perspective on New Crops and New Uses. ASHS Press, Alexandria, VA.

Janarthanam B, M Gopalakrishnan, G Lakshmi Sai & T Sekar (2009). Plant regeneration from leaf derived callus of Stevia rebaudiana Bertoni. Plant Tiss Cult Biotechnol 19(2), 133-141.

Jin CS & CL Keng (2013). Factors affecting the selection of callus cell lines and the preparation of the cell suspension culture of Artemisia annua L. Plant Tissue Cult & Biotech 23(2), 157‐163.

Keshvari T, A Najaphy, D Kahrizi & A Zebarjadi (2018). Callus induction and somatic embryogenesis in Stevia rebaudiana Bertoni as a medicinal plant. Cell Mol Biol 64(2), 46-49.

Kumar R, S Sharma & S Sood (2014). Yield components, light interception and marker compound accumulation of stevia (Stevia rebaudiana Bertoni) affected by planting material and plant density under western Himalayan conditions. Arch Agron Soil Sci 1, 1-15.

Lardet L, F Dessailly, MP Carron, MA Rio, N Ferreire & P Montoro (2009). Secondary somatic embryo in Hevea brasiliensis (Mull. Arg.): An alternative process for long-term somatic embryogenesis. J Rubb Res 12(4), 215-228.

Lardet L, F Martin, F Desailly, MP Carron & P Montoro (2007). Effect of exogenous calcium on post-thaw growth recovery and subsequent plant regeneration of cryopreserved embryogenic calli of Hevea brasiliensis (Mull. Arg.). Plant Cell 26, 559-569.

Lelu-Walter MA, F Gautier F, K Eliášová, L Sanchez, C Teyssier, AM Lomenech, CL Metté, C Hargreaves, JF Trontin & C Reeves (2018). High gellan gum concentration and secondary somatic embryogenesis: Two key factors to improve somatic embryo development in Pseudotsuga menziesii. Plant Cell Tissue Organ Cult 132, 137–155.

Lemus-Mondaca, A Vega-Galvez, P Rojas, K Stucken, S Delporte, G Valenzuela-Barra, RJ Jagus, MV Aguero & A Pasten (2018). Antioxidant, antimicrobial and anti-inflammatory potential of Stevia rebaudiana leaves: effect of different drying methods. J Appl Res Medicinal and Aromatic Plants 11, 37-46.

Lizawati (2012). Induksi kalus embriogenik dari eksplan tunas apikal tanaman jarak pagar (Jatropha curcas L.) dengan penggunaan 2,4-D dan TDZ. Bioplantae 1(2), 75-87.

Lopez-Arellano M, S Dhir, NC Albino, A Santiago, T Morris & SK Dhir (2015). Somatic embryogenesis and plantlet regeneration from protoplast culture of Stevia rebaudiana. Bristish Biotechnol J 5(1), 1-12.

Mengesha B, W Geja & Z Damtew (2014). Stevia production guidelines. Ethiopian Institute of Agricultural Research, Ethiopia.

Modeste KK, KK Edmond, KN Gilles, G Michel, K Mongomaké, KT Hilaire (2012). Callogenesis and somatic embryogenesis induction in Hevea brasiliensis: effects of fruit shelf-life and carbon source. Res in Biotechnol 3(6), 42-50.

Montoro P, MP Carron, F Granet, L Lardet & J Leclercq (2012). Development of new varietal types based on rejuvenation by somatic embryogenesis and propagation by conventional budding or microcutting in Hevea brasiliensis. CIBA Workshop 22-24 October 2012.

Murashige T & F Skoog (1962). A revised medium for rapid growth and bioassays with tobacco tissue culture. Physiol Plant 15, 473-497.

Mwaniki WI, AH Lubabali, KK Asava, CO Agwanda & SE Anami (2019). Effect of genotype and plant growth regulators on callus induction in leaf cultures of Coffea arabica L. F1 hybrid. African J Biotechnol 18(31), 1004-1015.

Nasim SA, A Mujib, R Kapoor, S Fatima, J Aslam & Mahmooduzzafar. (2010). Somatic embryogenesis in Allium sativum L. (cv. Yamuna Safed 3): Improving embryo maturation and germination with PGRs and carbohydrates. Anales de Biol 32, 1-9.

Oliveira AJB, LMC Cordeiro, RAC Goncalves,LF Ceole, T Ueda-Nakamura, M Lacomini (2013). Structure and antiviral activity of arabinogalactan with (1→6)-ß-D-galactan corefrom Stevia rebaudiana leaves. Carbohydrate Polymers 94, 179-184.

Ozyigit Y, E Ucar & K Turgut (2015). The effect of different pollination methods on seed yield and germination features in Stevia rebaudiana Bertoni. Turk JU Agric Res 21, 114-117.

Parris CA, CC Shock, M Qian (2016). Dry leaf and steviol glycoside productivity of Stevia rebaudiana in the Western United States. HortSci 51(10), 1220-1227.

Pérez E, C González, F Vaillant & M Lares (2016). Stevia derivative and its potential uses in diabetic-directed foods review. J Nutrients 3(1), 1-20.

Pikulthong V, T Teerakathi, A Thamchaipenet & S Peyachoknagul (2016). Development of somatic embryos for genetic transformation in Curcuma longa L. and Curcuma mangga Valeton & Zijp. Agric Nat Res 50(4), 276-285.

Pires R, HCardoso, A Ribeiro, A Peixe & A Cordeiro (2020). Somatic embryogenesis from mature embryos of Olea europaea L. cv. ‘Galega Vulgar’ and long-term management of calli morphogenic capacity. Plants 9, 758.

Prakash I, A Markosyan & C Bunders (2014). Development of next generation stevia sweetener: Rebaudioside M. Molecules 3, 162-175.

Raina R, SK Bhandari, R Chand & Y Sharma (2013). Strategies to improve poor seed germination in Stevia rebaudiana, a low-calorie sweetener. J Medicinal Plants Res 7(24), 1793-1799.

Ramulifho E, T Goche, J van As, TJ Tsilo, S Chivasa & R Ngara (2019). Establishment and characterization of callus and cell suspension cultures of selected Sorghum bicolor (L.) Moench varieties: A resource for gene discovery in plant stress biology. Agronomy 9, 1-18.

Ribas AF, E Dechamp, A Champion, B Bertrand, MC Combes, JL Verdeil, F Lapeyre, P Lashermes & H Etienne (2011). Agrobacterium-mediated genetic transformation of Coffea arabica (L.) is greatly enhanced by using established embryogenic callus cultures. BMC Plant Biol 11(92), 1-15.

Ruzin SE (1999). Plant Microtechnique and Microscopy. Oxford University Press. 322p.

Sinta MM & Sumaryono (2019). Pertumbuhan, produksi biomassa, dan kandungan glikosida steviol lima klon introduksi stevia di Bogor, Indonesia. J Agron Indonesia 47(1), 104-109.

Souza JMM, S Berkov & AS Santos (2014). Improvement of friable callus production of Boerhaavia paniculata Rich and the investigation of its lipid profile by GC/MS. An Acad Bras Cienc 86(3), 1015-1027.

Wang G, C Xu, S Yan & B Xu (2019). An efficient somatic embryo liquid culture system for potential use in large-scale and synchronic production of Anthurium andraeanum seedlings 10, 29.

Widoretno W, S Indriyani, C Martasari & R Hakin (2017). Effects of sugar type and concentration on Batu 55 Mandarin (Citrus reticulata Blanco.) somatic embryo maturation. Agrivita 39(1), 100-110.

Yadav AK, S Singh & Rajeev (2014). Self-incompatibility evidenced through scanning electron microscopy and pollination behaviour in Stevia rebaudiana. Indian J Agric Sci 84 (1), 93-100

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Submitted

08-07-2021

Accepted

12-10-2021

Published

29-10-2021

How to Cite

SINTA, M. M., SAPTARI, R. T., & SUMARYONO, . (2021). Inisiasi, pertumbuhan, dan perkembangan kalus embriogenik tanaman stevia (Stevia rebaudiana). Menara Perkebunan, 89(2). https://doi.org/10.22302/iribb.jur.mp.v89i2.458

Issue

Vol. 89 No. 2 (2021): Oktober, 2021

Section

Articles

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