The Role of Mutation Induction Technology in Forage Breeding

Achmad Fanindi, Harmini Harmini

Abstract

Mutation induction in breeding is one of many ways to improve the character of a plant, including forage crops.  Formation of new variety of forage plants, especially grass is still very rare in Indonesia due to several obstacles, including the flower structure, ploidand reproductive systems of forage plants. Mutation induction in breeding as a method of producing new varieties of forage plants (grass and legume) can be utilized by eliminating the constraints in forage plants, because it can create new variety without being restricted by floral structure and reproductive system of plant. The paper aims to describe about mutation breeding and its methods on forage plants and its prospect to obtain new varieties of superior forage plants to meet the needs of forage in Indonesia,A number of factors, including mutation technique, type, seed and other factors, are determining the success of mutational breeding. The creation of new types of forage plants by mutation-induction is aiming to increase productivity, improve forage performances and resist abiotic and biotic stress. Mutation breeding is expected to produce new varieties of superior forage plants in a relatively shorter time, because forage plants can be propagated in a vegetative or generative manner.  It is epxected that the assembly of new varieties of forage plants can meet the needs of forage in quantity and quality.

Keywords

Forage; breeding; mutation; superior variety

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References

Amin N, Human S, Trikosoemaningtyas T. 2014. Keragaman genetik gandum populasi Mutan M3 di Agroekosistem Tropis. J Ilm Apl Isot dan Radiasi. 10:35–44.

Amirikhaha R, Etemadia N, Mohammad R, Sabzalianb M, Nikbakhta A, Eskandaric A. 2019. Physiological consequences of gamma ray irradiation in tall fescue with elimination potential of Epichloë fungal endophyte. Ecotoxicol Environ Saf. 182.

Asadi. 2013. Pemuliaan Mutasi untuk Perbaikan terhadap Umur dan Produktivitas pada Kedelai. J AgroBiogen. 9:135–142.

Atis I, Duru M, Konuskan O, Gozubenli H. 2013. Effects of plant maturity stage on silage quality of some silage sorghum cultivars Effects of plant maturity stage on silage quality of some silage sorghum cultivars. J Food Agric Environ. 11:534–537.

Azrai M. 2016. Pemanfaatan Markah Molekuler dalam Proses Seleksi Pemuliaan Tanaman. J AgroBiogen. 1:26–37.

Bahagiawati B, Satyawan D, Santoso TJ. 2019. Tanaman Hasil Genome Editing dan Tantangan Pengaturan Keamanannya di Indonesia ( Genome-Edited Plants and the Challenges of Regulating Their Biosafety in Indonesia ). AgroBiogen. 15:93–106.

Barre P, Turner LB, Escobar-gutiérrez AJ. 2015. Leaf Length Variation in Perennial Forage Grasses. Agriculture. 5:682–696.

Barrière Y, Alber D, Dolstra O, Lapierre C, Motto M, Ordas A, Van Waes J, Vlasminkel L, Welcker C, Monod JP. 2005. Past and prospects of forage maize breeding in Europe. I. The grass cell wall as a basis of genetic variation and future improvements in feeding value. Maydica. 50:259–274.

Capstaff NM, Miller AJ. 2018. Improving the yield and nutritional quality of forage crops. Front Plant Sci. 9:1–18.

Chatterjee J, Coe RA, Acebron K, Thakur V, Yennamalli RM, Danila F, Lin HC, Balahadia CP, Bagunu E, Padhma PPOS, et al. 2021. A low CO2-responsive mutant of Setaria viridis reveals that reduced carbonic anhydrase limits C4photosynthesis. J Exp Bot. 72:3122–3136.

Dong X, Yan X, Li W. 2016. Plant Mutation Breeding with Heavy Ion Irradiation at IMP. J Agric Sci. 8:34-41.

Fan J, Shi M, Huang J, Xu J, Wang Z, Guo D. 2014. Regulation of photosynthetic performance and antioxidant capacity by 60Co γ-irradiation in Zizania latifolia plants. J Environ Radioact. 129:33–42.

Fanindi A, Sutjahjo S, Aisyah S, Purwantari ND. 2016. Characteristic morphology and genetic variability of Benggala grass (Panicum maximum cv Purple guinea) through gamma ray irradiated on acid land. J Ilmu Ternak dan Vet. 21:205–214.

Fanindi A, Sutjahjo SH, Aisyah SI, Purwantari ND. 2019. Morphological characteristics and productivity of Guinea Grass (Panicum maximum CV Purple Guinea) irradiated with Gamma-Ray. Trop Anim Sci J. 42:97–105.

Feldman A, Murchie E, Leung H, Baraoidan M, Coe R, Yu S. 2014. Increasing leaf vein density by mutagenesis: laying the foundations for C4 rice. PLoS One 9, e94947. [place unknown].

Foster B, Shu Q. 2011. Plant Mutagenesis in Crop Improvment: Basic Terms and Application. In: Shu Q, Foster B, Nakagawa N, editors. Plant Mutat Breed Biotechnol. Vienna (AT): Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture International Atomic Energy Agency; p. 9–21.

Freisleben R, Lein A. 1944. Möglichkeiten und praktische Durchführung de Mutationszüchtung. Kühn-Arhiv. 60:21–22.

Gea B, Karti P, Prihantoro I, Husni A. 2019. Aklimatisasi dan Evaluasi Produksi Mutan Rumput Gajah Kultivar Taiwan. J Ilmu Nutr dan Teknol Pakan. 17:47–53.

Gruszka D, Szarejko I, Maluszynski M. 2012. “Sodium azide as a mutagen,” in Plant Mutation Breeding and Biotechnology. [place unknown]: CABI International, Wallingford, UK.

Handayati W. 2013. Perkembangan pemuliaan mutasi tanaman hias di Indonesia. J Ilm Apl Isot dan Radiasi. 9:67–80.

Haris A, Boceng A, Tjoneng A. 2017. Pemanfaatan dosis letal efektif radiasi sinar gamma untuk mutan pendek dan genjah padi lokal (ase buluh) sulawesi selatan. Agroplantae. 7:1–7.

Harmini H, Fanindi A. 2020. Strategi Adaptasi Tanaman Pakan Ternak terhadap Perubahan Iklim ( Adaptation Strategy of Forage Crops to Climate Change ). Wartazoa. 30:201–210.

Harmini H, Sajimin S, Fanindi A, Husni A. 2020. Keragaan Agronomi Rumput Gajah (Pennisetum purpureum cv Taiwan) Hasil Irradiasi Sinar Gamma. JINTP. 18:62–66.

Hayes BJ, Cogan NOI, Pembleton LW, Goddard ME, Wang J, Spangenberg GC, Forster JW. 2013. Prospects for genomic selection in forage plant species. Plant Breed. 132:133–143.

Herman M. 2010. Aplikasi Teknik Rekayasa Genetik dalam Perbaikan Sumber Daya Genetik Tanaman untuk Ketahanan Cekaman Biotik. Bul Plasma Nutfah. 16:72–84.

Hetta M, Mussadiq Z, Gustavsson A, Swensson C. 2012. Effects of hybrid and maturity on performance and nutritive characteristics of forage maize at high latitudes , estimated using the gas production technique. Anim Feed Sci Technol [Internet]. 171:20–30. http://dx.doi.org/10.1016/j.anifeedsci.2011.09.015

IAEA. 2021. Mutant Variety Database. [place unknown]: https://mvd.iaea.org/.

Itoh Y, Crofts N, Abe M, Hosaka Y, Fujita N. 2017. Characterization of the endosperm starch and the pleiotropic effects of biosynthetic enzymes on their properties in novel mutant rice lines with high resistant starch and amylose content. Plant Sci. 258.

Kingston-Smith AH, Marshall AH, Moorby JM. 2013. Breeding for genetic improvement of forage plants in relation to increasing animal production with reduced environmental footprint. Animal [Internet]. 7:79–88. http://dx.doi.org/10.1017/S1751731112000961

Lestari E, Dewi I, Yunita R. 2015. Seleksi galur mutan padi Fatmawati tahan terhadap penyakit blas dan evaluasi karakter agronomi di rumah kaca dan di lahan sawah. Bul Plasma Nutfah. 21:79–88.

Lundqvista U, Franckowiak J, Forster B. 2011. Mutation Categories. In: Shu Q, Foster B, Nakagawa H, editors. Plant Mutat Breed Biotechnol. Vienna (AT): Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture International Atomic Energy Agency; p. 47–56.

Maleki M, Ghorbanpour M, Nikabadi S. 2019. In vitro screening of crop plants for abiotic stress tolerance. In: Wani SH, editor. Recent Approaches Omi Plant Resil to Clim Chang. [place unknown]: Springer Switzerland; p. 75–91.

Maluszynski M, Szarejko I, Maluszynsk J, Szurman-Zubrzycka M. 2017. Mutation Techniques. Encycl Appl Plant Sci. 2:215–228.

Manikanta CHLN, Goud B, Sowndarya K. 2020. Root System Architecture-A Key to Drought Tolerance. In: Adv Agric Biotechnol. [place unknown]: AkiNik Publications AkiNik; p. 24 hlm.

Manzanares C, Yates S, Ruckle M, Nay M, Studer B. 2016. TILLING in forage grasses for gene discovery and breeding improvement. N Biotechnol. 33:594–603.

Mba C. 2013. Induced mutations unleash the potentials of plant genetic resources for food and agriculture. Agronomy. 3:200–223.

Mejri S, Saidi M, Mabrouk Y, Belhadj O. 2018. Improving Faba Bean Crop for Biotic Stress Resistance Through Mutation Breeding Using Gamma Irradiation Technique (IAEA-CN--263). [place unknown]: International Atomic Energy Agency (IAEA).

Miao L Li, Li Y Ying, Zhang H Juan, Zhang H Ji, Liu X Lin, Wang J Yi, Chang X Ping, Mao X Guo, Jing R Lian. 2021. TaSnRK2.4 is a vital regulator in control of thousand-kernel weight and response to abiotic stress in wheat. J Integr Agric [Internet]. 20:46–54. http://dx.doi.org/10.1016/S2095-3119(19)62830-3

Mohapatra T, Robin S, Sarla N, Sheshasayee M, Singh A, Singh K. 2014. EMS induced mutants of upland rice variety Nagina22: generation and characterization. In: Indian Natl Sci Acad 80, 163. [place unknown].

Moura JCMS, Bonine CA V, Viana JOF, Dornelas MC, Mazzafera P. 2010. Abiotic and biotic stresses and changes in the lignin content and composition in plants. J Integr Plant Biol. 52:360–376.

Munasik, Sutrisno CI, Anwar S, Prayitno CH. 2012. The growth, yield and quality of elephant grass (Pennisetum purpureum) specific tolerant of acid soils by mutagenesis with ethylmethane sulfonate. J Anim Prod [Internet]. 14:87–91. http://www.animalproduction.net/index.php/JAP/article/view/367/336%0Ahttps://www.cabdirect.org/cabdirect/abstract/20133011522

Nuraida D. 2012. Pemuliaan Tanaman Cepat Dan Tepat Melalui Pendekatan Marka Molekuler. el–Hayah. 2:97–103.

Østrem L, Volden B, Larsen A. 2013. Morphology , dry matter yield and phenological characters at different maturity stages of × Festulolium compared with other grass species. Acta Agric Scand Sect B - Soil Plant Sci [Internet]. 63:531–542. http://dx.doi.org/10.1080/09064710.2013.819440

Pathirana R. 2011. Plant mutation breeding in agriculture. CAB Rev Perspect Agric Vet Sci Nutr Nat Resour. 6(November 2011):1–20.

Pecetti L, Annicchiarico P, Scotti C, Paolini M, Nanni V, Palmonari A. 2017. Effects of plant architecture and drought stress level on lucerne forage quality. Grass Forage Sci. 72:714–722.

Pérez-Jiménez M, Pérez-Tornero O. 2020. Improved salt-tolerance in Citrus macrophylla mutant rootstocks. Sci Hortic (Amsterdam). 259:1–9.

Pérez-Jiménez M, Tallón CI, Pérez-Tornero O. 2020. Inducing mutations in Citrus spp.: Sensitivity of different sources of plant material to gamma radiation. Appl Radiat Isot. 157:1–7.

Pirhofer-Walzl K, Rasmussen J, Høgh-Jensen H, Eriksen J, Søegaard K, Rasmussen J. 2012. Nitrogen transfer from forage legumes to nine neighbouring plants in a multi-species grassland. Plant Soil. 350:71–84.

PVTPP. 2021. Sistem informasi database varietas tanaman Kementrian Pertanian RI. aplikasi.pertanian.go.id.

Rahayu S, Dewi A, Yulidar Y, Wirnas D, Aswidinnoor H. 2013. Analisis stabilitas dan adaptabilitas beberapa galur padi dataran tinggi hasil mutasi induksi. J Ilm Apl Isot dan Radiasi. 9:81–90.

Resende, RMS, Casler, MD, Vilela de Resende M. 2013. Selection Methods in Forage Breeding: A Quantitative Appraisal. Crop Sci. 53:1925–1936.

Respati AN, Umami N, Hanim C. 2018. Growth and Production of Brachiaria brizantha cv . MG5 in Three Difference Regrowth Phase Treated by Gamma Radiation Dose. Trop Anim Sci J. 41:179–184.

Rios E, Blount A, Erickson J, Kenneth Quesenberry, Fredy Altpeter, Catherine Cellon and KK. 2013. Root and Shoot Characterization of Mutant Turf-Type Bahiagrasses. Int Turfgrass Soc Res J. 12(September 2015).

Roy AK, Malaviya DR, Kaushal P. 2016. Genetic improvement of fodder legumes especially dual purpose pulses. Indian J Genet Plant Breed. 76:608–625.

Sakata M, Seno M, Matsusaka H, Takahashi K, Nakamura Y, Yamagata Y. 2016. Development and evaluation of rice giant embryo mutants for high oil content originated from a high-yielding cultivar “Mizuhochikara.” Breed Sci. 66:425–433.

Shen XH, Jiang C, Zheng W, Feng P, Wang Q, Lai YC. 2020. Mutagen effect on the growth, physiology and microstructure of alfalfa (Medicago sativa l). Appl Ecol Environ Res. 18:3497–3510.

Shu Q, Forster B, Nakagawa H. 2012. Principles and Applications of Plant Mutation Breeding. In: Shu Q, Foster B, Nakagawa H, editors. Plant Mutat Breed Biotechnol. Vienna (AT): Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture International Atomic Energy Agency; p. 301-326.

Sobrizal S. 2017. Potensi Pemuliaan Mutasi untuk Perbaikan Varietas Padi Lokal Indonesia. J Ilm Apl Isot dan Radiasi. 12:23–36.

Soedjono S. 2003. Aplikasi mutasi induksi dan variasi somaklonal dalam pemuliaan tanaman. J Litbang Pertan. 22:70–78.

Stearns F, Fenster C. 2016. The effect of induced mutations on quantitative traits in Arabidopsis thaliana: Natural versus artificial conditions. Ecol Evol. 6:8366–8374.

Tai TH, Chun A, Henry IM, Ngo KJ, Burkart-Wako D. 2016. Effectiveness of sodium azide alone compared to sodium azide in combination with methyl nitrosurea for rice mutagenesis. Plant Breed Biotech. 4:453– 461.

Tasma IM. 2016. Pemanfaatan Teknologi Sekuensing Genom Untuk Mempercepat Program Pemuliaan Tanaman. J Penelit dan Pengemb Pertan. 34:159–168.

Tefera H, Kamara AY, Dashiell KE. 2009. Improvement in Grain and Fodder Yields of Early-Maturing Promiscuous Soybean Varieties in the Guinea Savanna of Nigeria. Crop Sci. 49:2037–2042.

Tejeda LHC, Viana VE, Maltzahn LE, Busanello C, Barros LM, da Maia LC, Costa de Oliveira A, Pegoraro C. 2020. Abiotic stress and self-destruction: ZmATG8 and ZmATG12 gene transcription and osmotic stress responses in maize. Biotechnol Res Innov. 3:1–9.

Trethewey JAK. 2015. Crop architecture and light interception in forage rape ( Brassica napus L .) grown for seed. Agron New Zeal. 39:47–57.

Tu Y, Jiang A, Gan L, Hossain M, Zhang J, Peng B, Xiong Y, Song Z, Cai D, Xu W, Zhang J, He Y. 2014. Genome duplication improves rice root resistance to salt stress. Rice. 7:15. http://dx.doi.org /10.1186/s12284-014-0015-4.

Tucak M, Popovič S, Čupič T, Španič V, Meglič V. 2013. Raudonojo dobilo (Trifolium pratense L.) selekciniu populiaciju ir veisliu derlingumas, pašaro kokybes bei morfologiniu požymiu ivairavimas. Zemdirbyste. 100:63–70.

Turk M, Albayrak S. 2019. Effect of harvesting stages on forage yield and quality of different leaf types pea cultivar. Turkish J F Crop. 17:111–114.

Ulukapi K, Ozmen S. 2018. Study of the effect of irradiation (60 Co) on M 1 plants of common bean ( Phaseolus vulgaris L.) cultivars and determined of proper doses for mutation breeding. J Radiat Res Appl Sci. 11:157–161.

Vardhan P, Shukla L. 2017. Gamma irradiation of medicinally important plants and the enhancement of secondary metabolite production. Int J Radiat Biol. 93:767–979.

Vasiljevic S, Milic D, Mikic A. 2009. Chemical attributes and quality improvement of forage legumes. Biotechnol Anim HusbandryBiotehnologija u Stoc. 25:493–504.

Van Harten A. 1998. Mutation breeding:theory and practical applications. Cambridge Univ Press.

Van Minnebruggen A, Van Bockstaele E, Rohde A, Cnops G. 2011. Morphological variation of plant architecture in red clover (Trifoliumpra tense). Commun Agric Appl Biol Sci. 76:215–2

Viana V, Pegoraro C, Busanello C, de Oliveira A. 2019. Mutagenesis in rice: the basis for breeding a new super plant. Frontiers in Plant Science. Front Plant Sci. 10.

Vinutha KS, Anil Kumar GS, Blümmel M, Srinivasa Rao P. 2017. Evaluation of yield and forage quality in main and ratoon crops of different sorghum lines. Trop Grasslands-Forrajes Trop. 5:40–49.

Wahyono T, Nugrahini S, Hardani W, Ansori D, Handayani T. 2018. Profil kecernaan in vitro tanaman sorgum hasil. In: Pros Semin Nas APISORA 2018. [place unknown]; p. 9–18.

Wahyono T, Sugoro I, Jayanegara A, Wiryawan KG, Astuti DA. 2019. Nutrient Profile and In vitro Degradability of New Promising Mutant Lines Sorghum as Forage in Indonesia. Adv Anim Vet Sci. 7:810–818.

Wang K, Liu Y, Teng F, Cen H, Yan J, Lin S, Li D, Zhang W. 2021. Heterogeneous expression of Osa-MIR156bc increases abiotic stress resistance and forage quality of alfalfa. Crop J [Internet].(xxxx):1-10 [in press]. https://doi.org/10.1016/j.cj.2020.11.009

Warman B, Sobrizal S, Suliansyah I, Swasti E, Syarif A. 2015. Perbaikan genetik kultivar padi beras hitam lokal sumatera barat melalui mutasi induksi. J Ilm Apl Isot dan Radiasi. 11:125–136.

Xu J, Shi S, Wang L, Tang Z, Lv T, Zhu X. 2017. OsHAC4 is critical for arsenate tolerance and regulates arsenic accumulation in rice. New Phytol. 2015:1090–1101.

Yunus A, Hartati S, Brojokusumojo R. 2017. Performance of Mentik Wangi rice generation M1 from the results of gamma ray irradiation. Agrosains. 19:6–14.

Zhang Y, Zhang D. 2007. Asexual and sexual reproductive strategies in clonal plants. Front Biol China. 2:256–262.

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