The demand for rice in Indonesia continues to increase but production has decreased. Efforts that can be made are the use of local varieties of mentik wangi rice. Mentik wangi rice has the disadvantages of long life, high stems, and low crop production. As a solution, plant breeding is carried out in the form of mutation by giving gamma irradiation which can improve unwanted genetic traits and produce superior varieties with the dose used of 200 gray. This study aims to evaluate the yield potential of promising mutant strains with 200 gray gamma irradiation on mentik wangi rice and get mutant strains that have superior criteria for short-stemmed, short-lived, and high-yielding. This research was conducted in the rice field of Ngampel Hamlet, Gentungan Village, Mojogedang, Karanganyar, Central Java. The research was conducted in June-October 2023. The design used was a Randomized Complete Group Design (RCBD) with a single factor, namely strains consisting of 14 mutant strains and 1 control strain with 3 repetitions. The results of observations were analyzed by Analysis of Variance (ANOVA) at the 5% level and continued with Duncan Multiple Range Test (DMRT) at the 5% level. All tested strains produced the expected superior criteria, namely short stem, short age, and high productivity.

1. Donggulo CV, Lapanjang IM, Made U. Pertumbuhan dan hasil tanaman padi (Oryza sativa L.) pada berbagai pola jajar legowo dan jarak tanam. J Ilmu-ilmu Pertanian. 2017;24(1):27-35.
2. Collard BC, Beredo JC, Lenaerts B, et al. Revisiting rice breeding methods, evaluating rapid generation advance (RGA) use for routine rice breeding. Plant Prod Sci. 2017;20(4):337-52.
3. Cing JM, Seno DSH, Santoso TJ. Identification of aroma gene (mutated badh2) and aroma properties on aromatic BC5 F2 ciherang. Curr Biochem. 2015;2(1):42-51.
4. Abdullah B, Prajitno KS, Mudjisihono R. Keragaan beberapa genotipe padi menuju perbaikan mutu beras. Subang (ID): Balai Besar Penelitian Tanaman Padi Sukamandi; 2006.
5. Meliala JHS, Basuki N, Soegianto A. Pengaruh iradiasi sinar gamma terhadap perubahan fenotipik tanaman padi gogo (Oryza sativa L.). J Produksi Tanaman. 2016;4(7):585-94.
6. Yunus A, Hartati S, Brojokusumojo RDK. Performance of mentik wangi rice generation m1 from the results of gamma ray irradiation. J Agrosains. 2017;19(1):6-14.
7. Supriyatna A, Khoerunnisa AS, Maulidina A, Maulidina I, Azizah IDMN. Efek induksi mutasi radiasi gamma terhadap pertumbuhan fisiologis tanaman kedelai (Glycine max (L.) Merrill). J Riset Rumpun Ilmu Tanaman. 2023;2(2):68-76.
8. Fadli N, Syarif Z, Satria B, Akhir N. The effect of gamma cobalt-60 ray irradiation on cultivar growth in taro white (Xanthosoma sagittifolium L.). Int J Environ Agric Biotechnol. 2018;3(6):2020-5.
9. Mabakotawasi S, Sutardi, Istiqomah. Uji efektifitas penggunaan ma-11 terhadap pertumbuhan tanaman tomat (Solanum lycopersicum Miller). J Biolearning. 2022;9(2):14-6.
10. Yuliantika D, Sudharmawan AAK, Sudika IW. Peningkatan karakter kuantitatif padi beras merah (Oryza sativa L.) genotipe g16 hasil induksi mutasi dengan iradiasi sinar gamma 200 gy. J Ilm Mahasiswa Agrokomplek. 2023;2(2):228-35.
11. Kuzmanović L, Giovenali G, Ruggeri R, et al. Small “nested” introgressions from wild Thinopyrum species confer effective resistance to Fusarium diseases and positively impact durum wheat yield potential. Plants. 2021;10(3):1-16.
12. Nurdin, Ichsan CN, Bakhtiar. Uji tanaman padi hasil persilangan varietas lokal dengan irbb-27 terhadap pertumbuhan dan ketahanan hawar daun bakteri. J Ilm Mahasiswa Pertanian Unsyiah. 2016;1(1):227-38.
13. Suliartini NWS, Adekayanti S, Sudharmawan AKK, et al. Effect of mutation induction on vegetative and generative characters of g16 rice (Oryza sativa L.). J Res Sci Educ. 2023;9(5):3790-9.
14. Sadimantara GR, Nuraida W, Suliartini NWS, Muhidin. Evaluation of some new plant types of upland rice (Oryza sativa L.) lines derived from cross-breeding for the growth and yield characteristics. IOP Conf Ser Earth Environ Sci. 2018;157:1-6.
15. Nisa EK, Purwanto E, Parjanto. Morphological and physiologic response of black rice M5 gamma ray irradiation to drought stress. IOP Conf Ser Earth Environ Sci. 2022;1107:1-9.
16. Harianja DH, Karti PDMH, Prihantoro I. Morfologi mutan alfalfa (Medicago sativa L.) hasil iradiasi sinar gamma pada cekaman kering. J Ilmu Nutrisi Teknologi Pakan. 2021;19(2):59-65.
17. Rosmala A, Khumaida N, Sukma D. Effect of gamma irradiation on callus of Handeuleum (Graptophillum pictum L. Griff) Kalimantan and Papua accession. J Hort Indones. 2022;13(1):23-8.
18. Indriatama WM, Trikoesoemaningtyas, Aisyah SI, et al. Pendugaan ragam genetik dan heritabilitas karakter agronomi gandum (Triticum aestivum L.) hasil berbagai perlakuan teknik iradiasi sinar gamma. J Ilm Aplikasi Isotop Radiasi. 2016;12(2):79-88.
19. Leon AP, Ramchander S, Kumar K, Muthamilarasan M, et al. Assessment of efficacy of mutagenesis of gamma-irradiation in plant height and days to maturity through expression analysis in rice. PLoS One. 2021;16(1):1-20.
20. Afdila D, Ezward C, Haitami A. Karakter tinggi tanaman, umur panen, jumlah anakan, dan berat panen pada 12 genotipe padi lokal Kabupaten Kuantan Singingi. J Sains Agro. 2021;6(1):1-9.
21. Gowthami R, Vanniarajan C, Souframanien J, Pillai MA. Effect of gamma rays and electron beam on various quantitative traits of rice (Oryza sativa L.) in M1 generation. Adv Life Sci. 2016;5(5):1876-82.
22. Purwanto E, Nandariyah N, Yuwono SS, et al. Induced mutation for genetic improvement in black rice using gamma rays. AGRIVITA J Agric Sci. 2019;41(2):213-20.
23. Irmayanti, Haris A, Saida. Karakteristik padi lokal ase banda generasi m5 hasil radiasi sinar gamma. J AgrotekMas. 2023;4(3):323-30.
24. Boceng A, Haris A, Tjoneng A. Karakter mutan padi lokal ase banda hasil irradiasi sinar gamma. J Agrokompleks. 2017;16(1):42-5.
25. Piri I, Babayan M, Tavassoli A, et al. Gamma irradiation mediated agriculture. Adv J Microbiol Res. 2021;15(1):1-6.
26. Jaenuristy DN, Azizah E, Samaullah MY, et al. Keragaan agronomi galur-galur padi (Oryza sativa L.) dengan potensi hasil tinggi di dataran rendah Sukamandi. J Agrikultura. 2022;33(2):189-99.
27. Ma’sum FQA, Kurniasih B, Ambarwati E. Pertumbuhan dan hasil padi sawah (Oryza sativa L.) pada beberapa takaran kompos jerami dan zeolite. J Vegetalika. 2016;5(3):29-40.
28. Suryani IS, Wahyono D. Korelasi pertumbuhan dan hasil tanaman padi (Oryza sativa L.) dengan teknik penanaman dan dosis pupuk organik. J Agrotechbiz. 2017;4(1):9-16.
29. Sibarani IB, Lahay RR, Hanafiah DS. Respon morfologi tanaman kedelai (Glycine max (L.) Merrill) varietas anjasmoro terhadap beberapa iradiasi sinar gamma. J Online Agroekoteknologi. 2015;3(2):515-26.
30. Tumanggor GE, Iswahyudi, Mardiyah A. Pertumbuhan, produksi dan karakter genetik padi kultivar sileso generasi m-2 hasil iradiasi sinar gamma. J Penelit Agrosamudra. 2022;9(2):31-40.
31. Masruroh F, et al. Improvement of rice (Oryza sativa L.) var. Ciherang and cempo ireng productivity using gamma irradiation. J Agric Sci Technol B. 2016;6(5):289-94.
32. Puspitasari HM, Kurniasih B, Indradewa D. The yield of m7 mentik wangi rice irradiated with several doses of gamma rays under drought stress. IOP Conf Ser Earth Environ Sci. 2022;985(1):1-9.