Effects of seed soaking with plant growth regulators combination on the aggregation ability of shallot from seeds
Retno Pangestuti(1*), Endang Sulistyaningsih(2), Budiastuti Kurniasih(3), Rudi Hari Murti(4)
(1) National Research and Innovation Agency
(2) Faculty of Agriculture, Universitas Gadjah Mada
(3) Faculty of Agriculture, Universitas Gadjah Mada
(4) Faculty of Agriculture, Universitas Gadjah Mada
(*) Corresponding Author
Abstract
The true seed of shallot (TSS) is an alternative technology to boost high-quality seeds, farming cost efficiency, and shallot productivity in Indonesia. Despite the advantages of TSS, including extended shelf life and lower seed requirements, farmer and consumer acceptance remains limited due to the genetic and physiological constraints leading to single and large-sized bulbs, as an effect of low aggregation ability. This caused shallot bulbs from TSS to have a low price and were not suitable for use as seed bulbs. This research addresses challenges in shallot (Allium cepa L. Aggregatum group) production from TSS by investigating the impact of various plant growth regulators (PGRs) treatments and different soaking time on shallot growth and aggregation ability of 'Tuk Tuk' planting from TSS. The study in Yogyakarta employed a split-plot randomized block design from July to November 2018. The main plot varied the PGRs combination (9 treatment), while the subplot used the soaking time of 4 hours and 12 hours. The results indicated that a GA₃ concentration of 100 ppm, in synergy with NAA at 50 ppm for 12 hours, effectively enhanced aggregation compared to another treatment. Notably, the 'Tuk Tuk' shallot, characterized by low aggregation ability, demonstrated improved potential through seed treatment by PGRs, which could raise the number of bulbs from one to an average of two bulbs per plant. This study enhanced shallot aggregation ability, providing valuable insights for research and developing shallot production from true seeds in Indonesia.
Keywords
Full Text:
PDFReferences
Adin, A., Firdaus, R., Haerudin, H., Rokhman, F., and Harpenas, A. (2023). A Review: TSS (True Shallot Seed) Development in Indonesia and Its Health Benefit. In Proceedings of the International Symposium Southeast Asia Vegetable 2021 (SEAVEG 2021), Springer Nature, (23), pp. 208.
Adiyoga, W. (2023). Assessing True Shallot Seed (TSS) performance and farmers’ perceptions of its innovation attributes. In IOP Conference Series: Earth and Environmental Science. IOP Publishing., 1230(1), pp. 012191.
Cárdenas-Aquino, M.D.R., Camas-Reyes, A., Valencia-Lozano, E., López-Sánchez, L., Martínez-Antonio, A. and Cabrera-Ponce, J.L., 2023. The Cytokinins BAP and 2-iP Modulate Different Molecular Mechanisms on Shoot Proliferation and Root Development in Lemongrass (Cymbopogon citratus). Plants, 12(20), pp. 3637.
Dalai, S., Singh, M.K., Singh, K.V., Kumar, M., Malik, S., and Kumar, V. (2015). Effect of foliar application of GA3 and NAA on growth, flower-ing yield and yield attributes of cucumber [Cucumis Sativus L.]. Annals of Horticulture, 8(2), pp. 181−194.
Degewione, A., Alamerew, S., and Tabor, G. (2011). Genetic Variability and Association of Bulb Yield and Related Traits in Shallot (Allium cepa var. Aggregatum DON.) In Ethiopia. Int. J. Agric. Res., 6(7), pp. 517–536.
Deswiniyanti, N. W., and Lestari, N. K. D. (2020). In Vitro Propagation of Lilium longiflorum Bulbs Using NAA and BAP Plant Growth Regulator Treatment. KnE Life Sciences, 5(2).
Esan A ., Olaiya, C., Anifowose, L., Lana, L., Omolekan, T. T., Fagbami, O., and Adeyemi, H. R. (2020). Effect of plant growth-promoting rhizobacteria and gibberellic acid on salt stress tolerance in tomato genotypes. African Crop Sci. Journal., 28, pp. 341–362.
Ghani, M.A., Amjad, M., Iqbal, Q., Nawaz, A., Ahmad, T., Haffez, O.B.A. (2013). Efficacy of plant growth regulators on sex expression, earliness and yield components in bitter gourd. Pakistan Journal of Life and Social Sciences, 11(3), pp. 218−224.
Hosseini, M. S., Zahedi, S. M., Hoveizeh, N. F. , Li, L., Rafiee, M., and Farooq, M. (2020). Improving seed germination and seedling growth of guava under heat and osmotic stresses by chemical and hormonal seed treatments. Bragantia, 79, pp. 512−524.
Irsyad, E.P., Yoesdiarti, A., and Miftah, H. (2018). Consumer Perceptions and Preferences Againts Attributes Of Commercial Vegetable Quality In Modern Market. Jurnal Agribis., 4(2), pp. 1−7.
Kandel, S.L., Herschberger, N., Kim, S.H., and Doty, S.L. (2015). Diazotrophic endophytes of poplar and willow for growth promotion of rice plants in nitrogen‐limited conditions. Crop Science, 55(4), pp. 1765−1772.
Khan, A.L., Hussain, J., Al-Harrasi, A., Al-Rawahi, A., and Lee, I.J. (2015). Endophytic fungi: resource for gibberellins and crop abiotic stress resistance. Critical reviews in biotechnology, 35(1), pp. 62−74.
Krontal, Y., Kamenetsky, R., and Rabinowitch, H.D. (1998). Lateral Development and Florigenesis of a Tropical Shallot—A Comparison with Bulb Onion. International Journal of Plant Science, 159, pp. 57−64.
Kudoyarova, G.R., Melentiev, A.I., Martynenko, E.V., Timergalina, L.N., Arkhipova, T.N., Shendel, G.V., Kuz'mina, L.Y., Dodd, I.C., and Veselov, S.Y. (2014). Cytokinin producing bacteria stimulate amino acid deposition by wheat roots. Plant Physiology and Biochemistry, 83, pp. 285−291.
Liu, P.P., Montgomery, T.A., Fahlgren, N., Kasschau, K.D., Nonogaki, H., and Carrington, J.C. (2007). Repression of Auxin Response Factor10 by microRNA160 is critical for seed germination and post‐germination stages. The Plant Journal, 52(1), pp. 133−146.
Liu, Y., Fang, Y., Huang, M., Jin, Y., Sun, J., Tao, X., Zhang, G., He, K., Zhao, Y., and Zhao, H. (2015). Uniconazole-induced starch accumulation in the bioenergy crop duckweed (Landoltia punctata) I: transcriptome analysis of the effects of uniconazole on chlorophyll and endogenous hormone biosynthesis. Biotechnology for biofuels, 8(1), pp. 1−12.
Mena, M., Cejudo, F.J., Isabel-Lamoneda, I., and Carbonero, P. (2002). A role for the DOF transcription factor BPBF in the regulation of gibberellin-responsive genes in barley aleurone. Plant Physiology, 130(1), pp. 111−119.
Miransari, M. and Smith, D. L. (2014). Plant hormones and seed germination. Environ. Exp. Bot., 99, pp. 110–121.
Oteino, N., Lally, R.D., Kiwanuka, S., Lloyd, A., Ryan, D., Germaine, K. J., and Dowling, D. N. (2015). Plant growth promotion induced by phosphate solubilizing endophytic Pseudomonas isolates. Front. Microbiol., 6, pp. 745.
Pachon, N.M., Mutimawurugo, M.C., Heynen, E., Sergeeva, L., Benders, A., Blilou, I., Hilhorst, H.W., and Immink, R.G. (2018). Role of Tulipa gesneriana Teosinte Branched1 (TgTB1) in the control of axillary bud outgrowth in bulbs. Plant reproduction, 31(2), pp. 145−157.
Pangestuti, R. and Sulistyaningsih, E. (2011). Potency of True Seed Shallot ( TSS) as the material of shallot propagation in Indonesia Pros. Semiloka Nas. Agro-Innovation Support for Empowerment. Farmers, pp. 258–266.
Pangestuti, R. (2022). Bulb Aggregation and Productivity of Shallot (Allium Cepa L. Aggregatum Group) Planting from Seeds. Doctoral dissertation. Universitas Gadjah Mada.
Perković, J., Major, N., Ban, D., Cvitan, D., and Ban, S. G. (2021). Shallot species and subtypes discrimination based on morphology descriptors. Plants, 10(1), pp. 1–18.
Rabinowitch, H. D., and Kamenetsky, R. (2002). Shallot (Allium cepa, Aggregatum group). In: Allium Crop Science: Recent Advances. CABI: Wallingford UK, pp. 409–430.
Rademacher, W. (2015). Plant growth regulators: backgrounds and uses in plant production. Journal of plant growth regulation, 34, pp. 845−872.
Rajalakshmi, K. and Banu, N. (2015). Extraction and estimation of chlorophyll from medicinal plants. International Journal of Science and Research, 4(11), pp. 209−212.
Robinson, S., Burian, A., Couturier, E., Landrein, B., Louveaux, M., Neumann, E. D., Peaucelle, A., Weber, A., and Nakayama, N. (2013). Mechanical control of morphogenesis at the shoot apex. Journal of experimental botany, 64(15), pp. 4729−4744.
Singh, K., Rathore, P., and Gumber, R.K. (2015). Impact of varied levels and seed soaking period of water on seedling emergence sown with Bt cotton planter. J. Cotton Res. Dev, 29, pp. 53−56.
Sudaryono, T. (2018). Effect of plant growth regulator on red onion cultivation from true seed shallot (TSS). J.PAL., 9 1), pp. 39−44.
Sukifto, R., Nulit, R., Kong, Y. C., Sidek, N., Mahadi, S. N., Mustafa, N., and Razak, R. A. (2020). Enhancing germination and early seedling growth of Malaysian indica rice (Oryza sativa L.) using hormonal priming with gibberellic acid (GA3). AIMS Agric. Food, 5, pp. 649–465.
Sun, T. P. (2010). Gibberellin-GID1-DELLA: A pivotal regulatory module for plant growth and development. Plant Physiol., 154, pp. 567–570.
Wahyuni, A.N., Irmadamayanti, A., and Padang, I.S. (2021). The effect of gibberellins soaking duration on germination frequency and growth of true shallot seed in the nursery. In IOP Conference Series: Earth and Environmental Science, IOP Publishing, 762(1), pp. 012072.
Waluyo, N., Wicaksana, N., Anas, A., and Hidayat, I.M. (2021). Genetic diversity and heritability of 12 shallot genotypes (Allium cepa L. var Aggregatum) in the highlands. Jurnal Agro, 8(1), pp. 1−13.
Yamazaki, H., Shiraiwa, N., Itai, A., and Honda, I. (2015). Involvement of gibberellins in the regulation of tillering in welsh onion (Allium fistulosum L.). The Horticulture Journal, 84(4), pp. 334–341.
Yang, G. X., Jan, A., Shen, S. H., Yazaki, J., Ishikawa, M., Shimatani, Z., Kishimoto, N., Kikuchi, S., Matsumoto, H., and Komatsu, S. (2004). Microarray analysis of brassinosteroids and gibberellinregulated gene expression in rice seedlings. Mol. Genet. Genomics, 271, pp. 468–478
DOI: https://doi.org/10.22146/ipas.90993
Article Metrics
Abstract views : 1937 | views : 1100Refbacks
- There are currently no refbacks.
Ilmu Pertanian (Agricultural Science) ISSN 0126-4214 (print), ISSN 2527-7162 (online) is published by Faculty of Agriculture Universitas Gadjah Mada collaboration with Perhimpunan Sarjana Pertanian Indonesia (PISPI) and licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.