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IMPROVED EARLY SEASON MANAGEMENT OF SUB1 RICE VARIETIES ENHANCES POST-SUBMERGENCE RECOVERY AND YIELD

Published online by Cambridge University Press:  10 January 2018

NINO P. M. BANAYO ,
RANEE C. MABESA-TELOSA ,
SUDHANSHU SINGH  and
YOICHIRO KATO
NINO P. M. BANAYO
Affiliation:
International Rice Research Institute, Los Baños, Philippines
RANEE C. MABESA-TELOSA
Affiliation:
International Rice Research Institute, Los Baños, Philippines
SUDHANSHU SINGH
Affiliation:
International Rice Research Institute, Los Baños, Philippines
YOICHIRO KATO*
Affiliation:
International Rice Research Institute, Los Baños, Philippines
*
Corresponding author. Email: y.kato@irri.org; International Rice Research Institute, DAPO Box 7777, Metro Manila, Philippines.
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Summary

More than 10 Sub1 rice varieties carrying the submergence-tolerance gene have been released for flood-prone environments in tropical Asia. Improved management practices have been shown to enhance yields of these varieties. The objective of this study was to dissect the growth response of IR64-Sub1 to integrated crop management in a flash flood at the late vegetative stage. Field experiments were conducted at the International Rice Research Institute, Philippines in the dry and wet seasons of 2013. Complete submergence was imposed for 14 days starting at 37 days after transplanting. Integrated management practice (IMP) consisting of: (i) application of fertilizer (compared with no fertilizer use in conventional practice), (ii) use of lower seeding rate (400 vs. 800 kg ha−1) in the nursery bed, (iii) use of slightly older seedling for transplanting (30 vs. 18 day-old), and (iv) higher planting density (33.3 vs. 25.0 hills m−2) gave yields higher by 8–87% compared with the conventional practice (1.3–2.4 t ha−1) in both seasons. This was attributable to higher shoot biomass after water recession, more tillers m−2, greater leaf area expansion and shoot biomass accumulation during the recovery period, and higher filled-grain percentage at maturity. The improved management had no positive effect on panicle formation, spikelets panicle−1, and harvest index since stress was imposed at the transition period between vegetative and reproductive phases. Our results suggest the appropriate nursery management, for submergence-resilient seedlings to further alleviate damage caused by flash floods and increase the yield of Sub1 varieties in flood-prone rainfed lowlands.

Keywords

DAT, Days after transplantingDS, Dry seasonFMP, Farmer's management practiceIMP, Integrated management practiceWS, Wet season%NSC, Concentrations of non-structural carbohydrate
Type
Research Article
Information
Experimental Agriculture , Volume 55 , Issue 1 , February 2019 , pp. 105 - 116
Copyright
Copyright © Cambridge University Press 2018 

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References

REFERENCES

Bailey-Serres, J., Fukao, T., Ronald, P. C., Ismail, A. M., Heuer, S. and Mackill, D. J. (2010). Submergence tolerant rice: SUB1’s journey from landrace to modern cultivar. Rice 3:138147.Google Scholar
Bhowmick, M. K., Dhara, M. C., Singh, S., Dar, M. H. and Singh, U. S. (2014). Improved management options for submergence-tolerant (Sub1) rice genotype in flood-prone rainfed lowlands of West Bengal. American Journal of Plant Sciences 5:1423.Google Scholar
Colmer, T. D., Armstrong, W. Greenway, H., Ismail, A. M., Girk, G. J. D. and Atwell, B. J. (2014). Physiological mechanisms in flooding tolerance of rice: Transient complete submergence and prolonged standing water. Progress in Botany 75:255307.Google Scholar
Ella, E. S. and Ismail, A. M. (2006). Seedling nutrient status before submergence affects survival after submergence in rice. Crop Science 46:16731681.Google Scholar
Fukao, T., Xu, K., Ronald, P. C. and Bailey-Serres, J. (2006). A variable cluster of ethylene response factor-like genes regulates metabolic and developmental acclimation responses to submergence in rice. The Plant Cell 18:20212034.Google Scholar
Haefele, S. M., Kato, Y. and Singh, S. (2016). Climate ready rice: Augmenting drought tolerance with best management practices. Field Crops Research, 190:6069.Google Scholar
Ismail, A. M., Ella, E. S., Vergara, G. V. and Mackill, D. J. (2009). Mechanisms associated with tolerance to flooding during germination and early seedling growth in rice (Oryza sativa). Annals of Botany 103:197209.Google Scholar
Kato, Y., Collard, B. C. Y., Septiningsih, E. M. and Ismail, A. M. (2014). Shoot growth and other traits associated with tolerance of stagnant flooding in rice. AoB PLANTS 6:plu058.Google Scholar
Lafitte, H. R., Guan, Y. S., Shi, Y. and Li, Z. K. (2007). Whole plant responses, key processes, and adaptation to drought stress: The case of rice. Journal of Experimental Botany 58:169175.Google Scholar
Lampayan, R. M., Faronilo, J. E., Tuong, T. P., Espiritu, A. J., de Dios, J. L., Bayot, R. S., Bueno, C. S. and Hosen, Y. (2015). Effects of seedbed management and delayed transplanting of rice seedlings on crop performance, grain yield, and water productivity. Field Crops Research 183:303314.Google Scholar
Lilley, J. M. and Fukai, S. (1994). Effect of timing and severity of water deficit on four diverse rice cultivars: III. Phenological development, crop growth and grain yield. Field Crops Research 37:225234.Google Scholar
Mackill, D. J., Ismail, A. M., Singh, U. S., Labios, R. V. and Paris, T. R. (2012). Development and rapid adoption of submergence-tolerant (Sub1) rice varieties. Advances in Agronomy 115:303356.Google Scholar
Manzanilla, D., Singh, R. K., Kato, Y. and Johnson, D. E. (2016). Climate-Ready Technologies: Combating Poverty by Raising Productivity in Rainfed Rice Environments in Asia. 204. Los Baños, Philippines: International Rice Research Institute. Google Scholar
Mitchell, J. H., Siamhan, D., Wamala, M. H., Risimeri, J. B., Chinyamakobvu, E., Henderson, S. A. and Fukai, S. (1998). The use of seedling leaf death score for evaluation of drought tolerance of rice. Field Crops Research 55:129139.Google Scholar
Palada, M. and Vergara, B. S. (1972). Environmental effect on the resistance of rice seedlings to complete submergence. Crop Science 12:209212.Google Scholar
Panda, M. M., Reddy, M. D. and Sharma, A. R. (1991). Yield performance of rainfed lowland rice as affected by nursery fertilization under conditions of intermediate deepwater (15–50 cm) and flash floods. Plant and Soil 132:6571.Google Scholar
Panda, D., Sharma, S. G. and Sarkar, R. K. (2008). Chlorophyll fluorescence parameters, CO2 photosynthetic rate and regeneration capacity as a result of complete submergence and subsequent re-emergence in rice (Oryza sativa L.). Aquatic Botany 88:127133.Google Scholar
Pasuquin, E., Lafarge, T. and Tubana, B. (2008). Transplanting young seedlings in irrigated rice fields: Early and high tiller production enhanced grain yield. Field Crops Research 105:141155.Google Scholar
Sarangi, S. K., Maji, B., Singh, S., Burman, D., Mandal, S.D., Sharma, D. K., Singh, U. S., Ismail, A. M. and Haefele, S. M. (2015). Improved nursery management further enhances the productivity of stress-tolerant rice varieties in coastal rainfed lowlands. Field Crops Research 174:6170.Google Scholar
Sarangi, S. K., Maji, B., Singh, S., Sharma, D. K., Burman, D., Mandal, S.D., Singh, U. S., Ismail, A. M. and Haefele, S. M. (2016). Using improved variety and management enhances rice productivity in stangnant flood-affected tropical coastal zones. Field Crops Research 190:7081.Google Scholar
Singh, S., Mackill, D. J. and Ismail, A. M. (2009). Responses of SUB1 rice introgression lines to submergence in the field: Yield and grain quality. Field Crops Research 113:1223.Google Scholar
Singh, S., Mackill, D. J. and Ismail, A. M. (2014). Physiological basis of tolerance to complete submergence in rice involves genetic factors in addition to the SUB1 gene. AoB PLANTS 6:plu060.Google Scholar
Singh, U. S., Dar, M. H., Singh, S., Zaidi, N. W., Bari, M. A., Mackill, D. J., Collard, B. C. Y., Singh, V. N., Singh, J. P., Reddy, J. N., Singh, R. K. and Ismail, A. M. (2013). Field performance, dissemination, impact and tracking of submergence tolerant (Sub1) rice varieties in South Asia. SABRAO Journal 45:112131.Google Scholar
Winkel, A., Colmer, T. D., Ismail, A. M. and Pedersen, O. (2013). Internal aeration of paddy field rice (Oryza sativa) during complete submergence - importance of light and floodwater O2. New Phytologist 197:11931203.Google Scholar
Yamada, N. (1959). Physiological basis of resistance of rice plant against overhead flooding. Bulletin of the National Institute of Agricultural Sciences 8:1110.Google Scholar