Evaluation of Drought response in Some Rice Mutant Lines Using Stress Tolerance Indices

Document Type : Research Article

Authors

1 Islamic Azad University, Rasht

2 Rice Research Institute of Iran

Abstract

Introduction
Drought is a major problem that limits the adoption of high-yielding rice varieties in drought-prone rainfed rice environments. To improve crop productivity, it is necessary to understand the mechanism of plant responses to drought conditions with the ultimate goal of improving crop performance in the vast areas of the world where rainfall is limiting or unreliable. Safaei Chaeikar et al. (2008) reported that MP, GMP, HM and STI indices, which showed the highest correlation with grain yield under both optimal and stress conditions, can be used as the best indices to introduce drought-tolerant genotypes in rice breeding programs. They also were introduced Nemat, Sepidrood, IR64, IR50 and Bejar genotypes as tolerant varieties. The present study was conducted to determine how drought affects grain yield in rice mutant lines and also to test this hypothesis in order to identify the most suitable indices/genotypes.
Materials and Methods
A field trial was conducted at Iranian Rice Research Centers in North of Iran, Rasht (latitude 37◦28', longitude 49◦28'E and altitude 7m below the sea level), during the 2014-2015 growing season. The seeds were sown in a nursery on the 10 May and 25 day old seedlings were transplanted to the field. Two separately experiment was carried out under reproductive stage drought stress and controlled conditions based on randomized complete block design with three replications, in four-row plots of three m length. Transplanting was done using 1 seedling per hill; at hill spacing of 25 cm × 25 cm. 18 rice genotypes were consisted 14 M5 mutant lines and their four parental cultivars.
Results and Discussion
Analysis of variance indicated significant effects of drought stress, genotype and interaction effects of two factors on grain yield, plant height, flag leaf area, tiller number and grain fertility percentage. Drought stress at reproductive stage caused reduction in grain yield (59.47%), grain fertility percentage (19.08%), plant height (9.35%), flag leaf area (8.59%) and panicle length (1.61%). Different drought indices probably measure similar aspect of drought tolerance/resistance. Significant yield reduction was observed under drought stress in majority of the rice genotypes studied. Drought tolerance indices were varied significantly indicating genotypic variability. Selection based on these stress tolerance indices will results in identification of drought tolerant genotypes for rainfed ecosystems. The stress tolerance index (STI), mean productivity (MP), geometric mean productivity (GMP) and harmonic mean (HM) were superior in genotype indicating that they can be used as alternative for each other to select drought tolerant genotypes with high yield performance in both stress and non-stress conditions. To determine the most desirable drought tolerance criteria, the correlation coefficients between Yp, Ys and other quantitative indices of drought tolerance were calculated. The results indicated that there were positive and significant correlations among Yp and MP, GMP, STI and HM. There were also significant and positive correlation between Ys and YI,HM,GMP,YSI,STIandMP. In this experiment, the principal component analysis was performed on eight indices and grain yield under stress and non-stress in 18 rice genotypes. Results showed that the first two components explained 82.8% and 17% of total variation, respectively. The relationship between principal components and studied indices showed that the higher values of first and the lower values of second components were related to drought tolerance and sensitivity to stress, respectively. Selection based on a combination of indices may provide a more useful criterion for improving rice drought-tolerant lines; therefore, studies of correlation coefficients are useful in finding out the degree of overall linear association between any two attributes. According to these drought stress indices, G1, G2, G3, G4 and G5 (M5 mutant lines of local lanrace, Tarom) and (M5 mutant line of Hashemi) were as drought tolerant and G14 (mutant lines of Khazar), G15 (Hashemi), G16 (Khazar) and G17 (Tarom) were sensitive to drought stress.
Conclusions
Results of present study showed that MP, GMP, YI and STI are best indices for selecting and specifying of rice tolerant genotypes in arid areas. The use of mutation caused drought resistant on the progenies and the above lines can be used in a project of introduction of drought tolerant rice varieties.

Keywords


1. Bouslama, M., and Schapaugh, W. T. 1984. Stress tolerance in soybean. Part I: Evaluation of three screening techniques for heat and drought tolerance. Crop Science 24: 933-937.
2. Davatgar, N., Neishabouri, M. R., Sepaskhah, A. R., and Soltan, A., 2009. Physiological and morphological responses of rice (Oryza sativa L.) to varying water stress management strategies. International Journal of Plant Production 3: 19-32.
3. Dehghani, H., Omidi, H., and Sabaghnia, N. 2008. Graphic analysis of trait relations for rapeseed using the biplot method. Agronomy Journal 100 (5): 1443-1449.
4. Erfani, F., Shokrpour, M., Momeni, A., and Erfani, A. 2012. Evaluation of drought tolerance in rice varieties using yield-based indices at vegetative and reproductive stage. Sustainable Agriculture and Production Science 23 (4): 136-147. (in Persian).
5. Fernandez, G. C. J. 1992. Effective Selection Criteria for Assessing Plant Stress Tolerance. In: Kuo, C. G. (Ed.). Adaptation of Food Crops to Temperature and Water Stress Tolerance. Proceedings of the International Symposium on Adaptation of Vegetables and Other Food Crops to Temperature and Water Stress. AVRDC Publication, Tainan, Shanhua, Taiwan. Pp, 257-270.
6. Fischer, K. S., Lafitte, R., Fukai, S., Atlin, G., and Hardy, B. 2003. Breeding Rice for Drought-Prone Environments. Los Baños: IRRI, 98.
7. Fischer, R., and Maurer, R. 1978. Drought resistance in spring wheat cultivars. I. Grain yield responses. Crop and Pasture Science 29: 897-912.
8. Gavuzzi, P., Rizza, F., Palumbo, M., Campaline, R. G., Ricciardi, G. L., and Brghi, B. 1997. Evaluation of field and laboratory of drought and heat stress in winter cereals. Canadian Journal of Plant Science 77 (4): 523-531.
9. Ghiasy Oskoee, M., Farahbakhsh, H., Sabouri, H., and Mohammadinejad, G. 2013. Evaluation of rice cultivars in drought and normal conditions based on sensitive and tolerance indices. Eectronic Journal of Crop Poduction 6 (4): 55-75. (in Persian).
10. Ghiasy Oskoee, M., Farahbakhsh, H., Sabouri, H., and Mohammadinejad, G. 2012. Effect of drought stress on yield and yield components in rice landraces and improved cultivars under Gonbad Kavous environmental condition. Cereal Research 2 (3): 165-179. (in Persian).
11. Kohansal Vajargah, F., Amiri, E., Paknejad F., Vazan S., Kohansal Vajargah, S., and Motamedi. M. 2010. Determination of the suitable drought resistance indices in rice varieties. Journal of Crop Production Research 2 (4): 299-313. (in Persian).
12. Lafitte, H. R., Price, A. H., and Courtois, B. 2004. Yield response to water deficit in an upland rice mapping population: Associations among traits and genetic markers. Field Crops Research 6: 1237-1246.
13. O'Toole, J. C., Namuco, and O. S. 1983. Role of panicle exertion in water-stress induced sterility. Crop Science 23: 1093-1097.
14. Rahimi, M., Dehghani, H., Rabiei, B., and Tarang, A. R. 2013. Evaluation of rice segregating population based on drought tolerance criteria and biplot analysis. International Journal of Agriculture and Crop Sciences 5 (3): 194-199
15. Rosielle, A., and Hamblin, J. 1981. Theoretical aspects of selection for yield in stress and non-stress environment. Crop Science 21: 943-946.
16. Safaei Chaeikar, S., Rabiei, B., Samizadeh, H., and Esfahani, M. 2008. Evaluation of tolerance to terminal drought stress in rice (Oryza sativa L.) genotypes. Iranian Journal of Crop Sciences 9 (4): 315-331. (in Persian).
17. Schnider, K. A., Rosales-Serna, R., Ibarra-Perez, F., Cazares-Enriques, B., Acosta-Gallegos, J. A., Ramirez-Vallejo, P., Wassimi, N., and Kelly, J. D. 1997. Improving common bean performance under drought stress. Crop Science 37: 43-50.
18. Venuprasad, R., Sta Cruz, M. T., Amante, M., Magbanua, R., Kumar, A., and Atlin, G. N. 2008. Response to two cycles of divergent selection for grain yield under drought stress in four rice breeding populations. Field Crops Research 107: 232-244.18.
19. Yang, J., and Zhang, J. 2010. Crop management technique to enhance harvest index in rice. Journal of Experimental Botany 61 (12): 3177- 3189.
20. Zubaer, M., Chowdhury, A., Islam, M., Ahmed, T., and Hasan, M. 2007. Effects of water stress on growth and yield attributes of aman rice genotypes. International Journal of Sustainable Crop Production 2: 25-30.
CAPTCHA Image
  • Receive Date: 13 January 2017
  • Revise Date: 09 August 2017
  • Accept Date: 18 September 2017
  • First Publish Date: 21 March 2018