Agronomic Performance and Biochemical Genetic Markers for Drought Tolerance in Rice (Oryza sativa L.)
Abstract
Rice (Oryza sativa L.) is considered one of the most important food crops not only in Egypt but also world wide. The demands of rice are in continuous increasing. The majority of rice ecotypes are semi-aquatic plants adapted to saturated soil conditions where it is difficult for crop species to survive (Champoux et al., 1995). Agricultural expansion in Egypt depends largely on water which is considered one of the main factors limiting agricultural development, so, one way to save water is increasing water intervals without any sharp effect on the yield. High degree of drought tolerance allows the plant to maintain its growth and development under water stress. The ability of the plant to produce new tillers and resume growth and development after irrigation is an important factor in drought tolerance (Chang et al., 1974). Identifying varieties with high yield potential and drought tolerance is one of the principal objectives of rice breeders.
Several researchers have conducted studies on the effect of water deficit on rice. The effect of water stress on grain yield depends on the duration and timing of water deficit (Lenka and Garnayak, 1991; Castillo et al., 1992; Tsuda et al., 1994). Grain yield and yield components were significantly decreased with increasing irrigation intervals (Nour et al., 1994; Sorour et al., 1998; Adhikary et al., 1999; Sehly et al., 2001; Gaballah, 2009). Drought stress resulted in high spikelet sterility (Nour and Mahrous, 1994; Chauhan et al., 1999). Panicle length was decreased sharply when rice plants were subjected to irrigation intervals every 6 days (El-Wehishy and Ghanem, 1996) or longer than 6 days (Abou El-Hassan,1997).
The conventional methods of plant selection for drought tolerance are not easy because of the large effects of the environment and low narrow sense heritability. Selection for drought tolerance genotypes of rice based on phenotypic performance alone is less reliable and will delay progress in breeding. Recent advent of molecular and biochemical markers, are used to find out drought tolerant rice genotypes.
Molecular marker assisted identification with high power of genetic resolutions has emerged as a robust technique for cultivar fingerprinting, identity profiling, estimating and comparing genetic similarity, and variety protection. Several types of molecular marker i.e., allozymes (Devanand et al., 1999), RAPD (Wang and Lu, 2006; Ichii et al., 2003) and SSR (Nandakumar et al., 2004) have been used in this term. . The application of molecular markers in rice improvement has been reviewed recently (Mackill, 2007). Another indication for a response of the plant against abiotic stress is an increased level of free amino acids. Some of the amino acids are by themselves compatible solutes like proline, others are precursors of compatible solutes, like glycin or alanin (Hanson et al., 1994). But also other amino acids turned out to be enhanced (Rizhsky et al., 2004) which might be necessary for de novo synthesis of induced proteins.
This study aimed to achieve reliable information about the relationships between morphological performance as some growth, yield as well as yield components and drought stress tolerance of 25 rice genotypes and to capture effective molecular and biochemical markers associated with drought tolerance to use in marker-aided selection breeding programs.
References
Abdelsalam, A. Z. E., S.A. Ibrahim, F. M. A. Eldomyati and Ghada H. El-Nady (1998). Biochemical and Molecular genetic charachterization of Egyptian barely cultivars and a trial for their micropropagation. 3rd Arab conference, Modern Biotech. & Areas of Application in the Arab World, 14-17 Dec., Cairo, Egypt, p. 582-605.
Abdel-Tawab, F. M., Eman M. Fahmy, A. Bahieldin, Asmahan A. Mahmoud and O. M. Saleh (1998a) Developing molecular genetic indices for drought tolerance in some inbreds and hybrids of maize (Zea mays L.) 3rd Arab Conference, Modern biotech. and Area of application in the Arab Word. Cairo, Egypt. p. 641-661.
Abdel-Tawab, F. M., M. A. Rashed, R. S. Dhindsa, A. Bahieldin and A. Abo-Doma (1998b). Molecular Markers for salt tolerance in Sorghum bicolor. International Congress on Molecular Genetics. Cairo, Egypt., p. 195-204.
Abdel-Tawab, F. M., Eman M. Fahmy, A. Bahieldin, and Hala F. Eissa (1997). Molecular markers for salt tolerance in some inbreds of maize (Zea mays L.). Arab. Univ. J. Agric. Sci., 5:3 85-417.
Abou El-Hassan, W. H. (1997). Effect of different methods of seedbed preparation and irrigation treatments on productivity of rice crop. MSc. Thesis, Fac. Agric., Kafrel-sheikh Tanta Univ., Egypt.
Adhikary, S., D. K. Bagchi and B. K. Surkar (1999). Studies on the extent of drought tolerance in upland superfast rice. Oryza, 36: 169-181.
Ali, D., P. H. Monnereux and J. L. Araus (1990). Breeding durum wheat for drought tolerance. Analytical, synthetical approaches and their connection. In Wheat breeding and future approaches. Bulgarian Agricultural Academy, Bulgaria, p. 224-240.
Bartlett, M. S. (1937). Properties of sufficiency and statistical test. Proc. Roy. Soc. London, Series A., 160: 268-282.
Bates, L. S., R. P. Waldren and L. D. Teare (1973). Rapid determination of free proline for water stress studies. Short Communication. Plant and Soil, 39: 205-207.
Bhowmik, S. K., S. Titov, M. M. Islam, A. Siddika, S. Sultana and M. D. Shahidul Haque (2009). Phenotypic and genotypic screening of rice genotypes at seedling stage for salt tolerance. African Journal of Biotechnology, 8: 490-494
Castillo, E. G., R. J. Buresh and K. T. Ingram (1992). Low land rice yield as affected by timing of water deficit and nitrogen fertilization. Agron. J., 84: 152-159.
Champoux, M. C., G. Wang, S. Sarkarung, D. J. Mackill, J. C. O’Toole, N. Huang and S. R. McCouch (1995). Locating genes associated with root morphology and drought avoidance in rice via linkage to molecular markers. Theor. and Appl. Genet., 90: 969-981.
Chang, T., G. C. Loresto and O. Tagumpay (1974). Screening rice germplasm for drought resistance. SABRAO J., 6: 9-16.
Chauhan, J. S., T. B. Mogal, R. K. Singh and C. V. Singh (1999). Influence of soil moisture stress during reproductive stage on physiological parameters and grain yield in upland rice. Oryza, 36: 130-135.
Ciucă M., E. Todorvska, S. Kolev, R. Nicolae and I. Guinea (2009). Marker - assisted selection (MAS) for drought tolerance in wheat using markers associated with membrane stability. AN. Indian. C. D. A. Fundulea, 7-12
Ciucă, M. and E. Petcu (2009). SSR markers associated with membrane stability in wheat (Triticum aestivum L.). Romanian Agricultural Research, 26: 21-24.
Cochran, W. G. and G. M. Cox (1957). Experimental Design. 2nd ed. John Wiley, NY.
Delauney, A. J. and D. P. S. Verma (1993). Proline biosynthesis and osmoregulation in plants. Plant J., 4: 215-223.
Devanand, P. S., J. Wan, M. Rangaswamy and H. Ikehashi (1999). Plant genetic resources: isozyme divergence between maintainers and restorers in hybrid rice breeding programs in India. Crop Sci., 39: 831-835.
Draz, A. E., A. A. Ali and S. Dora. (1993). Genetic evaluation of anther culture-derived lines of F1 hybrids of rice (Oryza sativa L.). J. Agric. Res. Tanta Univ., 19: 876-886.
Doyle, J. J. and J. L. Doyle (1990) Isolation of plant DNA from fresh tissue. Focus, 12: 13-15.
Duncan, B. D. (1955). Multiple F Test. Biometrics, 11: 1-42.
El-Degwy, I. S. (2006). Advanced studies on hybrid rice. Ph. D. Thesis, Fac. Agric., Kafrelsheikh, Tanta University.
El-Keredy, M. S., A. G. Abdel-Hafez, M. M. El-Wehishy and I. S. El-Degwy (2003). Potential of hybrid rice production under Egyptian conditions. I. Rice lines and hybrids. Proc. 3rd Plant Breed. Conf. April. 26, (Giza), Giza. J. Plant Breed., 7: 471-486.
El-Wehishy, M. M. and A. G. Abdel-Hafez (1997). Response of flooded rice to water deficit. J. Agric. Res. Tanta Univ., 23: 273-288.
El-Wehishy, M. M. and S. A. Ghanem (1996). Behaviour of Giza 176 rice variety as affected by water management, N-forms and nitrification inhibitor (DCD). Proc. 7th Conf. Agron. Mansoura Univ., p. 93-104.
Gaballah, M. M. (2009). Studies on physiological and morphological traits associated with drought resistance in rice (Oryza sativa L.). PhD. Thesis, Fac. Agric., Kafrel-sheikh Unvi., Egypt.
Hanson, A. D., B. Rathinasabapathi, J. Rivoal, M. Burnet, M. O. Dillon and D. A. Gage (1994). Osmoprotective compounds in the Plumbaginaceae: a natural experiment in metabolic engineering of stress tolerance. Proc. Nat. Acad. Sci., USA, 91: 306-310.
Hare, P. D. and W. A. Cress (1997). Metabolic implications of stress-induced proline accumulation in plants. Plant Growth Regul., 21: 79-102.
Ichii, M., D. L Hong, Y. Ohara, C. M. Zhao and S. Taketa (2003). Characterization of CMS and maintainer lines in indica rice (Oryza sativa L.) based on RAPD marker analysis. Euphytica, 129: 249-252.
Larsen, A. L. and W. C. Benson (1970). Variety-specific of oxidative enzymes from soybean seeds. Crop Sci., 10: 493-495.
Lenka, D. and L. M. Garnayak (1991). Effect of weather variation and moisture stress on growth and development of upland rice (Oryza sativa L.) in Oxisols of Bhubaneshwar. Indian Journal of Agricultural Sciences, 61: 865-871.
Mackill, D. J. (2007). Molecular markers and marker-assisted selection in rice. p. 147-168. In R. K. Varshney and R. Tuberosa (ed.) Genomics assisted crop improvement. Vol. 2. Genomics applications in crops. Springer, New York.
McCouch, S. R., G. Kochert, Z. H. Yu, Z. Y. Wang, G. S. Khush, R. W. Coffman and S. D. Tanksley. (1988). Molecular mapping of rice chromosomes. Theor. Appl. Genet. 76: 815-829.
McCouch, S. R., L. Teytelman, Y. Xu, K. B. Labos, K. Clare and M. Walton (2002). Development and mapping of 2240 new SSR markers in rice (Oryza sativa L.). DNA Res., 9: 199-207.
Nandakumr, N., A. Singh, K. Sharma, R. K. Mohapara, T. K. V. Prabhu and F. U. Zaman (2004). Molecular fingerprinting of hybrids and assessment of genetic purity of hybrid seeds in rice using microsatellite markers. Euphytica, 136: 257-264.
Nguyen, Thi Lang, B. C. Buu and A. Ismail (2008). Molecular mapping and marker assisted-selection for salt tolerance in rice (Oryza sativa L.). Omonrice, 16: 50-56.
Nour, M. A. and F. N. Mahrous (1994). Effect of varying irrigation intervals during tillering reproductive and ripening stages on rice yield and its components. Egypt. J. Appl. Sci., 9: 869-879.
Nour, M. A. M., A. E. Abd El-Wahab and S. A. Ghanem (1994). Broadcast seeded rice as affected by different irrigation intervals. Egypt. J. Appl. Sci., 9: 671-683.
Rizhsky, L., H. Liang, J. Shuman, V. Shulaev, S. Davletova and R. Mittler (2004). When defense pathways collide. The response of Arabidopsis to a combination of drought and heat stress. Plant Physiol., 134: 1683-1696.
Sahu, B. N. and B. J. Rad (1974). Water regime in rice soils. I. Effect of soil moisture stress at different phases of growth of three rice plant types. Oryza, 11: 54-65.
Sehly, M. R., R. H. Osman, S. M. El-Wahsh, E. A. Salem and E. A. S. Badr (2001). Effect of water irrigation intervals on rice blast disease. Egypt. J. Appl. Sci., 16: 429-443.
Sinha, S. K., R. Khanna, P. K. Aggarwal, G. S. Chaturvedi and K. R. Koundal (1982). Effect of drought on shoot growth: significance of metabolism to growth and yield. In: Drought resistance in crops with emphasis on rice. IRRI, P. O. Box 933, Manila, Philippines.
Smith, J. S. C. (1989). The characterization and assessment of Genetic diversity among Maize (Zea mays L.) hybrids that are widely grown in france. Euphytica, 43: 73-85.
Snedecor, G. W. and W. G. Cochran (1967). Statistical methods. Iowa State Univ. Press, USA.
Sorour, F. A., M. E. Mosalem, F. N. Mahrous and I. S. El-Refaee (1998). Effect of irrigation intervals and splitting of nitrogen on growth and yield quality of rice. J. Agric. Res. Tanta Univ., 1: 60-75.
Stegmann, H., A. M. R. Afifiy and K. R. F. Hussein (1985). Cultivar identification of Dates (phoenix dactylifera) by protein battern. 2nd International symposium of Biochemical Approaches to Identification of Cultivars. Braunschweig, West Germany, pp 44.
Tripathi, B. N., and J. P. Gaur (2004). Relationship between copper and zinc-induced oxidative stress and proline accumulation in Scenedesmus sp. Planta, 219: 397-404.
Tsuda, M., H. Yamaguchi, S. Takami and K. Ikeda (1994). Effect of panicle water potential on water stress susceptibility in rice. Japanese Journal of Crop Sci., 63: 200-220.
Tusda, M., Y. J. Yamane and S. Takami (1993). Relationship between panicle weight per plant and cumulative water stress in rice. Japanese J. of Crop Sci., 62: 60-65.
Wang, S. and Z. Lu (2006). Genetic diversity among parental lines of Indica hybrid rice (Oryza sativa L.) in china based on coefficient of parentage. Plant Breed., 125: 606-612.
