Full Length Research Paper
References
|
Bagheri N, Babaeian-Jelodar N, Pasha A (2011). Path coefficient for yield and yield components in divers rice. (Oryza sativa L.) Genotype. Bih. Biol. 5:32-35. |
|
|
Bernier J, Altin GN, Serraj R, Kumar A, Spaner D (2008). Breeding upland rice for drought resistance. J. Sci. Food Agric. 88:927-939. |
|
|
Board JE, Kang MS, Hartville BG (1997). Path analyses identify indirect selection criteria of field of late planted soybean. Crop Sci. 37:897-884. |
|
|
Bonnett DG, Rebetzke GJ, Spielmeyer W (2005). Strategies for Efficient Implementation of Molecular Markers in Wheat Breeding. Mol. Breed. 15:75-85. |
|
|
Chen S, Lin XH, Xu CG, Zhang Q (2000). Improvement of bacterial blight resistance of "Minghui 63", an elite restorer line of hybrid rice, by molecular marker assisted selection. Crop Sci. 40(1):239-244. |
|
|
Devereux S (2007). The impact of drought and floods on food security and policy options to alleviate negative effects. Agric. Econ. 37(S1):47-58. |
|
|
Dey MM, Upadhyaya HK (1996). Yield loss due to drought, cold and submergence in Asia. In Evenson RE, Herdt RW, Hossain M, eds, Rice Research in Asia: Progress and Priorities. CAB International, Wallingford. UK. pp. 291-303. |
|
|
Eathington SR, Dudley JW, Rufener GK (1997). Usefulness of markers-QTL association in early generation selection. Crop Sci. 37:1686-1693. |
|
|
Eradasappa E, Nadarajan N, Ganapathy KN, Shathala J, Satish RG (2007). Correlation and path analysis for yield and its attributing traits in rice. (Oryza Sativa L.). Crop Res. 34:156-159. |
|
|
Gauchan D, Pandey S (2012). Synthesis of key results and implications. In: Pandey S, Gauchan D, Malabayabas M, Bool-Emerick M, Hardy B. (Eds.), Patterns of Adoption of Improved Rice Varieties and Farm-Level Impacts in Stress-Prone Rainfed Areas in South Asia. International Rice Research Institute, Los Ba-os, Philippines. |
|
|
Griffing B (1956). Concept of general and specific combining ability in relation to diallel mating systems. Aust. J. Biol. Sci. 9:463-493. |
|
|
Hayman BI (1954). The theory and analysis of diallel crosses. Genentic 30:789-890. |
|
|
Iftekharuddaula KM, Ahmed HU, Ghosal S, Moni ZR, Amin MA, Ali MS (2015). Development of new Submergence tolerant rice variety for Bangladesh using Marker–Assisted backcrossing. Rice Sci. 22(1):16-26. |
|
|
IRRI (1988). Standard Evaluation System for Rice. International Rice Research Institute, Manila, Philippines pp. 35-37. |
|
|
IRRI (1996). Standard Evaluation System for rice. International Rice Research Institute. Los Banos, Philippines. 52 p. |
|
|
Jeena HS, Mani SC (1990). Studied on root characters and grain yield of some upland rice varieties. Oryza 27(2):214-216. |
|
|
Krisha Veni B, Shobha Rani N (2005). Assosiation and path analysis for yield compenents in F2 generation of rice. Andhara Agric. J. 52:290-292. |
|
|
Kuchel H, Fox R, Reinheimer J, Mosionek L, Willey N, Bariana H, Jefferies S (2007). The successful application of a marker-assisted wheat breeding strategy. Mol. Breed. 20:295-308. |
|
|
Kumar A, Berner J, Verulkar S, Lafitte HR, Atlin GN (2008). Breeding for drought tolerance: direct selection for yield, response to selection and use of drought-tolerant donors in upland and lowland-adapted populations. Field Crop Res. 107:221-231. |
|
|
Kumar A, Dixit S, Ram T, Yadaw RB, Mishra KK, Mandal NP (2014). Breeding high-yield drought tolerant rice: Genetic variation and conventional and molecular approaches. J. Exp. Bot. 65(21):6265-6278. |
|
|
Khush GS (2005). What it will take to feed 5.0 billion rice consumers in 2030. Plant Mol. Biol. 59:1-6. |
|
|
Lande R, Thompson R (1990). Efficiency of Marker-Assisted Selection in the Improvement of Quantitative Traits. Genetics 124:743-756. |
|
|
Lang NT, Nha CT, Ha PTT, Buu BC (2013). Quantitative Trait Loci (QTLs) Associated With Drought Tolerance In Rice (Oryza Sativa l.). SABRAO J. Breed. Genet. 45(3):409-421. |
|
|
Lang NT, Phuoc NT, Ha PTT, Toan TP, Buu BC, Reinke R, Ismail AM, Wassmann R (2015). Development of Submergence Tolerant Breeding Lines for Vietnam. SABRAO J. Breed. Genet. 47(4):448-459. |
|
|
Lang NT, Buu BC (2008). Fine mapping for drought tolerance in rice (Oryza sativa L.). Omon Rice 16:9-15. |
|
|
Madhavilatha L, Reddi M, Suneetha Y, Srinivas T (2005). Genentic variability, correlation and path analysis for yield and quality traits in rice (Oryza sativa L.). Res. Crop 6(3):527-534. |
|
|
McCouch SR, Chen X, Paunaud O, Temnykh S, Xu Y, Cho YG, Huang N, Ishii T, Blair M (1997) Microsettlite marker development, mapping and application in rice genetics and breeding. Plant Mol. Biol. 35:89-99. |
|
|
Melchinger AE (1990). Use of molecular markers in breeding for oligogenic disease resistance. Pland Breed. 104(1):1-19. |
|
|
Mohsin T, Khan N, Naqvi FN (2009). Heritability, phenotypic correlation and path coefficient studies for some agronomic characters in synthetic elite lines of wheat. J. Food Agric. Environ. 7:278-282. |
|
|
Muthuramu S, Jebaraj S, Gnanasekaran M (2010). Combining ability and heterosis for drought tolerance in different locations in rice (Oryza saitva L.). Res. J. Agric. Sci. 1(3):266-270. |
|
|
Neeraja CN, Maaghirang R, Pamplona A, Heuer S, Collard BCY, Septiningsih EM, Vergara G, Sanchez D, Xu K, Ismail AM, Mackill DJ (2007). A marker- assisted backcross approach for rice cultivar. Theor. Appl. Gennet. 115:767-776. |
|
|
Nguyen TT, Klueva N, Chamareck V, Aarti A, Magpantay G, Millena AC, Pathan MS, Nguyen HT (2004). Saturation mapping of QTL regions and identification of putative candidate genes for drought tolerance in rice. Mol. Genet. Genom. 272(1):35-46. |
|
|
O'Toole JC, De Datta SK (1986). Drought resistance in rainfed lowland rice. Progress in rainfed rice . IRRI Los Banos. Philipines. P 145. |
|
|
Pandey S, Bhadari H (2009). Drought: economic cost and research implication. In. Serraj J, Bennet J, Hardy B. Drought frontiers in rice: crop improvement for increase rainfed production. Word Sci. Publishing Singapore. pp. 3-17. |
|
|
Rahimi M, Rabei B, Samizadeh H, Ghasami AK (2010). Combining ability and heterosis in rice (Oryza saitva L.) cutivars. J. Agric. Sci. Techol. 12:223-231. |
|
|
Rananwake AL, Hewage MJ (2014). Correlation analysis of drought, salinity ang submergence tolerance in some traditional rice cultivars of Sri Lanka. Int. J. Sci. Res. 4(7):1-5. |
|
|
Rathnayake NRMKND, Bentota AP, Dissanayake DMN, Perera KLNS, Sooriyapathirana SDSS, Jayasekera GAU (2012). DNA markers RM464 and RM219 Haplotypes are effective in selecting Sub - 1 locus for the introgression of submergence tolerance into new rice varieties. Biol. Sci. 41:125-136. |
|
|
Sambrook J, Fritsch EF, Maniatis T (1989). Molecular cloning: a laboratory Manual, vol. 3. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. |
|
|
Septinnighsih EM, Pamplona AM, Sanchez DL, Neeraja CN, Vergara GV, Heuer S, Ismai AM, Mackil DJ (2009). Development of submergence tolerant rice cultivars: the Sub1 locus and beyond. Ann. Bot. 103:151-160. |
|
|
Sharma PK, Pantuwan G, Ingram KT, De Datta SK (1994). Rainfed lowland rice roots: soil and hydrological effects: in Kiirk GJD, (Ed.) Rice roots: nutrient and water use. IRRI, Los Banos, Philipines. pp. 55-56. |
|
|
Sinclair TR, Muchow RC (2001). Systerm analysis of plant traits to increase grain yield on limited water supplies. Agron. J. 93:263-270. |
|
|
Sunderraj N, Nagaraj S, Vekara RMN, Jagannath MK (1972). Designs and analysis of field experiments. Uni. Agri. Sci, Hebbal, Bangalore. |
|
|
Tanksley SD, Young ND, Paterson AH, Bionierbale MW (1989). RELP mapping in plant breeding, new tools for an old science. Biotechnology 7:257-264. |
|
|
Tanskley SD (1983). Molecular markers in plant breeding. Plant Mol. Biol. Rep. 1:3-8. |
|
|
Thangaraj M, O'Toole JC, De Datta SK (1990). Root response to water stress in rainfed lowland rice. Exp. Agric. 26:287-296. |
|
|
Vaishali MG (2003). DNA marker assisted mapping of blast and yield loci, graphical genotyping and candidate gene analysis in rice (Oryza sativa L.) Ph.D Thesis. Univ. Agric. Sci. Bengaluru, India. |
|
|
Venupeasad R, Lafitte HR, Atlin GN (2007). Response to direct selection for grain yield under drought stress in rice. Crop Sci. pp. 285-293. |
|
|
Xu K, Deb R, Mackill DJ (2004). A microsatellite marker and codominant PCR-based marker for marker -assisted selection of submergence in rice. Crop Sci. 44:248-253. |
|
|
Xu K, Mackill DJ (1996). A major locus for submergence tolerance mapped on rice chromosome 9. Mol. Breed. 2:219-224. |
|
|
Xu K, Xia X, Fukao T, Canlas P, Maghirang R, Heuer S, Ismail AM, Bailey SJ, Ronald PC, Mackill DJ (2006). Sub1A is an ethylene response factor-like gene that confers submergence tolerance to rice. Nature 442:705-708. |
|
|
Yogameenaskshi P, Vivekanandan P (2010). Association analysis in F1 and F2 generation of rice under reproductive stage drought stress. Electron . J. Plant Breed. 1(4):890-898. |
|
|
Zou P, Tan Y, He Y, Xu C, Zhang Q (2003). Simultaneous improvement for four quality traits of Zhenshan 97, an elite parent of hybrid rice, molecular marker-assisted selection. Theor. Appl. Genet. 106(2):326-331. |
|
Copyright © 2024 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0
