Shorten rice breeding cycle and developing new promising lines

El-Namaky, Raafat; Seedek, Saber; Elbadawy, Osama; Bleih, Eman; Sultan, Saied; Awadallah, Mervat; Tahoon, Abdelaziz; Taha, Ahmed

doi:10.21608/ejar.2023.195656.1373

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Egyptian Journal of Agricultural Research

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	Shorten rice breeding cycle and developing new promising lines
Article 32, Volume 101, Issue 2, July 2023, Page 685-699 PDF (841.27 K)
Document Type: Original Article
DOI: 10.21608/ejar.2023.195656.1373
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Authors
Raafat El-Namaky ¹; Saber Seedek¹; Osama Elbadawy¹; Eman Bleih¹; Saied Sultan¹; Mervat Awadallah¹; Abdelaziz Tahoon²; Ahmed Taha¹
¹Rice Research and Training Center, Field Crop Research institute, Agricultural Research Center, Egypt
²Rice Pathology Department, Plant Pathology Research Institute, Agricultural Research Center, Egypt
Abstract
Accelerating rice breeding can be accomplished through various approaches, including molecular or conventional techniques. In this regard, some rice breeding programs around the world have changed to use rapid generation advancement (RGA) as a new breeding method. The objectives of this investigation are to establish and implement RGA techniques at the Rice Research & Training Center (RRTC) to develop new, improved, blast disease-resistant, and high-yielding varieties more quickly and at a low cost. Three F2 populations, (Giza177 x Sakha Super300), (IR75589-31 x Giza178), and (Giza179 x IR59673-93-2-3-3-2), were advanced to F2 and evaluated in Lines Stage Trials (LST) and preliminary yield trials (PYT). RGA facilities were installed at the greenhouse of the RRTC, and the F2 plants of each population were harvested individually. One seed from each panicle was used to cultivate the next generation (F3) according to the single seed descent (SSD) method. The RGA technique was successfully implemented at RRTC with simple multipot trays and the maintenance of the greenhouse and screen house. The early generations (F2, F3, F4, and F5) showed good performance in the greenhouse; the narrow space and low fertilizer led to early flowering. promising RGA lines, SK-RGA2-5, SK-RGA2-9, and SK-RGA3-6, revealed grain yields of more than 11.0 t/ha compared with the check varieties, Giza177, Giza178, and Sakha super300, which gave 9.57, 10.17, and 10.50 t/ha, respectively. For grain quality traits, most of the test RGA lines and check varieties have low to medium amylose content, ranging between 17.83 and 23.13%. RGA lines and check varieties gave desirable values for hulling and milling. In general, hulling% ranged between 80.0 and 85.0%, and milling% ranged between 69.43 and 73.0%.
Keywords
Rice Breeding; RGA; Single seed descent (SSD); grain yield; Rice blast disease; grain quality


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