日本語フィールド
著者:Sarkar, M. A. R., W. Otsu, A. Suzuki, F. Hashimoto, T. Anai, S. Watanabe題名:Single-base deletion in GmCHR5 increases the genistein-to-daidzein ratio in soybean seed.発表情報:Breeding Science 巻: 70 号: 3 ページ: 265-276キーワード:概要:抄録:Novel mutant alleles related to isoflavone content are useful for breeding programs to improve the disease resistance and nutritional content of soybean. However, identification of mutant alleles from high-density mutant libraries is expensive and time-consuming because soybean has a large, complicated genome. Here, we identified the gene responsible for increased genistein-to-daidzein ratio in seed of the mutant line F333ES017D9. For this purpose, we used a time- and cost-effective approach based on selective genotyping of a small number of F2 plants showing the mutant phenotype with nearest-neighboring-nucleotide substitution–high-resolution melting analysis markers, followed by alignment of short reads obtained by next-generation sequencing analysis with the identified locus. In the mutant line, GmCHR5 harbored a single-base deletion that caused a change in the substrate flow in the isoflavone biosynthetic pathway towards genistein. Mutated GmCHR5 was expressed at a lower level during seed development than wild-type GmCHR5. Ectopic overexpression of GmCHR5 increased the production of daidzein derivatives in both the wild-type and mutant plants. The present strategy will be useful for accelerating identification of mutant alleles responsible for traits of interest in agronomically important crops.英語フィールド
Author:Sarkar, M. A. R., W. Otsu, A. Suzuki, F. Hashimoto, T. Anai, S. WatanabeTitle:Single-base deletion in GmCHR5 increases the genistein-to-daidzein ratio in soybean seed.Announcement information:Breeding Science Vol: 70 Issue: 3 Page: 265-276An abstract:Novel mutant alleles related to isoflavone content are useful for breeding programs to improve the disease resistance and nutritional content of soybean. However, identification of mutant alleles from high-density mutant libraries is expensive and time-consuming because soybean has a large, complicated genome. Here, we identified the gene responsible for increased genistein-to-daidzein ratio in seed of the mutant line F333ES017D9. For this purpose, we used a time- and cost-effective approach based on selective genotyping of a small number of F2 plants showing the mutant phenotype with nearest-neighboring-nucleotide substitution–high-resolution melting analysis markers, followed by alignment of short reads obtained by next-generation sequencing analysis with the identified locus. In the mutant line, GmCHR5 harbored a single-base deletion that caused a change in the substrate flow in the isoflavone biosynthetic pathway towards genistein. Mutated GmCHR5 was expressed at a lower level during seed development than wild-type GmCHR5. Ectopic overexpression of GmCHR5 increased the production of daidzein derivatives in both the wild-type and mutant plants. The present strategy will be useful for accelerating identification of mutant alleles responsible for traits of interest in agronomically important crops.