Soybean is an important cash crop with unique and important traits such as the high seed protein and oil contents, and the ability to perform symbiotic nitrogen fixation. A reference genome of cultivated soybeans was ...Soybean is an important cash crop with unique and important traits such as the high seed protein and oil contents, and the ability to perform symbiotic nitrogen fixation. A reference genome of cultivated soybeans was established in 2010, followed by whole-genome re-sequencing of wild and cultivated soybean accessions. These efforts revealed unique features of the soybean genome and helped to understand its evolution. Mapping of variations between wild and cultivated soybean genomes were perfo^aned. These genomic variations may be related to the process of domestication and human selection. Wild soybean germplasms exhibited hiigh genomic diversity and hence may be an important source of novel genes/alleles. Accumulation of genomic data will help to refine genetic maps and expedite the identification of functional genes. In this review, we summarize the major findings from the whole-genome sequencing projects and discuss the possible impacts on soybean researches and breeding programs. Some emerging areas such as transcriptomic and epigenomic studies will be introduced. In addition, we also tabulated some useful bioinformatics tools that will help the mining of the soybean genomic data.展开更多
Nitrogen (N) metabolism is essential for the biosynthesis of vital biomolecules. N status thus exerts profound effects on plant growth and development, and must be closely monitored. In bacteria and fungi, a few sop...Nitrogen (N) metabolism is essential for the biosynthesis of vital biomolecules. N status thus exerts profound effects on plant growth and development, and must be closely monitored. In bacteria and fungi, a few sophisticated N sensing systems have been extensively studied. In animals, the ability to receive amino acid signals has evolved to become an integral part of the nervous coordination system. In this review, we will summarize recent developments in the search for putative N sensing systems in higher plants based on homologous systems in bacteria, fungi, and animals. Apparently, although plants have separated and diversified from other organisms during the evolution process, striking similarities can be found in their N sensing systems compared with those of their counterparts; however, our understanding of these systems is still incomplete. Significant modifications of the N sensing systems (including cross-talk with other signal transduction pathways) in higher plants may be a strategy of adaptation to their unique mode of life.展开更多
基金supported by the Hong Kong RGC General Research Fund(Nos.468409 and 468610)
文摘Soybean is an important cash crop with unique and important traits such as the high seed protein and oil contents, and the ability to perform symbiotic nitrogen fixation. A reference genome of cultivated soybeans was established in 2010, followed by whole-genome re-sequencing of wild and cultivated soybean accessions. These efforts revealed unique features of the soybean genome and helped to understand its evolution. Mapping of variations between wild and cultivated soybean genomes were perfo^aned. These genomic variations may be related to the process of domestication and human selection. Wild soybean germplasms exhibited hiigh genomic diversity and hence may be an important source of novel genes/alleles. Accumulation of genomic data will help to refine genetic maps and expedite the identification of functional genes. In this review, we summarize the major findings from the whole-genome sequencing projects and discuss the possible impacts on soybean researches and breeding programs. Some emerging areas such as transcriptomic and epigenomic studies will be introduced. In addition, we also tabulated some useful bioinformatics tools that will help the mining of the soybean genomic data.
基金Supported by the Hong Kong UGC Area of Excellence on Plant and Fungal Biotechnology Center and Hong Kong RGC earmarked grant CUHK4263/ 00M
文摘Nitrogen (N) metabolism is essential for the biosynthesis of vital biomolecules. N status thus exerts profound effects on plant growth and development, and must be closely monitored. In bacteria and fungi, a few sophisticated N sensing systems have been extensively studied. In animals, the ability to receive amino acid signals has evolved to become an integral part of the nervous coordination system. In this review, we will summarize recent developments in the search for putative N sensing systems in higher plants based on homologous systems in bacteria, fungi, and animals. Apparently, although plants have separated and diversified from other organisms during the evolution process, striking similarities can be found in their N sensing systems compared with those of their counterparts; however, our understanding of these systems is still incomplete. Significant modifications of the N sensing systems (including cross-talk with other signal transduction pathways) in higher plants may be a strategy of adaptation to their unique mode of life.