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Evolution and Diversification of Reproductive Phased Small Interfering RNAs in Oryza Species

本站小编 Free考研考试/2022-01-01

Peng Tian, Xuemei Zhang, Rui Xia, Yang Liu, Meijiao Wang, Bo Li, Tieyan Liu, Jinfeng Shi , Rod A Wing, Blake C Meyers, Mingsheng Chen

New Phytologist


Abstract
In grasses, two types of phased, small interfering RNAs (phasiRNAs) are expressed largely in young, developing anthers. They are 21 or 24 nucleotides (nt) in length, and are triggered by miR2118 or miR2275, respectively. However, most of their functions and activities are not fully understood. We performed comparative genomic analysis of their source loci (PHAS) in five Oryza genomes, and combined this with analysis of high-throughput sRNA and degradome datasets. In total, we identified 8216 21-PHAS and 626 24-PHAS loci. Local tandem and segmental duplications mainly contributed to the expansion and supercluster distribution of the 21-PHAS loci. Despite their relatively conserved genomic positions, PHAS sequences diverged rapidly, except for the miR2118/2275 target sites, which were under strong selection for conservation. We found 21-nt phasiRNAs with a 5'-terminal uridine (U) demonstrated cis cleavage at PHAS precursors, and these cis-acting sites were also variable among close species. miR2118 could trigger phasiRNA production from antisense transcript of its own, and the derived phasiRNAs might reversely regulate miR2118 precursors. We hypothesized that successful initiation of phasiRNA biogenesis is conservatively maintained, while the phasiRNA products diverged quickly and are not individually conserved. In particular, phasiRNA production is under the control of multiple reciprocal regulation mechanisms.


论文编号: DOI:10.1111/nph.17035
论文题目: Evolution and Diversification of Reproductive Phased Small Interfering RNAs in Oryza Species
英文论文题目: Evolution and Diversification of Reproductive Phased Small Interfering RNAs in Oryza Species
第一作者: Peng Tian, Xuemei Zhang, Rui Xia, Yang Liu, Meijiao Wang, Bo Li, Tieyan Liu, Jinfeng Shi , Rod A Wing, Blake C Meyers, Mingsheng Chen
英文第一作者: Peng Tian, Xuemei Zhang, Rui Xia, Yang Liu, Meijiao Wang, Bo Li, Tieyan Liu, Jinfeng Shi , Rod A Wing, Blake C Meyers, Mingsheng Chen
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发表年度: 2020-11-17
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摘要: In grasses, two types of phased, small interfering RNAs (phasiRNAs) are expressed largely in young, developing anthers. They are 21 or 24 nucleotides (nt) in length, and are triggered by miR2118 or miR2275, respectively. However, most of their functions and activities are not fully understood. We performed comparative genomic analysis of their source loci (PHAS) in five Oryza genomes, and combined this with analysis of high-throughput sRNA and degradome datasets. In total, we identified 8216 21-PHAS and 626 24-PHAS loci. Local tandem and segmental duplications mainly contributed to the expansion and supercluster distribution of the 21-PHAS loci. Despite their relatively conserved genomic positions, PHAS sequences diverged rapidly, except for the miR2118/2275 target sites, which were under strong selection for conservation. We found 21-nt phasiRNAs with a 5'-terminal uridine (U) demonstrated cis cleavage at PHAS precursors, and these cis-acting sites were also variable among close species. miR2118 could trigger phasiRNA production from antisense transcript of its own, and the derived phasiRNAs might reversely regulate miR2118 precursors. We hypothesized that successful initiation of phasiRNA biogenesis is conservatively maintained, while the phasiRNA products diverged quickly and are not individually conserved. In particular, phasiRNA production is under the control of multiple reciprocal regulation mechanisms.
英文摘要: In grasses, two types of phased, small interfering RNAs (phasiRNAs) are expressed largely in young, developing anthers. They are 21 or 24 nucleotides (nt) in length, and are triggered by miR2118 or miR2275, respectively. However, most of their functions and activities are not fully understood. We performed comparative genomic analysis of their source loci (PHAS) in five Oryza genomes, and combined this with analysis of high-throughput sRNA and degradome datasets. In total, we identified 8216 21-PHAS and 626 24-PHAS loci. Local tandem and segmental duplications mainly contributed to the expansion and supercluster distribution of the 21-PHAS loci. Despite their relatively conserved genomic positions, PHAS sequences diverged rapidly, except for the miR2118/2275 target sites, which were under strong selection for conservation. We found 21-nt phasiRNAs with a 5'-terminal uridine (U) demonstrated cis cleavage at PHAS precursors, and these cis-acting sites were also variable among close species. miR2118 could trigger phasiRNA production from antisense transcript of its own, and the derived phasiRNAs might reversely regulate miR2118 precursors. We hypothesized that successful initiation of phasiRNA biogenesis is conservatively maintained, while the phasiRNA products diverged quickly and are not individually conserved. In particular, phasiRNA production is under the control of multiple reciprocal regulation mechanisms.
刊物名称: New Phytologist
英文刊物名称: New Phytologist
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其它备注: Peng Tian, Xuemei Zhang, Rui Xia, Yang Liu, Meijiao Wang, Bo Li, Tieyan Liu, Jinfeng Shi , Rod A Wing, Blake C Meyers, Mingsheng Chen. Evolution and Diversification of Reproductive Phased Small Interfering RNAs in Oryza Species. New Phytologis. DOI:10.1111/nph.17035
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