The 25-26 Nt Small RNAs in Are Associated with Efficient Silencing of Homologous Endogenous Genes

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2017 May 18

PMID 28512457

Citations 20

Authors

Jinbu Jia

Wenqin Lu

Chengcheng Zhong

Ran Zhou

Junjie Xu

Wei Liu

Xiuhong Gou

Qinhu Wang

Junliang Yin

Cheng Xu

Weixing Shan

Affiliations

Soon will be listed here.

Abstract

Small RNAs (sRNAs) are important non-coding RNA regulators, playing key roles in developmental regulation, transposon suppression, environmental response, host-pathogen interaction and other diverse biological processes. However, their roles in oomycetes are poorly understood. Here, we performed sRNA sequencing and RNA sequencing of at stages of vegetative growth and infection of roots to examine diversity and function of sRNAs in , a model hemibiotrophic oomycete plant pathogen. Our results indicate that there are two distinct types of sRNA-generating loci in genome, giving rise to clusters of 25-26 nt and 21 nt sRNAs, respectively, with no significant strand-biases. The 25-26 nt sRNA loci lie predominantly in gene-sparse and repeat-rich regions, and overlap with over 7000 endogenous gene loci. These overlapped genes are typically species-specific, with no homologies to the sister species . They include approximately 40% RXLR effector genes, 50% CRN effector genes and some elicitor genes. The transcripts of most of these genes could not be detected at both the vegetative mycelium and infection stages as revealed by RNA sequencing, indicating that the 25-26 nt sRNAs are associated with efficient silencing of these genes. The 21 nt sRNA loci typically overlap with the exon regions of highly expressed genes, suggesting that the biogenesis of the 21 nt sRNAs may be dependent on the level of gene transcription and that these sRNAs do not mediate efficient silencing of homologous genes. Analyses of the published sRNA and mRNA sequencing data consistently show that the 25-26 nt sRNAs, but not the 21 nt sRNAs, may mediate efficient gene silencing in .

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