Xenogeneic Silencing and Bacterial Genome Evolution: Mechanisms for DNA Recognition Imply Multifaceted Roles of Xenogeneic Silencers

Abstract Horizontal gene transfer (HGT) is a major driving force for bacterial evolution. To avoid the deleterious effects due to the unregulated expression of newly acquired foreign genes, bacteria have evolved specific proteins named xenogeneic silencers to recognize foreign DNA sequences and supp...

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Published in:Molecular biology and evolution 2021-10, Vol.38 (10), p.4135-4148
Main Authors: Duan, Bo, Ding, Pengfei, Navarre, William Wiley, Liu, Jun, Xia, Bin
Format: Article
Language:English
Subjects:
Analysis
Bacteria
Bacterial genetics
Bacterial Proteins - genetics
DNA
DNA sequencing
DNA, Bacterial
DNA-Binding Proteins - genetics
DNA-ligand interactions
Escherichia coli
Gene Silencing
Gene Transfer, Horizontal
Genes
Genetic research
Genetic transcription
Genome, Bacterial
Genomics
Humans
Nucleotide sequencing
Proteins
Review
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container_end_page 4148
container_issue 10
container_start_page 4135
container_title Molecular biology and evolution
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creator Duan, Bo
Ding, Pengfei
Navarre, William Wiley
Liu, Jun
Xia, Bin
description Abstract Horizontal gene transfer (HGT) is a major driving force for bacterial evolution. To avoid the deleterious effects due to the unregulated expression of newly acquired foreign genes, bacteria have evolved specific proteins named xenogeneic silencers to recognize foreign DNA sequences and suppress their transcription. As there is considerable diversity in genomic base compositions among bacteria, how xenogeneic silencers distinguish self- from nonself DNA in different bacteria remains poorly understood. This review summarizes the progress in studying the DNA binding preferences and the underlying molecular mechanisms of known xenogeneic silencer families, represented by H-NS of Escherichia coli, Lsr2 of Mycobacterium, MvaT of Pseudomonas, and Rok of Bacillus. Comparative analyses of the published data indicate that the differences in DNA recognition mechanisms enable these xenogeneic silencers to have clear characteristics in DNA sequence preferences, which are further correlated with different host genomic features. These correlations provide insights into the mechanisms of how these xenogeneic silencers selectively target foreign DNA in different genomic backgrounds. Furthermore, it is revealed that the genomic AT contents of bacterial species with the same xenogeneic silencer family proteins are distributed in a limited range and are generally lower than those species without any known xenogeneic silencers in the same phylum/class/genus, indicating that xenogeneic silencers have multifaceted roles on bacterial genome evolution. In addition to regulating horizontal gene transfer, xenogeneic silencers also act as a selective force against the GC to AT mutational bias found in bacterial genomes and help the host genomic AT contents maintained at relatively low levels.
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These correlations provide insights into the mechanisms of how these xenogeneic silencers selectively target foreign DNA in different genomic backgrounds. Furthermore, it is revealed that the genomic AT contents of bacterial species with the same xenogeneic silencer family proteins are distributed in a limited range and are generally lower than those species without any known xenogeneic silencers in the same phylum/class/genus, indicating that xenogeneic silencers have multifaceted roles on bacterial genome evolution. 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subjects Analysis
Bacteria
Bacterial genetics
Bacterial Proteins - genetics
DNA
DNA sequencing
DNA, Bacterial
DNA-Binding Proteins - genetics
DNA-ligand interactions
Escherichia coli
Gene Silencing
Gene Transfer, Horizontal
Genes
Genetic research
Genetic transcription
Genome, Bacterial
Genomics
Humans
Nucleotide sequencing
Proteins
Review
title Xenogeneic Silencing and Bacterial Genome Evolution: Mechanisms for DNA Recognition Imply Multifaceted Roles of Xenogeneic Silencers
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