Genomic Location of the Major Ribosomal Protein Gene Locus Determines Vibrio cholerae Global Growth and Infectivity: e1005156

The effects on cell physiology of gene order within the bacterial chromosome are poorly understood. In silico approaches have shown that genes involved in transcription and translation processes, in particular ribosomal protein (RP) genes, localize near the replication origin (oriC) in fast-growing...

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Published in:PLoS genetics 2015-04, Vol.11 (4)
Main Authors: Soler-Bistué, Alfonso, Mondotte, Juan A, Bland, Michael Jason, Val, Marie-Eve, Saleh, María-Carla, Mazel, Didier
Format: Article
Language:English
Subjects:
Bacteria
Bacteriology
Cell division
Chromosomes
Deoxyribonucleic acid
DNA
Drosophila melanogaster
Experiments
Gene expression
Genomes
Growth rate
Insects
Microscopy
Physiology
Proteins
RNA polymerase
Studies
Vibrio cholerae
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container_title PLoS genetics
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Mondotte, Juan A
Bland, Michael Jason
Val, Marie-Eve
Saleh, María-Carla
Mazel, Didier
description The effects on cell physiology of gene order within the bacterial chromosome are poorly understood. In silico approaches have shown that genes involved in transcription and translation processes, in particular ribosomal protein (RP) genes, localize near the replication origin (oriC) in fast-growing bacteria suggesting that such a positional bias is an evolutionarily conserved growth-optimization strategy. Such genomic localization could either provide a higher dosage of these genes during fast growth or facilitate the assembly of ribosomes and transcription foci by keeping physically close the many components of these macromolecular machines. To explore this, we used novel recombineering tools to create a set of Vibrio cholerae strains in which S10-spec-α (S10), a locus bearing half of the ribosomal protein genes, was systematically relocated to alternative genomic positions. We show that the relative distance of S10 to the origin of replication tightly correlated with a reduction of S10 dosage, mRNA abundance and growth rate within these otherwise isogenic strains. Furthermore, this was accompanied by a significant reduction in the host-invasion capacity in Drosophila melanogaster. Both phenotypes were rescued in strains bearing two S10 copies highly distal to oriC, demonstrating that replication-dependent gene dosage reduction is the main mechanism behind these alterations. Hence, S10 positioning connects genome structure to cell physiology in Vibrio cholerae. Our results show experimentally for the first time that genomic positioning of genes involved in the flux of genetic information conditions global growth control and hence bacterial physiology and potentially its evolution.
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subjects Bacteria
Bacteriology
Cell division
Chromosomes
Deoxyribonucleic acid
DNA
Drosophila melanogaster
Experiments
Gene expression
Genomes
Growth rate
Insects
Microscopy
Physiology
Proteins
RNA polymerase
Studies
Vibrio cholerae
title Genomic Location of the Major Ribosomal Protein Gene Locus Determines Vibrio cholerae Global Growth and Infectivity: e1005156
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