Versatility of global transcriptional regulators in alpha-Proteobacteria: from essential cell cycle control to ancillary functions

Recent data indicate that cell cycle transcription in many alpha-Proteobacteria is executed by at least three conserved functional modules in which pairs of antagonistic regulators act jointly, rather than in isolation, to control transcription in S-, G2- or G1-phase. Inactivation of module components often results in pleiotropic defects, ranging from cell death and impaired cell division to fairly benign deficiencies in motility. Expression of module components can follow systemic (cell cycle) or external (nutritional/cell density) cues and may be implemented by auto-regulation, ancillary regulators or other (unknown) mechanisms. Here, we highlight the recent progress in understanding the molecular events and the genetic relationships of the module components in environmental, pathogenic and/or symbiotic alpha-proteobacterial genera. Additionally, we take advantage of the recent genome-wide transcriptional analyses performed in the model alpha-Proteobacterium Caulobacter crescentus to illustrate the complexity of the interactions of the global regulators at selected cell cycle-regulated promoters and we detail the consequences of (mis-)expression when the regulators are absent. This review thus provides the first detailed mechanistic framework for understanding orthologous operational principles acting on cell cycle-regulated promoters in other alpha-Proteobacteri

Protein binding sites involved in the assembly of the KplE1 prophage intasome

AbstractThe organization of the recombination regions of the KplE1 prophage in Escherichia coli K12 differs from that observed in the λ prophage. Indeed, the binding sites characterized for the IntS integrase, the TorI recombination directionality factor (RDF) and the integration host factor (IHF) vary in number, spacing and orientation on the attL and attR regions. In this paper, we performed site-directed mutagenesis of the recombination sites to decipher if all sites are essential for the site-specific recombination reaction and how the KplE1 intasome is assembled. We also show that TorI and IntS form oligomers that are stabilized in the presence of their target DNA. Moreover, we found that IHF is the only nucleoid associated protein (NAP) involved in KplE1 recombination, although it is dispensable. This is consistent with the presence of only one functional IHF site on attR and none on attL

Regulatory (pan-)genome of an obligate intracellular pathogen in the PVC superphylum.

Like other obligate intracellular bacteria, the Chlamydiae feature a compact regulatory genome that remains uncharted owing to poor genetic tractability. Exploiting the reduced number of transcription factors (TFs) encoded in the chlamydial (pan-)genome as a model for TF control supporting the intracellular lifestyle, we determined the conserved landscape of TF specificities by ChIP-Seq (chromatin immunoprecipitation-sequencing) in the chlamydial pathogen Waddlia chondrophila. Among 10 conserved TFs, Euo emerged as a master TF targeting >100 promoters through conserved residues in a DNA excisionase-like winged helix-turn-helix-like (wHTH) fold. Minimal target (Euo) boxes were found in conserved developmentally-regulated genes governing vertical genome transmission (cytokinesis and DNA replication) and genome plasticity (transposases). Our ChIP-Seq analysis with intracellular bacteria not only reveals that global TF regulation is maintained in the reduced regulatory genomes of Chlamydiae, but also predicts that master TFs interpret genomic information in the obligate intracellular α-proteobacteria, including the rickettsiae, from which modern day mitochondria evolved

Tight Regulation of the intS Gene of the KplE1 Prophage: A New Paradigm for Integrase Gene Regulation

Temperate phages have the ability to maintain their genome in their host, a process called lysogeny. For most, passive replication of the phage genome relies on integration into the host's chromosome and becoming a prophage. Prophages remain silent in the absence of stress and replicate passively within their host genome. However, when stressful conditions occur, a prophage excises itself and resumes the viral cycle. Integration and excision of phage genomes are mediated by regulated site-specific recombination catalyzed by tyrosine and serine recombinases. In the KplE1 prophage, site-specific recombination is mediated by the IntS integrase and the TorI recombination directionality factor (RDF). We previously described a sub-family of temperate phages that is characterized by an unusual organization of the recombination module. Consequently, the attL recombination region overlaps with the integrase promoter, and the integrase and RDF genes do not share a common activated promoter upon lytic induction as in the lambda prophage. In this study, we show that the intS gene is tightly regulated by its own product as well as by the TorI RDF protein. In silico analysis revealed that overlap of the attL region with the integrase promoter is widely encountered in prophages present in prokaryotic genomes, suggesting a general occurrence of negatively autoregulated integrase genes. The prediction that these integrase genes are negatively autoregulated was biologically assessed by studying the regulation of several integrase genes from two different Escherichia coli strains. Our results suggest that the majority of tRNA-associated integrase genes in prokaryotic genomes could be autoregulated and that this might be correlated with the recombination efficiency as in KplE1. The consequences of this unprecedented regulation for excisive recombination are discussed

Caracterisation of the KplE1 prophage site-specific recombination module in Escherichia coli : from intasome assembly to genetics regulation

KplE1 est l’un des dix prophages présents sur le chromosome de la souche Escherichia coli K12. Nous avons montré in vivo que ce prophage est compétant pour s’exciser du chromosome bactérien bien qu’il soit incapable de former des particules virales et de lyser son hôte. Au laboratoire, nous avons identifié les protéines IntS (intégrase) et TorI (RDF), codées sur le prophage KplE1, et la protéine IHF (NBP) de l’hôte comme seules impliquées dans le mécanisme de recombinaison spécifique de site (RSS). Nous avons cartographié sur les régions attL et attR, les sites de fixations des protéines de recombinaison permettant l’assemblage de l’intasome, le complexe nucléoprotéique compétant pour la RSS. L’ensemble de ces sites ainsi que les gènes intS et torI qui chevauchent respectivement les régions attL et attR, ont permis de définir un module de recombinaison de type KplE1. Ce module est très conservé et se retrouve chez des phages infectant différentes souches d’E. coli et de shigella. Le modèle en terme de RSS est celui décrit pour les bactériophages de type λ. Cependant, le nombre et l’organisation des sites de recombinaison suggèrent que l’architecture de l’intasome de type KplE1 diffère de celle de λ. Nos résultats renforcent ainsi l’idée que l’assemblage de l’intasome est spécifique du module de RSS considéré même si, in fine, la réaction catalysée demeure similaire.En ce qui concerne l’expression des gènes intS et torI, le fait que ces gènes soient localisés à chacune des extrémités du prophage, rend ainsi impossible leur couplage transcriptionnel à partir d’un promoteur commun au moment de la commutation lyse/lysogénie, tel qu’il est connu pour les phages lambdoïdes. De part son orientation atypique sur attL, la présence de sites de fixations des protéines IntS et TorI au niveau du promoteur du gène intS, nous ont logiquement amené à étudier sa régulation. Nous avons ainsi montré que le gène intS est négativement régulé par son propre produit ainsi que par la protéine RDF TorI. Nos résultats in vivo et in vitro indiquent que l’efficacité de la réaction de recombinaison excisive est intimement liée à la quantité d’intégrase présente, pouvant alors justifier la raison d’être de ce contrôle strict de l’expression du gène intS. En parallèle, une approche in silico a révélé que cette orientation atypique du gène codant pour l’intégrase est largement répandue sur les génomes des prophages, nous amenant à généraliser ce mécanisme atypique de régulation négative de l’intégrase.KplE1 is one of the 10 prophage region present on the Escherichia coli K12 chromosome. We showed in vivo that this prophage is fully competent to excise from the bacterial chromosome, although it is unable to form viral particles and lyse its host. In the laboratory, we have identified Ints (integrase) and TorI (RDF) proteins, encoded on the KplE1 prophage, and the host protein IHF (NBP) only involved in the mechanism of site-specific recombination (SSR). We have mapped on attL and attR regions, the binding sites of recombinant proteins for the assembly of the intasome, the nucleoprotein complex competent for SSR. All of these sites as well as intS and torI genes that overlap respectively attL and attR regions, have permit to define a KplE1 recombination module. This module is highly conserved and is found among phages infecting different E. coli and shigella strains. The model in terms of RSS is that described for λ bacteriophage. However, the number and organization of recombination sites suggests that the architecture of the KplE1 intasome differs from that of λ. Our findings reinforce the idea that the intasome assembly is specific to the SSR module considered even if ultimately the catalyzed reaction is similar.Regarding the intS and torI gene expressions, the fact that these genes are located at each end of the prophage, prevented the transcriptional coupling of these genes from a common promoter when the lysis/lysogeny switch occurs. Because of its atypical orientation on attL, and the presence of IntS and TorI protein binding sites that overlap its promoter region, we have logically studied the regulation of the intS gene. We have shown that intS is negatively regulated by both IntS and TorI proteins. Our in vivo and in vitro results suggest that the efficiency of the excision recombination reaction is closely related to the amount of this integrase, which can justify the strict control of the intS gene expression. In parallel, an in silico approach has revealed that the atypical orientation of the integrase gene is widespread in prophage genomes, leading us to generalize this atypical mechanism of negative regulation of integras

Caracterisation of the KplE1 prophage site-specific recombination module in Escherichia coli (from intasome assembly to genetics regulation)

KplE1 est l un des dix prophages présents sur le chromosome de la souche Escherichia coli K12. Nous avons montré in vivo que ce prophage est compétant pour s exciser du chromosome bactérien bien qu il soit incapable de former des particules virales et de lyser son hôte. Au laboratoire, nous avons identifié les protéines IntS (intégrase) et TorI (RDF), codées sur le prophage KplE1, et la protéine IHF (NBP) de l hôte comme seules impliquées dans le mécanisme de recombinaison spécifique de site (RSS). Nous avons cartographié sur les régions attL et attR, les sites de fixations des protéines de recombinaison permettant l assemblage de l intasome, le complexe nucléoprotéique compétant pour la RSS. L ensemble de ces sites ainsi que les gènes intS et torI qui chevauchent respectivement les régions attL et attR, ont permis de définir un module de recombinaison de type KplE1. Ce module est très conservé et se retrouve chez des phages infectant différentes souches d E. coli et de shigella. Le modèle en terme de RSS est celui décrit pour les bactériophages de type . Cependant, le nombre et l organisation des sites de recombinaison suggèrent que l architecture de l intasome de type KplE1 diffère de celle de . Nos résultats renforcent ainsi l idée que l assemblage de l intasome est spécifique du module de RSS considéré même si, in fine, la réaction catalysée demeure similaire.En ce qui concerne l expression des gènes intS et torI, le fait que ces gènes soient localisés à chacune des extrémités du prophage, rend ainsi impossible leur couplage transcriptionnel à partir d un promoteur commun au moment de la commutation lyse/lysogénie, tel qu il est connu pour les phages lambdoïdes. De part son orientation atypique sur attL, la présence de sites de fixations des protéines IntS et TorI au niveau du promoteur du gène intS, nous ont logiquement amené à étudier sa régulation. Nous avons ainsi montré que le gène intS est négativement régulé par son propre produit ainsi que par la protéine RDF TorI. Nos résultats in vivo et in vitro indiquent que l efficacité de la réaction de recombinaison excisive est intimement liée à la quantité d intégrase présente, pouvant alors justifier la raison d être de ce contrôle strict de l expression du gène intS. En parallèle, une approche in silico a révélé que cette orientation atypique du gène codant pour l intégrase est largement répandue sur les génomes des prophages, nous amenant à généraliser ce mécanisme atypique de régulation négative de l intégrase.KplE1 is one of the 10 prophage region present on the Escherichia coli K12 chromosome. We showed in vivo that this prophage is fully competent to excise from the bacterial chromosome, although it is unable to form viral particles and lyse its host. In the laboratory, we have identified Ints (integrase) and TorI (RDF) proteins, encoded on the KplE1 prophage, and the host protein IHF (NBP) only involved in the mechanism of site-specific recombination (SSR). We have mapped on attL and attR regions, the binding sites of recombinant proteins for the assembly of the intasome, the nucleoprotein complex competent for SSR. All of these sites as well as intS and torI genes that overlap respectively attL and attR regions, have permit to define a KplE1 recombination module. This module is highly conserved and is found among phages infecting different E. coli and shigella strains. The model in terms of RSS is that described for bacteriophage. However, the number and organization of recombination sites suggests that the architecture of the KplE1 intasome differs from that of . Our findings reinforce the idea that the intasome assembly is specific to the SSR module considered even if ultimately the catalyzed reaction is similar.Regarding the intS and torI gene expressions, the fact that these genes are located at each end of the prophage, prevented the transcriptional coupling of these genes from a common promoter when the lysis/lysogeny switch occurs. Because of its atypical orientation on attL, and the presence of IntS and TorI protein binding sites that overlap its promoter region, we have logically studied the regulation of the intS gene. We have shown that intS is negatively regulated by both IntS and TorI proteins. Our in vivo and in vitro results suggest that the efficiency of the excision recombination reaction is closely related to the amount of this integrase, which can justify the strict control of the intS gene expression. In parallel, an in silico approach has revealed that the atypical orientation of the integrase gene is widespread in prophage genomes, leading us to generalize this atypical mechanism of negative regulation of integraseAIX-MARSEILLE2-Bib.electronique (130559901) / SudocSudocFranceF

Complete Genome Sequence of Caulobacter crescentus Bacteriophage φCbK

φCbK is a B3 morphotype bacteriophage of the Siphoviridae family that infects Caulobacter crescentus, the preeminent model system for bacterial cell cycle studies. The last 4 decades of research with φCbK as a genetic and cytological tool to study the biology of the host warrant an investigation of the phage genome composition. Herein, we report the complete genome sequence of φCbK and highlight unusual features that emerged from its annotation. The complete genome analysis of the φCbK phage provides new insight into its characteristics and potential interactions with its Caulobacter crescentus host, setting the stage for future functional studies with φCbK

Control and Regulation of KplE1 Prophage Site-specific Recombination

International audienc

More than a Tad: spatiotemporal control of Caulobacter pili

The Type IV pilus (T4P) is a powerful and sophisticated bacterial nanomachine involved in numerous cellular processes, including adhesion, DNA uptake and motility. Aside from the well-described subtype T4aP of the Gram-negative genera, including Myxococcus, Pseudomonas and Neisseria, the Tad (tight adherence) pilus secretion system re-shuffles homologous parts from other secretion systems along with uncharacterized components into a new type of protein translocation apparatus. A representative of the Tad apparatus, the Caulobacter crescentus pilus assembly (Cpa) machine is built exclusively at the newborn cell pole once per cell cycle. Recent comprehensive genetic analyses unearthed a myriad of spatiotemporal determinants acting on the Tad/Cpa system, many of which are conserved in other α-proteobacteria, including obligate intracellular pathogens and symbionts