Staphylococcus aureus RNAIII Binds to Two Distant Regions of coa mRNA to Arrest Translation and Promote mRNA Degradation

Staphylococcus aureus RNAIII is the intracellular effector of the quorum sensing system that temporally controls a large number of virulence factors including exoproteins and cell-wall-associated proteins. Staphylocoagulase is one major virulence factor, which promotes clotting of human plasma. Like the major cell surface protein A, the expression of staphylocoagulase is strongly repressed by the quorum sensing system at the post-exponential growth phase. Here we used a combination of approaches in vivo and in vitro to analyze the mechanism used by RNAIII to regulate the expression of staphylocoagulase. Our data show that RNAIII represses the synthesis of the protein through a direct binding with the mRNA. Structure mapping shows that two distant regions of RNAIII interact with coa mRNA and that the mRNA harbors a conserved signature as found in other RNAIII-target mRNAs. The resulting complex is composed of an imperfect duplex masking the Shine-Dalgarno sequence of coa mRNA and of a loop-loop interaction occurring downstream in the coding region. The imperfect duplex is sufficient to prevent the formation of the ribosomal initiation complex and to repress the expression of a reporter gene in vivo. In addition, the double-strand-specific endoribonuclease III cleaves the two regions of the mRNA bound to RNAIII that may contribute to the degradation of the repressed mRNA. This study validates another direct target of RNAIII that plays a role in virulence. It also illustrates the diversity of RNAIII-mRNA topologies and how these multiple RNAIII-mRNA interactions would mediate virulence regulation

Function of novel non coding RNAs in gene regulation in Staphylococcus aureus : adaptation to environment and virulence

Staphylococcus aureus, pathogène opportuniste de l’homme, est responsable de 30% des infections nosocomiales. L’apparition de souches multi résistantes aux antibiotiques en font un problème majeur de santé publique. La pathogénie de la bactérie résulte de l’expression d’une pléthore de facteurs de virulence, mais quels sont les mécanismes de régulation contrôlant l’expression de ces gènes ? Aujourd’hui, il est clairement établi que les ARN non-codant sont des molécules clés dans la régulation de l’expression des gènes. Plus de 50 ARN ont été identifiés chez S. aureus. Néanmoins la fonction de peu d’entre eux est connue. Durant ce travail de thèse, l’étude de la fonction et du mécanisme de régulation des ARN RsaA et RsaE a été entreprise. RsaA est un ARN sous le contrôle du facteur de stress sigmaB. Les résultats obtenus montrent que ce dernier régule la traduction de l’ARNm mgrA qui code pour un facteur de transcription important dans l’expression des gènes de virulence et la régulation de l’autolyse. Par appariement de base, RsaA cible l’ARNm en utilisant deux sites distants et coopératifs, permettant un interaction forte qui empêche la traduction de l’ARNm. In vivo, la délétion du gène rsaA perturbe la synthèse de biofilm de capsule. En régulant la traduction de sa cible, RsaA permet de relier l’adaptation au stress à l’expression des gènes de virulence. De manière plus générale, les réseaux de régulation des ARN se connectent les uns aux autres pour permettre à la bactérie d’intégrer une multitude de signaux provenant du milieu extracellulaire afin de moduler finement l’expression des gènes.Staphylococcus aureus is a versatile and opportunist human pathogen, which is responsible of 30% of nosocomial infections. S. aureus is today an important public safety concern due to high persistence rate in hospital combined with emergence of multi resistant strains against antibiotics. The pathogenicity of the bacteria results from the expression of numerous virulence factors. An importance focus has been made to understand what triggers virulence genes expression. Regulatory RNAs are important regulators of genes expression in bacteria. In S. aureus, there is more than 50 RNAs identified, but there is a lack of investigations about their functions and regulatory networks. The aim of this work was to characterize the function and mechanism of action of RsaA and RsaE RNAs. RsaA is under the control of the stress factor sigma B. Computational analysis combined with global analysis of the proteome led to the discovery of one target : mgrA mRNA, which is a global transcription factor involved in autolysis and biofilm regulation. In vitro studies show that RsaA binds efficiently mgrA mRNA using two distant and cooperative interaction sites. Binding of RsaA to the mRNA prevents initiation of the translation. In vivo, rsaA gene deletion shows impact on biofilm and capsule production. By regulating the expression of mgrA mRNA, RsaA network is linked to agr system and virulence gene expression. In a more general way, this work shows that regulatory RNAs networks allow bacteria to modulate virulence, stress and metabolism gene expression depending on the signals provided by the environment of the bacteria

Function of novel non coding RNAs in gene regulation in Staphylococcus aureus : adaptation to environment and virulence

Staphylococcus aureus, pathogène opportuniste de l’homme, est responsable de 30% des infections nosocomiales. L’apparition de souches multi résistantes aux antibiotiques en font un problème majeur de santé publique. La pathogénie de la bactérie résulte de l’expression d’une pléthore de facteurs de virulence, mais quels sont les mécanismes de régulation contrôlant l’expression de ces gènes ? Aujourd’hui, il est clairement établi que les ARN non-codant sont des molécules clés dans la régulation de l’expression des gènes. Plus de 50 ARN ont été identifiés chez S. aureus. Néanmoins la fonction de peu d’entre eux est connue. Durant ce travail de thèse, l’étude de la fonction et du mécanisme de régulation des ARN RsaA et RsaE a été entreprise. RsaA est un ARN sous le contrôle du facteur de stress sigmaB. Les résultats obtenus montrent que ce dernier régule la traduction de l’ARNm mgrA qui code pour un facteur de transcription important dans l’expression des gènes de virulence et la régulation de l’autolyse. Par appariement de base, RsaA cible l’ARNm en utilisant deux sites distants et coopératifs, permettant un interaction forte qui empêche la traduction de l’ARNm. In vivo, la délétion du gène rsaA perturbe la synthèse de biofilm de capsule. En régulant la traduction de sa cible, RsaA permet de relier l’adaptation au stress à l’expression des gènes de virulence. De manière plus générale, les réseaux de régulation des ARN se connectent les uns aux autres pour permettre à la bactérie d’intégrer une multitude de signaux provenant du milieu extracellulaire afin de moduler finement l’expression des gènes.Staphylococcus aureus is a versatile and opportunist human pathogen, which is responsible of 30% of nosocomial infections. S. aureus is today an important public safety concern due to high persistence rate in hospital combined with emergence of multi resistant strains against antibiotics. The pathogenicity of the bacteria results from the expression of numerous virulence factors. An importance focus has been made to understand what triggers virulence genes expression. Regulatory RNAs are important regulators of genes expression in bacteria. In S. aureus, there is more than 50 RNAs identified, but there is a lack of investigations about their functions and regulatory networks. The aim of this work was to characterize the function and mechanism of action of RsaA and RsaE RNAs. RsaA is under the control of the stress factor sigma B. Computational analysis combined with global analysis of the proteome led to the discovery of one target : mgrA mRNA, which is a global transcription factor involved in autolysis and biofilm regulation. In vitro studies show that RsaA binds efficiently mgrA mRNA using two distant and cooperative interaction sites. Binding of RsaA to the mRNA prevents initiation of the translation. In vivo, rsaA gene deletion shows impact on biofilm and capsule production. By regulating the expression of mgrA mRNA, RsaA network is linked to agr system and virulence gene expression. In a more general way, this work shows that regulatory RNAs networks allow bacteria to modulate virulence, stress and metabolism gene expression depending on the signals provided by the environment of the bacteria

Fonctions de nouveaux ARN non codant dans la régulation de l'expression des gènes chez Staphylococcus aureus : adaptation à l'environnement et virulence

Staphylococcus aureus is a versatile and opportunist human pathogen, which is responsible of 30% of nosocomial infections. S. aureus is today an important public safety concern due to high persistence rate in hospital combined with emergence of multi resistant strains against antibiotics. The pathogenicity of the bacteria results from the expression of numerous virulence factors. An importance focus has been made to understand what triggers virulence genes expression. Regulatory RNAs are important regulators of genes expression in bacteria. In S. aureus, there is more than 50 RNAs identified, but there is a lack of investigations about their functions and regulatory networks. The aim of this work was to characterize the function and mechanism of action of RsaA and RsaE RNAs. RsaA is under the control of the stress factor sigma B. Computational analysis combined with global analysis of the proteome led to the discovery of one target : mgrA mRNA, which is a global transcription factor involved in autolysis and biofilm regulation. In vitro studies show that RsaA binds efficiently mgrA mRNA using two distant and cooperative interaction sites. Binding of RsaA to the mRNA prevents initiation of the translation. In vivo, rsaA gene deletion shows impact on biofilm and capsule production. By regulating the expression of mgrA mRNA, RsaA network is linked to agr system and virulence gene expression. In a more general way, this work shows that regulatory RNAs networks allow bacteria to modulate virulence, stress and metabolism gene expression depending on the signals provided by the environment of the bacteria.Staphylococcus aureus, pathogène opportuniste de l’homme, est responsable de 30% des infections nosocomiales. L’apparition de souches multi résistantes aux antibiotiques en font un problème majeur de santé publique. La pathogénie de la bactérie résulte de l’expression d’une pléthore de facteurs de virulence, mais quels sont les mécanismes de régulation contrôlant l’expression de ces gènes ? Aujourd’hui, il est clairement établi que les ARN non-codant sont des molécules clés dans la régulation de l’expression des gènes. Plus de 50 ARN ont été identifiés chez S. aureus. Néanmoins la fonction de peu d’entre eux est connue. Durant ce travail de thèse, l’étude de la fonction et du mécanisme de régulation des ARN RsaA et RsaE a été entreprise. RsaA est un ARN sous le contrôle du facteur de stress sigmaB. Les résultats obtenus montrent que ce dernier régule la traduction de l’ARNm mgrA qui code pour un facteur de transcription important dans l’expression des gènes de virulence et la régulation de l’autolyse. Par appariement de base, RsaA cible l’ARNm en utilisant deux sites distants et coopératifs, permettant un interaction forte qui empêche la traduction de l’ARNm. In vivo, la délétion du gène rsaA perturbe la synthèse de biofilm de capsule. En régulant la traduction de sa cible, RsaA permet de relier l’adaptation au stress à l’expression des gènes de virulence. De manière plus générale, les réseaux de régulation des ARN se connectent les uns aux autres pour permettre à la bactérie d’intégrer une multitude de signaux provenant du milieu extracellulaire afin de moduler finement l’expression des gènes

Fonctions de nouveaux ARN non codant dans la régulation de l'expression des gènes chez Staphylococcus aureus (adaptation à l'environnement et virulence)

Staphylococcus aureus, pathogène opportuniste de l homme, est responsable de 30% des infections nosocomiales. L apparition de souches multi résistantes aux antibiotiques en font un problème majeur de santé publique. La pathogénie de la bactérie résulte de l expression d une pléthore de facteurs de virulence, mais quels sont les mécanismes de régulation contrôlant l expression de ces gènes ? Aujourd hui, il est clairement établi que les ARN non-codant sont des molécules clés dans la régulation de l expression des gènes. Plus de 50 ARN ont été identifiés chez S. aureus. Néanmoins la fonction de peu d entre eux est connue. Durant ce travail de thèse, l étude de la fonction et du mécanisme de régulation des ARN RsaA et RsaE a été entreprise. RsaA est un ARN sous le contrôle du facteur de stress sigmaB. Les résultats obtenus montrent que ce dernier régule la traduction de l ARNm mgrA qui code pour un facteur de transcription important dans l expression des gènes de virulence et la régulation de l autolyse. Par appariement de base, RsaA cible l ARNm en utilisant deux sites distants et coopératifs, permettant un interaction forte qui empêche la traduction de l ARNm. In vivo, la délétion du gène rsaA perturbe la synthèse de biofilm de capsule. En régulant la traduction de sa cible, RsaA permet de relier l adaptation au stress à l expression des gènes de virulence. De manière plus générale, les réseaux de régulation des ARN se connectent les uns aux autres pour permettre à la bactérie d intégrer une multitude de signaux provenant du milieu extracellulaire afin de moduler finement l expression des gènes.Staphylococcus aureus is a versatile and opportunist human pathogen, which is responsible of 30% of nosocomial infections. S. aureus is today an important public safety concern due to high persistence rate in hospital combined with emergence of multi resistant strains against antibiotics. The pathogenicity of the bacteria results from the expression of numerous virulence factors. An importance focus has been made to understand what triggers virulence genes expression. Regulatory RNAs are important regulators of genes expression in bacteria. In S. aureus, there is more than 50 RNAsidentified, but there is a lack of investigations about their functions and regulatory networks. The aim of this work was to characterize the function and mechanism of action of RsaA and RsaE RNAs. RsaA is under the control of the stress factorsigmaB. Computational analysis combined with global analysis of the proteome led to the discovery of one target : mgrA mRNA, which is a global transcription factor involved in autolysis and biofilm regulation. In vitro studies show that RsaA binds efficiently mgrA mRNA using two distant and cooperative interaction sites. Binding of RsaA to the mRNA prevents initiation of the translation. In vivo, rsaA gene deletion shows impact on biofilm and capsule production. By regulating the expression of mgrA mRNA, RsaA network is linked to agr system and virulence gene expression. In a more general way, this work shows that regulatory RNAs networks allow bacteria to modulate virulence, stress and metabolism gene expression depending on the signals provided by the environment of the bacteria.STRASBOURG-Bib.electronique 063 (674829902) / SudocSudocFranceF

L’ARN non codant RsaA favorise la persistance et atténue la virulence de Staphylococcus aureus

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A Non-Coding RNA Promotes Bacterial Persistence and Decreases Virulence by Regulating a Regulator in Staphylococcus aureus.

International audienceStaphylococcus aureus produces a high number of RNAs for which the functions are poorly understood. Several non-coding RNAs carry a C-rich sequence suggesting that they regulate mRNAs at the post-transcriptional level. We demonstrate that the Sigma B-dependent RsaA RNA represses the synthesis of the global transcriptional regulator MgrA by forming an imperfect duplex with the Shine and Dalgarno sequence and a loop-loop interaction within the coding region of the target mRNA. These two recognition sites are required for translation repression. Consequently, RsaA causes enhanced production of biofilm and a decreased synthesis of capsule formation in several strain backgrounds. These phenotypes led to a decreased protection of S. aureus against opsonophagocytic killing by polymorphonuclear leukocytes compared to the mutant strains lacking RsaA. Mice animal models showed that RsaA attenuates the severity of acute systemic infections and enhances chronic catheter infection. RsaA takes part in a regulatory network that contributes to the complex interactions of S. aureus with the host immune system to moderate invasiveness and favour chronic infections. It is the first example of a conserved small RNA in S. aureus functioning as a virulence suppressor of acute infections. Because S. aureus is essentially a human commensal, we propose that RsaA has been positively selected through evolution to support commensalism and saprophytic interactions with the host

A nitric oxide regulated small RNA controls expression of genes involved in redox homeostasis in Bacillus subtilis

RsaE is the only known trans-acting small regulatory RNA (sRNA) besides the ubiquitous 6S RNA that is conserved between the human pathogen Staphylococcus aureus and the soil-dwelling Firmicute Bacillus subtilis. Although a number of RsaE targets are known in S. aureus, neither the environmental signals that lead to its expression nor its physiological role are known. Here we show that expression of the B. subtilis homolog of RsaE is regulated by the presence of nitric oxide (NO) in the cellular milieu. Control of expression by NO is dependent on the ResDE two-component system in B. subtilis and we determined that the same is true in S. aureus. Transcriptome and proteome analyses revealed that many genes with functions related to oxidative stress and oxidation-reduction reactions were up-regulated in a B. subtilis strain lacking this sRNA. We have thus renamed it RoxS. The prediction of RoxS-dependent mRNA targets also suggested a significant enrichment for mRNAs related to respiration and electron transfer. Among the potential direct mRNA targets, we have validated the ppnKB mRNA, encoding an NAD(+)/NADH kinase, both in vivo and in vitro. RoxS controls both translation initiation and the stability of this transcript, in the latter case via two independent pathways implicating RNase Y and RNase III. Furthermore, RNase Y intervenes at an additional level by processing the 50 end of the RoxS sRNA removing about 20 nucleotides. Processing of RoxS allows it to interact more efficiently with a second target, the sucCD mRNA, encoding succinyl-CoA synthase, thus expanding the repertoire of targets recognized by this sRNA