Biochemical and Structural Studies on PrfA, the Transcriptional Regulator of Virulence in Listeria monocytogenes

Hamilton, Keri

January 2016

<p>Abstract</p><p>Listeria monocytogenes is a gram-positive soil saprophytic bacterium that is capable of causing fatal infection in humans. The main virulence regulator PrfA, a member of the Crp/FNR family of transcriptional regulators, activates the expression of essential proteins required for host cell invasion and cell-to-cell spread. The mechanism of PrfA activation and the identity of its small molecule coactivator have remained a mystery for more than 20 years, but it is hypothesized that PrfA shares mechanistic similarity to the E. coli cAMP binding protein, Crp. Crp activates gene expression by binding cAMP, increasing the DNA binding affinity of the protein and causing a significant DNA bend that facilitates RNA polymerase binding and downstream gene activation. Our data suggests PrfA activates virulence protein expression through a mechanism distinct from the canonical Crp activation mechanism that involves a combination of cysteine residue reduction and glutathione (GSH) binding. </p><p>Listeria lacking glutathione synthase (ΔgshF) is avirulent in mice; however virulence is rescued when the bacterium expresses the constitutively active PrfA mutant G145S. Interestingly, Listeria expressing a PrfA mutant in which its four cysteines are mutated to alanine (Quad PrfA), demonstrate a 30-fold decrease in virulence. The Quad and ΔgshF double mutant strains are avirulent. DNA-binding affinity, measured through fluorescence polarization assays, indicate reduction of the cysteine side chains is sufficient to allow PrfA to binds its physiological promoters Phly and PactA with low nanomolar affinity. Oxidized PrfA binds the promoters poorly. </p><p>Unexpectedly, Quad also binds promoter DNA with nanomolar affinity, suggesting that the cysteines play a role in transcription efficiency in addition to DNA binding. Both PrfA and Quad bind GSH at physiologically relevant and comparable affinities, however GSH did not affect DNA binding in either case. Thermal denaturation assays suggest that Quad and wild-type PrfA differ structurally upon binding GSH, which supports the in vivo difference in infection between the regulator and its mutant. </p><p>Structures of PrfA in complex with cognate DNA, determined through X-ray crystallography, further support the disparity between PrfA and Crp activation mechanisms as two structures of reduced PrfA bound to Phly (PrfA-Phly30 and PrfA-Phly24) suggest the DNA adopts a less bent DNA conformation when compared to Crp-cAMP- DNA. The structure of Quad-Phly30 confirms the DNA-binding data as the protein-DNA complex adopts the same overall conformation as PrfA-Phly. </p><p>From these results, we hypothesize a two-step activation mechanism wherein PrfA, oxidized upon cell entry and unable to bind DNA, is reduced upon its intracellular release and binds DNA, causing a slight bend in the promoter and small increase in transcription of PrfA-regulated genes. The structures of PrfA-Phly30 and PrfA-Phly24 likely visualize this intermediate complex. Increasing concentrations of GSH shift the protein to a (PrfA-GSH)-DNA complex which is fully active transcriptionally and is hypothesized to resemble closely the transcriptionally active structure of the cAMP-(Crp)-DNA complex. Thermal denaturation results suggest Quad PrfA is deficient in this second step, which explains the decrease in virulence and implicates the cysteine residues as critical for transcription efficiency. Further structural and biochemical studies are on-going to clarify this mechanism of activation.</p> / Dissertation

Biochemistry

PrfA

Transcription

Regulatory pathways and virulence inhibition in Listeria monocytogenes

Andersson, Christopher

January 2016

Listeria monocytogenes is a rod-shaped Gram positive bacterium. It generally exist ubiquitously in nature, where it lives as a saprophyte. Occasionally it however enters the food chain, from where it can be ingested by humans and cause gastro-intestinal distress. In immunocompetent individuals L. monocytogenes is generally cleared within a couple of weeks, but in immunocompromised patients it can progress to listeriosis, a potentially life-threatening infection in the central nervous system. If the infected individual is pregnant, the bacteria can cross the placental barrier and infect the fetus, possibly leading to spontaneous abortion. The infectivity of L. monocytogenes requires a certain set of genes, and the majority of them is dependent on the transcriptional regulator PrfA. The expression and activity of PrfA is controlled at several levels, and has traditionally been viewed to be active at 37 °C (virulence conditions) where it bind as a homodimer to a “PrfA-box” and induces the expression of the downstream gene. One of these genes is ActA, which enables intracellular movement by recruiting an actin polymerizing protein complex. When studying the effects of a blue light receptor we surprisingly found an effect of ActA at non-virulent conditions, where it is required for the bacteria to properly react to light exposure. To further study the PrfA regulon we tested deletion mutants of several PrfA-regulated virulence genes in chicken embryo infection studies. Based on these studies we could conclude that the chicken embryo model is a viable complement to traditional murine models, especially when investigating non-traditional internalin pathogenicity pathways. We have also studied the effects of small molecule virulence inhibitors that, by acting on PrfA, can inhibit L. monocytogenes infectivity in cell cultures with concentrations in the low micro-molar range.

Listeria monocytogenes

PrfA

ActA

infection

Einfluss des Kohlenstoff-Metabolismus auf die Aktivität des Virulenzfaktors PrfA von Listeria monocytogenes / Effect of the carbon metabolism on the PrfA activity in Listeria monocytogenes

Mertins, Sonja

January 2008

Listeria monocytogenes gehört zu den Gram-positiven fakultativ intrazellulären Bakterien, ist aber auch zu einem saprophytischen Leben in freier Natur fähig. Zahlreiche, umfassend charakterisierte Virulenzfaktoren sind für die verschiedenen Schritte im Infektionszyklus von L. monocytogenes erforderlich: InlA und InlB induzieren die Aufnahme von L. monocytogenes in nicht-phagozytische Zellen, LLO und PlcA sind für die Freisetzung aus dem primären Phagosom, ActA für die Zell-zu-Zell-Ausbreitung und LLO zusammen mit PlcA und vor allem PlcB für die Freisetzung der Listerien aus dem sekundären Phagosom erforderlich. Der Hexose-Phosphat-Transporter UhpT ist teilweise für die Vermehrung von L. monocytogenes im Zytosol der infizierten Wirtszelle verantwortlich. Die Gene, die für diese Virulenzfaktoren kodieren, sind größtenteils in dem 9,6 kb-großen Virulenzgencluster LIPI-1 zusammengefasst oder liegen verteilt auf dem Chromosom. Alle diese Virulenzgene werden durch den positiven Regulationsfaktor PrfA (PrfA = positive regulatory factor A) in ihrer Transkription kontrolliert. Das prfA-Gen, kodierend für PrfA, ist benfalls Bestandteil des Virulenzgenclusters (LIPI-1). In bisherigen Studien konnte gezeigt werden, dass die Verwertung der Kohlenstoffquellen Glukose, Mannose und Cellobiose zur Hemmung der PrfA-Aktivität in L. monocytogenes führt. Basierend auf Literaturdaten und eigenen Ergebnissen wurde die Hypothese aufgestellt, dass Komponenten der globalen Kohlenstoff-Katabolitrepression (KKR) oder des PTS (Phosphoenolpyruvat-Phosphotransferase-System)-abhängigen Zuckertransports an der Modulation der PrfA-Aktivität beteiligt sind. Um zu überprüfen, ob über die KKR die Aktivität von PrfA gesteuert wird und dadurch auch die Regulation der PrfA-abhängigen Virulenzgenexpression, wurden in dieser Arbeit pLSV101-Insertionsmutanten für die Gene ccpA (kodierend für CcpA = catabolite control protein A), hprK (kodierend für die HPr-Kinase/Phosphorylase, die HPr am Ser46 phophoryliert) und ptsH (kodierend für das hitzestabile HPr) charakterisiert. Die Insertionsmutanten ::ccpA und ::hprK zeigten sowohl in BHI (undefiniertes nährstoffreiches Medium) als auch in definiertem Minimalmedium (MM) mit 50 mM Glukose ein verlangsamtes Wachstum und eine verringerte [14C]-Glukose-Aufnahme im Vergleich zum Wildtyp (WT). Die ::ptsH-Insertionsmutante war nur zu einem Wachstum in BHI fähig und zeigte erwartungsgemäß (fehlendes HPr) kein Wachstum in definiertem MM mit Glukose als einziger Kohlenstoffquelle. Die ::hprK- und (unter bestimmten Wachstumsbedingungen) auch die ::ptsH–Mutante wiesen sowohl auf Transkriptions- als auch auf Translationsebene eine gesteigerte Expression PrfA-abhängiger Virulenzgene auf. Cellobiose-Verwertung führte auch in der ::hprK-Insertionsmutante zu einer Hemmung der PrfA-Aktivität. Dagegen wurde in der ::ccpA-Insertionsmutante eine geringere Expression aller PrfA-abhängigen Virulenzgene im Vergleich zum WT festgestellt. Die Revertanten RccpA, RhprK und RptsH wiesen im Wachstumsverhalten und in der PrfA-abhängigen Virulenzgenexpression wieder einen wildtypischen Phänotyp auf. Trotz der etwas gesteigerten Virulenzgenexpression zeigte die ::ptsH-Mutante eine deutlich verringerte Replikationsrate in J744 Makrophagen gegenüber dem WT. Die Transkriptomprofile der ::ccpA- und ::hprK-Insertionsmutanten zeigten im Vergleich zum WT viele hochregulierte Gene. Diese umfassen Gene, die v.a. für den PTS-abhängigen Zuckertransport, ABC-Transporter und Enzyme des C- und N-Metabolismus kodieren und im WT wahrscheinlich unter den gegebenen Wachstumsbedingungen unter KKR-Kontrolle stehen. Die erhöhte PrfA-abhängige Virulenzgenexpression in der ::hprK-Mutante korreliert mit der Herunterregulation einiger Gene, die in ihrer Transkription durch einen aktiven PTSvermittelten Glukose-Transport kontrolliert werden. Die gesteigerte PrfA-Aktivität und die Abwesenheit von HPr-Ser46~P (neben CcpA eine wichtige Komponente der KKR) in den ::hprK- und ::ptsH-Insertionsmutanten führten zu der Annahme, dass eine Korrelation zwischen der Menge an HPr-Ser46~P und der PrfA-Aktivität bestehen könnte. Die Untersuchung der PrfA-Aktivität und parallel dazu die Mengenbestimmung von HPr-Ser46~P in MM mit Glukose, Cellobiose und Glyzerin zeigte jedoch, dass weder HPr-Ser46~P noch HPr-His15~P direkte Modulatoren der PrfA-Aktivität sind. Eine direkte Interaktion zwischen HPr-Ser46~P und PrfA konnte mittels Biacor-Analyse ebenfalls nicht nachgewiesen werden. Auch in vitro Transkriptions-Studien zeigten keinen inhibitorischen Effekt von HPr-Ser46~P auf die Initiation der Transkription bei PrfA-abhängigen Promotoren (S. Müller-Altrock, persönliche Mitteilung). Interessanterweise war bei einem aktiven Glukose-Transport, bei Bedingungen also, wo die EIIA-Komponenten aller aktiven Glukose-spezifischen PTS im unphosphoryliertem Zustand vorliegen (EIIA-Komponenten übertragen über EIIB das aktive Phosphat auf die über EIIC in die Bakterienzelle transportierte Glukose), die PrfA-Aktivität gering. Erst in der spätlogarithmischen bis stationären Wachstumsphasen, wenn Glukose nur noch in geringem Umfang von der Bakterienzelle aufgenommen wird und die Glukose-spezifischen EIIA-Komponenten in phosphorylierter Form vorliegen, steigt die PrfA-Aktivität. Die Verwertung der PTS-unabhängigen Kohlenstoffquelle Glyzerin zeigte gegenüber den PTS Zuckern Glukose und Cellobiose schon in der frühen Wachstumsphase eine erhöhte PrfA-Aktivität. Demnach scheint sich die Expression spezifischer PTS und der Phosphorylierungszustand von EIIA dieser PTS regulatorisch auf die PrfA-Aktivität auszuwirken. Die Glukose-Aufnahme in L. monocytogenes ist noch nicht vollständig aufgeklärt (R. Stoll, unveröffentlichte Ergebnisse). Doch kann aufgrund des Wachstumsverlustes der ::ptsH-Insertionsmutante in Glukose-haltigem MM davon ausgegangen werden, dass die Glukose-Aufnahme in L. monocytogenes ausschließlich PTS-abhängig erfolgt. Ein Glukose-spezifisches PtsG, das in B. subtilis und anderen Bakterien als wichtiger Glukose-Transporter beschrieben wurde, existiert in L. monocytogenes nicht. Hier konnte nur eine PtsG-spezifische EIIA-Komponente (kodiert von lmo1017) identifiziert werden. Wachstumsuntersuchungen in definiertem MM mit den Kohlenstoffquellen Glukose, Mannose, Cellobiose und Glyzerin ergaben keinen Wachstumsunterschied zwischen der in dieser Komponente defekten &#916;eIIAGlc-Mutante und dem WT. Die PrfA-Aktivität dieser Mutante war leicht erhöht, was sich in einer etwas gesteigerten ActA- bzw. PrfA-Expression und einer höheren LLO-Aktivität gegenüber dem WT ausprägte. Es konnte jedoch keine eindeutige Interaktion zwischen dieser gereinigten EIIAGlc-Komponente und dem PrfA-Protein mittels Biacor-Analyse nachgewiesen werden (S. Müller-Altrock und G. Seidel, persönliche Mitteilung). Welche EIIA-Komponenten spezifischer PTS an der Modulation der PrfA-Aktivität beteiligt sind, konnte in dieser Arbeit damit nicht abschließend geklärt werden. Der Transport von phosphorylierten Zuckern, wie Glukose-1-, Glukose-6- oder Mannose-6- Phosphat, erfolgt in L. monocytogenes über den Hexose-Phosphat-Transporter UhpT, der von dem strikt PrfA-abhängig uhpT-Gen kodiert wird. Durch die Zugabe von Amberlite XAD-4 zu LB-Medium oder durch vorherigen Anzucht in Glyzerin-haltigem MM, Bedingungen, die sich stimulierend auf die PrfA-Aktivität auswirken, konnte ein effizientes Wachstum von L. monocytogenes in Glukose-6-Phosphat-haltigem Medium erreicht werden. Obwohl die Kohlenstoff-Verbindungen (Glukose, Cellobiose und Glukose-6-Phosphat) in die Glykolyse eingeschleust werden, führte die Verwertung von Glukose-6-Phosphat zur Aufhebung der KKR. Dies konnte durch vergleichende Gesamtgenom-Transkriptom-Analysen und an der Bestimmung der HPr-Ser46~P Meng gezeigt werden. Die PTS-unabhängige Glukose-6-Phosphat-Aufnahme führt, ähnlich wie die von Glyzerin, zu einer erhöhten Aktivität von PrfA. Neben Glyzerin können auch Dihydroxyaceton (Dha) und Pyruvat (letztere allerdings mit niedriger Wachstumseffizienz), nicht aber Glyzerin-3-Phosphat in vitro als C3-Quellen dienen. Da die ::ptsH-Insertionsmutante kein Wachstum in Glyzerin- oder Dha-haltigem Medium zeigte, lässt sich vermuten, dass die listeriellen Glyzerin-Kinase(n) (GlpK), ähnlich wie die von B. subtilis, durch HPr-His15~P aktiviert werden muss und die Dha-Kinase(n) (DhaK) von L. monocytogenes ebenfalls HPr-His15~P als Kofaktor für die Phosphorylierung von Dha verwendet. Der Glyzerin-Metabolismus in L. monocytogenes wurde vor allem über Gesamtgenom-Transkriptom-Analysen und Real-time RT-PCR Untersuchungen näher charakterisiert. Es konnte gezeigt werden, dass L. monocytogenes mehrere Gene besitzt, die in Glyzerin-haltigem Medium verstärkt exprimiert werden und vermutlich am Glyzerin- bzw. Dha-Metabolismus beteiligt sind. L. monocytogenes besitzt zwei Dha-Kinasen (kodiert von lmo0347-48 und lmo2695-96), die beide eine hohe Homologie zur DhaK aus E. coli besitzen. Eine Deletion beider Dha-Kinasen (&#916;dhaK = &#916;lmo0347-48/lmo2695-96) führte zu einer starken Wachstumshemmung in Glyzerin-haltigem MM und zur weitgehenden Inaktivierung von PrfA. Die &#916;dhaK- und die &#916;glpD/dhaK-Mutante wiesen in J744 Makrophagen eine verringerte Replikationsrate im Vergleich zum WT auf, was für eine Verwertung von Glyzerin und/oder Dha durch L. monocytogenes im Zytoplasma von Wirtszellen spricht. Da diese Mutanten aber noch –wenn auch mit verringerter Effizienz – in diesem Zellkompartiment der Makrophagen wachsen können, muss L. monocytogenes wohl auch in der Lage sein, weitere Kohlenstoffquellen dieser Wirtszelle verwerten zu können. / Listeria monocytogenes is a Gram-positive facultative intracellular bacterium of mammals naturally inhabiting decayed plant matter in the soil. Several well-characterised virulence factors are necessary for the different steps in the infection cycle of L. monocytogenes: InlA and InlB for active internalization of L. monocytogenes into nonprofessional phagocytic cells, LLO and PlcA for the release of the primary phagosome, ActA for cell-to-cell spreading, LLO together with PlcA and mainly PlcB are responsible for the escape from the secondary phagosome. The hexose-phosphate-transpoter (UhpT) is partially involved in intracellular replication in the cytosol of the host. The genes that encode these virulence factors are clustered mainly in a single 9,6 kb region of the chromosome (LIPI-1) or dispersed elsewhere on the listerial chromosome. The transcriptions of these genes are regulated by the positive regulatory factor A ( PrfA), encoded by prfA, which is itself a member of the same gene cluster (LIPI-1). Previous studies have indicated that the utilization fermentable sugars like glucose, mannose, and cellobiose repressed the PrfA-controlled virulence gene expression in L. monocytogenens. Based on the published results and the results obtained in this study, it is tempting to hypothesise that components of the carbon catabolite repression (CCR) or of the PTS- (Phosphoenolpyruvate Phosphotransferase System) dependent sugar transport are involved in modulation of PrfA activity. To show that components of CCR could be involved in modulation of PrfA activity and therfore in regulation of PrfA-dependent virulence gene expression in L. monocytogenes, insertion mutants of ccpA (coding for CcpA = catabolite control protein A), hprK (coding for HPr kinase/phosphatase which phosphorylates HPr at Ser46) and ptsH (coding for HPr) were characterised. The ::ccpA and ::hprK mutants showed reduced growth in BHI (undefined nutrient rich medium) as well as in defined minimal medium (MM) with 50 mM glucose and decreased [14C]-glucose uptake compared to wild-type. The ::ptsH mutant could only grow in a rich culture medium and as expected was unable to grow in MM with glucose as sole carbon source because of its inability to produce HPr. ::hprK and ::ptsH mutant (under certain growth conditions) too showed increased expression of PrfA-controlled genes both at the transcriptional and translational level. Cellobiose utilisation in the ::hprK mutant led to inhibition of PrfA activity. In contrast, the ::ccpA mutant showed decreased expression of the PrfA-dependent virulence genes in comparison to wild-type. Revertants, RccpA RhprK and RptsH again showed a wild type phenotype with respect to growth and expression of the PrfA regulated genes. In spite of slight increased virulence gene expression, the ::ptsH mutant showed reduced replication in J744 macrophages compared to wild-type. The transcript profiles of the::ccpA and ::hprK mutants revealed in comparison to the wildtype several upregulated genes. Amongst others, genes coding for PTS-dependent sugar transport, ABC-transporter and enzyms of the C- and N-metabolism were upregulated, suggesting that they were repressed in wild-type under those growth conditions. Upregulation of the PrfA-dependent virulence genes in the ::hprK mutant correlates with the down-regulation of genes which are controlled by the efficiency of PTS-mediated glucose transport. The increased PrfA activity and the absence of the HPr-Ser46~P (beside CcpA a main key player of CCR) in ::hprK and ::ptsH mutants led to assumption that there is an inverse correlation between the level of HPr-Ser46~P and PrfA activity. However, the determination of the PrfA activity and quantification of the amount of HPr-Ser46~P in the medium with glucose cellobiose and glycerol respectively showed that neither HPr-Ser46~P nor HPr-His15~P could act as direct negative modulators of PrfA activity. Recent studies aimed at demonstrating direct binding of purified HPr-Ser46~P and PrfA using Biacore assays also failed. In addition in vitro transcription showed no inhibition effect by HPr-Ser46~P to initiated transcription from several PrfA-dependent promoters (S. Müller-Altrock, personal communication). Interestingly, during active glucose transport, conditions where EIIA components of active glucose-specific PTS are unphosphorylated (EIIA components transfer the phosphate via EIIB to the glucose being tranported by EIIC into the bacterial cell) the PrfA activity is low. In the late log phase and the early stationary phase where less glucose is taken up by the bacteria and glucose-specific EIIA components are phosphorylated, the PrfA activity increased. L. monocytogenes grown in the presence of the non-PTS carbon source glycerol showed already in the early growth phase a higher PrfA activity in comparison to growth with PTS-dependent sugars like glucose or cellobiose. Based on these results, the expression of specific PTS and the phosphorylation state of EIIA componentes of these PTS seams to affect the regulation of PrfA activity. The exact mechanism of glucose uptake in L. monocytogenes is still unclear (R. Stoll; unpublished data). Due to the growth deficiency of the ::ptsH mutant in glucose-containing MM glucose uptake must be PTS-dependent. The glucose-specific PtsG described for B. subtilis and other bacteria as important glucose transporter is not present in L. monocytogenes. Only a PtsG-specific EIIA component (encoded by lmo1017) has been identified. Growth analysis in defined MM supplemented with glucose, mannose, cellobiose and glycerol respectively showed no differences in growth between eIIAGlc mutant and wildtype. The PrfA activity in that mutant was slightly increased, shown in a slight increased expression of ActA and PrfA and a higher LLO activity compared to wild-type. However, studies aimed at demonstrating direct binding of purified EIIAGlc and PrfA with in Biacore assays failed (S. Müller-Altrock and G. Seidel, personal communication). Which of the EIIA components of specific PTS are involved in modulation of PrfA activity needs further clarification. Transport of phosphate sugars like glucose-1-, glucose-6- or mannose-6-phosphate is mediated by the hexose-phosphate-transporter UhpT encoded by the strictly PrfA-dependent gene uhpT. Addition of Amberlite XAD-4 to LB-Medium or preincubation in glycerolcontaining MM conditions which induce PrfA activity led to efficient growth of L. monocytogenes in glucose-6-phosphate containing medium. Even though, glucose, cellobiose and glucose-6-phosphate are catabolised via glycolyis, glucose-6-phosphate utilisation led to deregulation of the CCR. This deregulation was shown on the basis of wholegenome-transcriptom analysis and quantification of the amount of HPr-Ser46~P. The non-PTS-dependent transport of glucose-6-phosphate resulted similar to that of glycerol to a higher activation of PrfA. Besides glycerol, dihydroxyacetone (dha) and pyruvate (with lower growth efficiencies) but not glycerol-3-phosphate seem to be suitable C3 sources for L. monocytogenes. The ::ptsH mutant was unable to grow in glycerol- or dha-containing medium which suggests that the listerial glycerol kinase(s) (GlpK) similar to that of B. subtilis is activated by HPr-His15~P and that the dha kinase(s) (DhaK) also use HPr-His15~P as a cofactor for dha phosphorylation. The glycerol metabolism of L. monocytogenes was mainly characteriezed by wholegenome transcriptome analysis and Real-time RT-PCR. It was shown that L. monocytogenes exhibits many genes highly upregulated in glycerol-containing MM indicating an involvement in glycerol and dha metabolism, respectively. L. monocytogenes possesses two dha kinases (encoded by lmo0347-48 and lmo2695-96) with high sequence homology to the dha kinase of E. coli. Deletion of both dha kinases (&#916;dhaK = &#916;lmo0347-48/lmo2695-96) led to high growth inhibition and to almost complete PrfA inactivation. The dhaK and glpD/dhaK mutants exhibited a reduction in intracellular replication in J744 macrophages compared to wild-type, suggesting an utilisation of glycerol and/or dha in the host cytosol by L. monocytogenes. The fact that these mutants could still grow in this cell compartment of macrophages (however with lower efficiencies) indicates that L. monocytogenes must be able to utilise additional carbon sources in the host cell.

Listeria monocytogenes

PrfA

PEP:PTS

Kohlenstoffkatabolitrepression

ddc:570

Régulation des principaux transporteurs de glucose et leurs effets sur l’expression des gènes de virulence chez Listeria monocytogenes / Regulation of the main Listeria monocytogenes glucose transporter and effects on virulence gene expression

Ake, Francine Désirée Moussan

29 April 2011

Listeria monocytogenes est une bactérie à Gram+, ubiquiste, pathogène intracellulaire d’origine alimentaire, responsable chez l’homme, de nombreuses infections telles que les infections foeto-maternelles, des méningo-encéphalites et des septicémies. La bactérie utilise préférentiellement le glucose qui est transporté via le système phosphoenolpyruvate:sucre phsosphotransferase (PTS) et des perméases non-PTS. Les deux principaux transporteurs de glucose chez L. monocytogenes seraient des PTS de la classe mannose. Le premier est codé par l’opéron manLMN (man) et le deuxième, par l’opéron mpoABCD (mpo). Nous avons, dans un premier temps, mis en évidence le transport de glucose par ces PTS chez L. monocytogenes et aussi identifier d’autres transporteurs non-PTS de glucose. Des tests de croissance en milieu minimum (MM) additionné de glucose et des tests de consommation de glucose ont permis de montrer que les mutants ΔmanL (manL code pour l’EIIABMan) et ΔmanM (manM code pour l’EIICMan) utilisent moins vite le glucose que la souche sauvage AML73 ou EGDe (3 à 4 fois moins vite). Le mutant ΔmpoA (mpoA code pour l’EIIAMpo) montre un phénotype similaire à la souche sauvage tandis que le mutant ΔmpoB (mpoB code pour l’EIIBMpo) utilise 4 à 5 fois moins vite le glucose que la souche sauvage. Des tests de qRT-PCR ont par ailleurs permis de montrer que la délétion du gène mpoA permet une expression constitutive de l’opéron man tandis que la délétion du gène mpoB entraîne une inhibition de l’expression de cet opéron. Nous avons aussi montré que l’opéron man est induit par le glucose et l’opéron mpo est exprimé constitutivement. Le PTSMan est le principal système de transport de glucose chez L. monocytogenes et le PTSMpo pourrait fonctionner comme un senseur de glucose qui en présence de ce sucre stimule l’expression de l’opéron man en régulant l’activité de ManR. Le mutant ΔptsI (ptsI code pour la protéine générale EI du PTS) utilise 8 à 10 fois moins vite le glucose que la souche sauvage et présente une très faible expression de l’opéron man. L’utilisation du glucose (bien que faible) par le mutant ΔptsI permet d’affirmer qu’il existerait des transporteurs non-PTS qui permettraient à ce mutant d’utiliser le glucose. Des tests de complémentation hétérologue dans la souche E. coli LJ140 (incapable de transporter le glucose) ont permis de montrer que les trois protéines GlcU (GlcU1, GlcU2 et GlcU3, identifiées par homologie de séquences aux GlcU d’autres firmicutes) permettent le transport de glucose chez L. monocytogenes mais avec une très faible affinité. Un rôle potentiel du PTS et des transporteurs non-PTS dans la régulation de PrfA a également été mis en évidence par des tests de dosage β-D-glucuronidase à partir de cultures bactériennes réalisées en milieux liquides ou sur géloses et aussi par des tests de qRT-PCR (pour l’expression des gènes actA et hly). Ces tests ont été réalisés à partir de la souche L. monocytogenes AML73 (portant la fusion Phly-gus) et des mutants ΔmanL, ΔmanM, ΔmpoB, ΔmpoA, ΔptsI et glcU (construits dans cette souche). Les mutations manL, manM, mpoB, ptsI entraînent une augmentation de l’activité de PrfA (de 2 à 14 fois) et une augmentation de l’expression des gènes de virulence PrfA-dépendants (hly et actA) est également observée dans les mutants ΔmanL, ΔmanM et ΔmpoB. Les mutations glcU et mpoA ne montrent aucun effet sur l’activité de PrfA. Les mutants montrant une forte activité de PrfA contiennent peu ou pas de protéine EIIABMan qui est supposée jouer un rôle dans la régulation de l’activité de PrfA par le glucose. L’effet des mutations PTS observé sur l’expression des gènes de virulence dépend de PrfA car cet effet disparaît quand le gène prfA est délété dans les mutants ΔmanL, ΔmanM et ΔmpoB. Les mutations montrant un effet sur l’activité de PrfA ont également été étudiées in vitro par des infections des cellules épithéliales (Caco-2 et Jeg-3) avec les différents mutants et également in vivo dans la souris. La délétion du gène ptsI montre un effet dans l’infection plus particulièrement dans l’entrée des bactéries dans les cellules / L. monocytogenes is a ubiquitous foodborne pathogenic Gram-positive bacterium, which can multiply in host cells and infect humans causing septicemia, spontaneous abortion and méningoencephalitis. This bacterium transports glucose via phosphoenolpyruvate:sugar phosphotransferase systems (PTS) and non-PTS permeases. Two major glucose-transporting PTSs belong to the mannose class. One is encoded by the manLMN (man) operon and the second by the mpoABCD (mpo) operon. One goal was to study the transport of glucose by the proteins encoded by these operons and to identify non-PTS glucose transporters. Growth studies in MM supplemented with glucose and glucose consumption assays with several mutants revealed that deletion of manL (encodes EIIABMan) or manM (encodes EIICMan) significantly slowed glucose utilization (3- to 4-fold) compared to the WT AML73 or EGDe strain. Deletion of mpoA (encodes EIIAMpo) had no significant effect on glucose utilization (same phenotype as the WT) whereas deletion of mpoB (encodes EIIBMpo) significantly slowed glucose utilization (4- to -5 fold). By using qRT-PCR, we show that expression of the man operon is induced by glucose, whereas the mpo operon is expressed constitutively. Nevertheless, deletion of mpoA causes constitutive man operon expression whereas deletion of mpoB inhibits it. The PTSMpo therefore functions as a constantly synthesized glucose sensor regulating man operon expression. Deletion of ptsI (encodes the general PTS component EI) also inhibits man expression and the ΔptsI mutant was most strongly impeded in glucose utilization. The residual glucose uptake probably owes to three GlcU-like non-PTS transporters. The successful heterelogous complementation of the E. coli LJ140 strain, wich is unable to transport glucose, suggests that the L. monocytogenes GlcU proteins, GlcU1, GlcU2 and GlcU3 (identified by sequences homology to GlcU proteins in other firmicutes) are indeed capable of transporting glucose.A potential role of PTS and non-PTS components in PrfA regulation was studied in the L. monocytogenes AML73 strain (contains a Phly-gus fusion) and in the ΔmanL, ΔmanM, ΔmpoB, ΔmpoA, ΔptsI, glcU mutants derived from it. For that purpose, I carried out β-D-glucuronidase activity tests with bacteria grown either in liquid or on solid medium and qRT-PCR experiments (expression of actA and hly genes). Interestingly, deletion of ptsI, manL, manM and mpoB caused elevated PrfA activity (2- to -14 fold) and elevated expression of virulence gene expression (actA and hly) in the ΔmanL, ΔmanM and ΔmpoB mutants was observed. Nevertheless, glcU inactivation and mpoA deletion had no effect on PrfA activity. The elevated PrfA activity disappeared when the prfA gene was also deleted in the ΔmanL, ΔmanM and ΔmpoB mutants, confirming that the stimulatory effect of the various mutations on virulence gene expression is PrfA-dependent. All mutants exhibiting elevated virulence gene expression contain no or only little unphosphorylated EIIABMan, which we therefore suspect to play a major role in glucose-mediated PrfA inhibition. The effect of the PTS mutations was also tested in in vitro host cells infection assays (Caco-2, Jeg-3 cells) and in an in vivo mouse model. Deletion of ptsI led to elevated infection of the host cells, which probably owes to the elevated synthesis of the InlA protein.

Listeria monocytogenes

Système Phosphotransférase

Transport de glucose

PrfA

Virulence

Listeria monocytogenes

Phosphotransferase system

Glucose transport

PrfA

Virulence

Exploration into the virulence mechanisms of Listeria

Bielecka, Magdalena Kamila

January 2011

Pathogenic Listeria are the causative agents of listeriosis, a severe food-borne infection. They are able to invade various non-phagocytic cell types including epithelial cells. The life cycle of these intracellular parasites involves penetrating into host cells, rupturing of the phagocytic vacuole, rapidly proliferating in the cytosol, and directly spreading cell to cell. Each step of the listerial intracellular infection involves activation of virulence factors dependent on PrfA, the master regulator of Listeria virulence. PrfAmediated virulence gene activation occurs within host cells by mechanisms that remain unknown. This thesis explores several aspects of PrfA regulation and its impact in the host-pathogen interaction. Methods for assessing PrfA-dependent gene expression were first developed and standardized, including a highly sensitive and accurate quantitative reverse-transcription real-time PCR (RT-QPCR), as well as procedures to investigate the correlation with virulence using cell culture-based assays. These techniques were applied in an investigation into the structure-function of PrfA. We studied the role of a solvent-accessible pocket identified in the N-terminal domain of PrfA, homologous to the cyclic nucleotide-binding (CNB) domain of Crp and other cAMP-regulated proteins, in intracellular virulence gene activation. Site-directed PrfA mutants were constructed. Our data support the notion that PrfA activity is allosterically regulated and are consistent with a role for the pocket as putative binding site for the PrfA-activating allosteric effector. The characterization of spontaneously occurring PrfA mutations that identified in our laboratory as PrfA*- suppressor or attenuator mutations, A129T, E173G and C229Y, allowed us to gain additional insight into PrfA structure-function. The role of the C229Y in sugar-mediated repression was investigated and found to explain the anomalous phenotype of strain NCTC 7973, a prfA* (G145S) mutant that carries this second mutation and is repressed by cellobiose but not glucose. We also carried out experiments to address the intriguing activation of PrfAdependent virulence genes upon addition of an adsorbent to the culture medium, the socalled "charcoal effect". Using a chemically defined culture medium and resin, Amberlite™ XAD-4, we provided evidence that the virulence gene activation may involve the sequestration of a medium component rather than a bacteria-derived autorepressor, as initially thought. We also explored the role of PrfA and the sigma factor σB in L. monocytogenes entry into host cells. ΔsigB mutants in different prfA regulation backgrounds were constructed. We showed that σB has no major effect on host cell invasion, and that L. monocytogenes invasiveness is a strictly PrfA-dependent trait. Our results also demonstrate a differential role of σB in L. monocytogenes serotypes. σB apparently plays no role in stress tolerance in serotype 4b, whereas it is important in serotype 1/2a for maintenance of bacterial fitness in stress conditions. Finally, we investigated the occurrence of apoptosis in Listeria-infected cells and developed normalized methods to accurately determine and quantify this cellular response in infected cell monolayers.

616.9

Regulatory roles of two small RNAs in the human pathogen Listeria monocytogenes and the evaluation of an alternative infection model

Gripenland, Jonas

January 2012

Listeriosis is a potentially lethal disease caused by the Gram-positive facultative intracellular pathogen Listeria monocytogenes (L.m.). L.m. is found ubiquitously in the environment and infects humans via ingestion of contaminated food. Contaminated products are usually derived from ruminants and involve dairy products and different kinds of processed meat. Listeriosis is a potential lifethreatening disease with a total mortality rate of 20-30 %. The development of listeriosis may lead to meningitis and septicemia or other invasive diseases. Pregnant women are of increased risk of developing listeriosis and a materno-fetal infection commonly lead to spontaneous abortion or still-birth. Regulation of gene expression, and specifically virulence gene expression, is essential for pathogenic bacteria to be equipped for handling counteractions from the host as well as thriving in the often hostile environment. In pathogenic Listeria, virulence gene expression is under the control of the global virulence gene regulator PrfA. The expression of prfA is highly regulated at the transcriptional, post-transcriptional and post- translational level. We have identified a novel type of post-transcriptional regulation of prfA-mRNA by a trans-acting riboswitch element (SreA). By binding to the leader region of prfA-mRNA, SreA negatively regulates the expression of prfA. To our knowledge, this is the first description of a cis-acting riboswitch capable of functioning as a small RNA in trans, regulating targets on distant sites. To date, there have been around 100 sRNAs identified in Listeria monocytogenes, but experimental data is still limited. We have characterized a blood induced sRNA, Rli38, which is important for full virulence during oral infection of mice. Our data suggest that Rli38 regulates the expression of at least two proteins; OppD (Oligopeptide transport protein) and IsdG (heme degrading monooxygenase). Both of these proteins have been implicated in the infectious cycle of L.m. We speculate that the virulence phenotype of an ∆rli38 mutant is possibly mediated through the effect of these proteins. L.m. is a complex pathogen, able to infect and replicate in a variety of organs and cause several distinctive forms of disease. These qualities of L.m. generate difficulties in simulating human listeriosis in animal models, as entailed by the multitude of models used in the field. In this work, we have evaluated the use of an alternative animal model in studying listeriosis. Our results describe the differentiated virulence potential of wildtype bacteria and a ∆prfA mutant strain in the chicken embryo by live/death screening and organ colonization. Large differences in mean time to death were found between wild-type and the ∆prfA strain and ∆prfA cells displayed a considerable defect in colonization of the embryonal liver. The results presented in this thesis show that the chicken embryo infection model is a valuable and convenient tool in studying end-outcome and organ colonization of Listeria monocytogenes. Taken together, this thesis describes the characterization of two previously unknown sRNAs in the human pathogen Listeria monocytogenes and the use of an alternative infection model for simulating listeriosis.

small RNA

sRNA

Riboswitch

Listeria monocytogenes

ncRNA

PrfA

RNA-mediated virulence gene regulation in the human pathogen Listeria monocytogenes

Loh, Edmund

January 2010

The Gram-positive human pathogen Listeria monocytogenes uses a wide range of virulence factors for its pathogenesis. The majority of its virulence genes are encoded on a 9-kb pathogenicity island and are controlled by the transcriptional activator PrfA. Expression of these genes is maximal at 37°C and minimal at 30°C in a mechanism involving an RNA thermosensor. This thesis brings up different aspects of RNA-mediated regulation, including regulatory RNA structures within coding mRNA controlling expression to 5-untranslated RNA (5´-UTR) that controls downstream genes (cis-acting) as well as small non-coding RNAs (ncRNAs) that bind other target RNA (trans-acting). We investigated the importance of the coding region of the prfA-mRNA for its expression. Various lengths of prfA-mRNA were fused with reporter genes. Our finding suggested that the first 20 codons of prfA-mRNA were essential for efficient translation in Listeria monocytogenes. Translation of the shorter constructs was shown to be reduced. The expression level showed an inverse correlation with the RNA secondary structure stability in the beginning of the coding region. Riboswitches have previously been known to control expression of their downstream mRNA in a cis-acting manner. A trans-acting S-adenosylmethionine-binding riboswitch termed SreA was identified in Listeria monocytogenes. It was found to control the expression of the virulence regulator PrfA, by binding to the prfA-UTR and thereby affecting its translation. We examined the RNA locus encoding different virulence factors in Listeria monocytogenes. Several of them were preceded by 5´-UTRs of various lengths. We speculate that these 5´-UTRs could control expression of the downstream mRNA, provided they are of sufficient length. These findings prompted us to examine where and when Listeria monocytogenes switches on gene expression. Tiling array was used to compare RNAs isolated from wild-type and mutant bacteria grown at different growth conditions. Antisense RNAs covering parts of or whole open-reading frames as well as 29 new ncRNAs were identified. Several novel riboswitches possibly functioning as upstream terminators were also found. My thesis work compiles together a variety of novel RNA-mediated gene regulatory entities. A first coordinated transcriptional map of Listeria monocytogenes has been set up. My work has also revealed that the expression of the virulence regulator PrfA is controlled at several levels, indicating the importance of both the 5´-UTR and the coding RNA for regulated expression.

Listeria monocytogenes

virulence

ncRNAs

PrfA

5´-UTRs

Molecular biology

Molekylärbiologi

Understanding the role of virulence regulators in niche adaptability using the Listeria PrfA 'saprotroph to parasite' switch

Radhakrishnan Balasubramaniam, Vasanthakrishnan

January 2014

Listeria monocytogenes the causative agent of foodborne listeriosis is a facultative pathogen that lives as a saprophyte in soil and as an intracellular parasite in host tissues. A regulatory protein, the transcriptional activator PrfA, plays a key role in the “saprotroph to parasite” conversion of L. monocytogenes by selectively activating key virulence genes essential for infection when the bacteria enter host cells. Central to this conversion is the plastic ability of PrfA allosterically shift between two states, weakly active (“ON-OFF”, outside in the environment) and strongly active (“ON”, intracellular compartment). In this thesis, I have used the PrfA “ON-OFF” virulence switch to understand the role of virulence regulators in the adaptability of facultative parasites to a wide range of niches. Using the PrfA model, I have also examined the trade-offs between the saprotroph and virulent states of facultative pathogens and the role of plasticity in maintaining adaptation to multiple environments. Using soil as a natural environment model, I have shown that overexpression of the PrfA-dependent virulence regulon has a negative impact on environmental survival of L. monocytogenes. Then I investigated the fitness consequences of losing PrfA switchability in non-host environments. The results in in-vitro growth conditions with isogenic strains with PrfA locked in the “ON” state and in which all the genes of the virulence regulon were deleted, showed that PrfA-dependent gene overexpression causes a reduction in fitness. Our data indicate this was directly attributable to the costs associated with the overproduction of an array of unneeded proteins and not to indirect effects of hyperactive PrfA in Listeria metabolism. Finally, I used experimental evolution studies in in-vitro only conditions and in alternate in-vitro and intracellular conditions with bacteria with wild-type or “ON-locked” PrfA alleles to visualize the selective pressures acting on the PrfA switch. The results of the selection experiments showed that adaptation to the different conditions involves a rapid evolution of PrfA with mutations changing its activity according to the specific environment in which selection occurred. The findings from this thesis highlight the importance of plastic ability, evolution of properly regulated genetic systems and the role of these genetic systems in enabling organisms to maximise their fitness during the adaptation process to a specific niche.

579.3

Régulation des principaux transporteurs de glucose et leurs effets sur l'expression des gènes de virulence chez Listeria monocytogenes

Ake, Francine Désirée Moussan

29 April 2011

Listeria monocytogenes est une bactérie à Gram+, ubiquiste, pathogène intracellulaire d'origine alimentaire, responsable chez l'homme, de nombreuses infections telles que les infections foeto-maternelles, des méningo-encéphalites et des septicémies. La bactérie utilise préférentiellement le glucose qui est transporté via le système phosphoenolpyruvate:sucre phsosphotransferase (PTS) et des perméases non-PTS. Les deux principaux transporteurs de glucose chez L. monocytogenes seraient des PTS de la classe mannose. Le premier est codé par l'opéron manLMN (man) et le deuxième, par l'opéron mpoABCD (mpo). Nous avons, dans un premier temps, mis en évidence le transport de glucose par ces PTS chez L. monocytogenes et aussi identifier d'autres transporteurs non-PTS de glucose. Des tests de croissance en milieu minimum (MM) additionné de glucose et des tests de consommation de glucose ont permis de montrer que les mutants ΔmanL (manL code pour l'EIIABMan) et ΔmanM (manM code pour l'EIICMan) utilisent moins vite le glucose que la souche sauvage AML73 ou EGDe (3 à 4 fois moins vite). Le mutant ΔmpoA (mpoA code pour l'EIIAMpo) montre un phénotype similaire à la souche sauvage tandis que le mutant ΔmpoB (mpoB code pour l'EIIBMpo) utilise 4 à 5 fois moins vite le glucose que la souche sauvage. Des tests de qRT-PCR ont par ailleurs permis de montrer que la délétion du gène mpoA permet une expression constitutive de l'opéron man tandis que la délétion du gène mpoB entraîne une inhibition de l'expression de cet opéron. Nous avons aussi montré que l'opéron man est induit par le glucose et l'opéron mpo est exprimé constitutivement. Le PTSMan est le principal système de transport de glucose chez L. monocytogenes et le PTSMpo pourrait fonctionner comme un senseur de glucose qui en présence de ce sucre stimule l'expression de l'opéron man en régulant l'activité de ManR. Le mutant ΔptsI (ptsI code pour la protéine générale EI du PTS) utilise 8 à 10 fois moins vite le glucose que la souche sauvage et présente une très faible expression de l'opéron man. L'utilisation du glucose (bien que faible) par le mutant ΔptsI permet d'affirmer qu'il existerait des transporteurs non-PTS qui permettraient à ce mutant d'utiliser le glucose. Des tests de complémentation hétérologue dans la souche E. coli LJ140 (incapable de transporter le glucose) ont permis de montrer que les trois protéines GlcU (GlcU1, GlcU2 et GlcU3, identifiées par homologie de séquences aux GlcU d'autres firmicutes) permettent le transport de glucose chez L. monocytogenes mais avec une très faible affinité. Un rôle potentiel du PTS et des transporteurs non-PTS dans la régulation de PrfA a également été mis en évidence par des tests de dosage β-D-glucuronidase à partir de cultures bactériennes réalisées en milieux liquides ou sur géloses et aussi par des tests de qRT-PCR (pour l'expression des gènes actA et hly). Ces tests ont été réalisés à partir de la souche L. monocytogenes AML73 (portant la fusion Phly-gus) et des mutants ΔmanL, ΔmanM, ΔmpoB, ΔmpoA, ΔptsI et glcU (construits dans cette souche). Les mutations manL, manM, mpoB, ptsI entraînent une augmentation de l'activité de PrfA (de 2 à 14 fois) et une augmentation de l'expression des gènes de virulence PrfA-dépendants (hly et actA) est également observée dans les mutants ΔmanL, ΔmanM et ΔmpoB. Les mutations glcU et mpoA ne montrent aucun effet sur l'activité de PrfA. Les mutants montrant une forte activité de PrfA contiennent peu ou pas de protéine EIIABMan qui est supposée jouer un rôle dans la régulation de l'activité de PrfA par le glucose. L'effet des mutations PTS observé sur l'expression des gènes de virulence dépend de PrfA car cet effet disparaît quand le gène prfA est délété dans les mutants ΔmanL, ΔmanM et ΔmpoB. Les mutations montrant un effet sur l'activité de PrfA ont également été étudiées in vitro par des infections des cellules épithéliales (Caco-2 et Jeg-3) avec les différents mutants et également in vivo dans la souris. La délétion du gène ptsI montre un effet dans l'infection plus particulièrement dans l'entrée des bactéries dans les cellules

[SDV] Life Sciences

[SDV] Sciences du Vivant

Listeria monocytogenes

Système Phosphotransférase

Transport de glucose

PrfA

Virulence

Contribution à l'étude de la réparation et du renforcement des poutres endommagées en béton armé avec matériaux composites / Contribution to the study of the repair and reinforcement of damaged reinforced concrete beams with composite materials

Laraba, Abdelkrim

18 December 2017

Ce présent travail concerne les aspects de la réparation et du renforcement des ouvrages utilisant des matériaux composites et plus particulièrement, il traite le cas des poutres en béton endommagées. La méthode de renforcement des ouvrages en béton par collage de matériaux composites est une pratique qui connaît actuellement un essor important. Dans cette optique, on propose d’apporter une contribution à l’analyse du comportement des poutres endommagées en béton par matériaux composites. La nouvelle méthode de renforcement interne NSM (Near Surface Mounted) consiste en l’insertion de bandes de Polymères Renforcées de Fibres (PRF) dans des engravures préparées préalablement dans le béton d'enrobage des surfaces tendues, remplies de résines époxydiques pour fixation. Pour construire un système renforcé de NSM efficace, les armatures en PRF doivent être en mesure de transférer ses efforts longitudinaux développés à l'élément de flexion en béton armé afin d'assurer l’action du composite, avec une compatibilité de déformation des matériaux. Les spécimens testés sont composés de poutres coutres avec une section rectangulaire de (100 mm x180 mm) et une longueur de 1300 mm renforcés avec PRFC-NSM. D’autres spécimens de poutres rectangulaires ont été testés avec une section de 200 mm x 400 mm et une longueur de 2300 mm, les renforts en PRF utilisés sont des plats ou des joncs. Les paramètres étudiés dans ce travail concernent la classe de résistance en compression, le taux de renfort, le type de composite et le degré d’endommagement. L’étude expérimentale sur le comportement des poutres endommagées puis renforcées sollicitées en flexion 4 points a dévoilé beaucoup de critères de performances en termes de ductilité, de rigidité et de capacité portante. Une modélisation analytique a été menée afin de comparer les réponses moment-courbure analytiques avec celles obtenues expérimentalement. Une fois cette modélisation validée, l’approche analytique a été couplée avec la méthode des plans d’expériences dans le but d’évaluer l’influence de différents paramètres et leurs interactions tels que le type de renfort (carbone, Joncs, aramide), le taux d’armatures passives et de renfort et la classe de résistance sur les réponses concernant la capacité portante et la ductilité des poutres renforcées. / This work deals with aspects of repair and reinforcement of structures and in particular, it deals with the case of damaged concrete beams. The method of reinforcing concrete structures by adhesive bonding of composite materials is a practice which is currently undergoing a major expansion. In this context, we propose to contribute to the analysis of the behavior of damaged concrete beams by composite materials. The new NSM (Near Surface Mounted) internal reinforcement method consists of the insertion of carbon fiber reinforced polymer (PRFC) strips in pre-prepared etchings in the encapsulation concrete of stretched surfaces filled with epoxy resins for fixing. To build an effective NSM reinforced system, FRP reinforcements must be able to transfer its developed longitudinal forces to the reinforced concrete flexure element to ensure the action of the composite with material deformation compatibility. The specimens tested consist of beams with a rectangular section (100 mm x 180 mm) and a length of 1300 mm reinforced with PRFC-NSM. Other specimens of rectangular beams were tested with a section of 400 mm x 800 mm and a length of 2300 mm, the FRP reinforcements used were either plates or rods. The parameters studied in this work concern the strength of the concrete, the reinforcement rate, the type of composite, the degree of damage. The experimental study on the behavior of damaged beams, then reinforced and subjected to bending, revealed many performance criteria in terms of ductility, stiffness and bearing capacity. Analytical modeling coupled with the experimental design method was carried out in order to evaluate the responses of the beams tested according to the interaction of the different parameters such as the reinforcement type (carbon, joncs, aramid), the Passive and reinforcement rates and strength class of reinforced beams.

Béton

Flexion

Poutres

Endommagement

Renforcement

Réparation

NSM

PRF

PRFC

PRFV

PRFA

Ductilité

Rigidité

Efficacité

Modélisation

Méthode des plans d’expériences

Concrete

Bending

Beams

Damage

Reinforcement

Repair

MFS

PRF

Ductility

Rigidity

Efficiency

Modeling

Experimental design method