First steps of bacteriophage SPP1 entry into Bacillus subtilis

AbstractThe mechanism of genome transfer from the virion to the host cytoplasm is critical to understand and control the beginning of viral infection. The initial steps of bacteriophage SPP1 infection of the Gram-positive bacterium Bacillus subtilis were monitored by following changes in permeability of the cytoplasmic membrane (CM). SPP1 leads to a distinctively faster CM depolarization than the one caused by podovirus ϕ29 or myovirus SP01 during B. subtilis infection. Depolarization requires interaction of SPP1 infective virion to its receptor protein YueB. The amplitude of depolarization depends on phage input and concentration of YueB at the cell surface. Sub-millimolar concentrations of Ca2+ are necessary and sufficient for SPP1 reversible binding to the host envelope and thus to trigger depolarization while DNA delivery to the cytoplasm depends on millimolar concentrations of this divalent cation. A model describing the early events of bacteriophage SPP1 infection is presented

Bacterial cytoskeleton Cell shape determination in Bacillus subtilis

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The Actin-like MreB 'Cytoskeleton'

Prokaryotic cells possess filamentous proteins, analogous to eukaryotic cytoskeletal proteins, that play a key role in the spatial organization of essential cellular processes. The bacterial homologues of actin (MreB, ParM, MamK, AlfA and Alps proteins) are involved in cell shape determination, DNA segregation, cell polarity, cell motility and other functions that require the targeting and accurate positioning of proteins and molecular complexes in the cell. In Bacillus subtilis, MreB homologues (MreB, Mbl and MreBH) assemble into dynamic polymeric structures that move processively along peripheral tracks perpendicular to the cell axis together with other morphogenetic factors involved in growth of the cylindrical side wall (elongation). The ultimate morphology of the cell is believed to depend on a dynamic interplay between the intracellular MreB proteins and the extracellular proteins that carry up cell wall biosynthesis, maturation and degradation, probably linked through MreCD and/or other membrane proteins such as RodZ. Peptidoglycan synthesis drives the circumferential movement of MreB filaments around the cell periphery, which in turn leads to spatial organization of the peptidoglycan elongation machinery. MreB isoforms of B. subtilis have also been implicated in the organization of the cell membrane and of viral DNA replication, in the inhibition of cell elongation during the escape from the competence state, and in chromosome segregation, although they do not seem to be essential for this process. The general properties of MreB proteins, relative to eukaryotic actin and to other prokaryotic homologues of actin, and the known functions of the MreB cytoskeleton in B. subtilis and other bacteria, will be discussed in this chapter

Organisation de composants de la sécrétion dans Bacillus subtilis

La membrane bactérienne a fait l'objet de nombreuses études de localisation de protéines et de phospholipides. Par fusion d une protéine fluorescente (GFP) aux gènes d intérêt, il est alors possible d observer la localisation des protéines associées par microscopie. La plupart de ces observations ont été réalisées à l aide de microscopes dits à épifluorescence. Afin d obtenir une qualité d image suffisante, il était nécessaire de surexprimer la protéine observée, insérée à un locus ectopique non naturel. Ce travail de thèse a permis d utiliser une nouvelle technologie acquise dans notre laboratoire, le microscope à fluorescence par réflexion totale interne (TIRFM), plus puissant que le microscope à épifluorescence utilisé précédemment. Cette technologie a permis une caractérisation plus détaillée de la localisation de protéines d intérêt, placées sous contrôle de leur promoteur naturel. Il a également été possible de caractériser la dynamique des foci observés. Nous avons concentré notre étude sur 3 protéines: (i) SecA pour l étude de la translocation des protéines du cytoplasme vers la membrane, (ii) YidC pour l insertion des protéines dans la membrane, (iii) PgsA pour la synthèse des phospholipids. Les foci se déplacent dynamiquement et s associent de manière transitoire dans la membrane. L observation sur la durée de ces foci, et l analyse de leur intensité moyenne au cours des observations, montre que SecA se déplace sur l ensemble de la membrane de manière uniforme. L analyse du déplacement des foci montre une relation quadratique entre la distance moyenne parcourue par les foci en fonction du temps. Ce résultat est en accord avec l hypothèse d un mouvement brownien des foci. Les foci sont observés dans les différentes phases de croissance des cellules, et le nombre de foci présents dans une cellule de la longueur de celle-ci. SecA-GFP a été testés dans un certain nombre de contextes génétiques. La localisation a été perturbée lors de la déplétion de pgsA. Cependant, comme PgsA est une protéine essentielle, il ne peut être exclu que ce changement de localisation apparaît des cellules qui sont mortes ou mourantes. Dans une souche mutante clsA, on n observe aucune différence dans la localisation de SecA en phase exponentielle, mais on aperçoit une relocalisation aux poles en phase stationnaire de croissance. La voie Tat est responsable du transport des protéines devant être exportées dans un état structuré, par exemple dans le cas de l incorporation d un co-facteur. À ce jour, la régulation du système Tat est peu connues, de même que les interactions entre les différentes sous-unités du système Tat et d'autres protéines dans le cytoplasme, dans la membrane ou dans la paroi cellulaire. Des fusions de les gènes de la voie Tat ont été co-exprimées deux à deux dans des cellules de levure, et leur capacité à interagir in vivo a été testée par la méthode dite du double hybride chez la levure. Nous avons généré un réseau d interaction autour des cinq composants de système Tat. Pour déterminer les implications fonctionnelles des composants du réseau, nous avons travaillé en collaboration avec le laboratoire de Jan-Maarten van Dijl. Nous avons utilisé une collection de souches mutantes pour lesquels certains composants individuels du réseau ont été retires. Trois a été observe d etre nécessaires pour la sécrétion Tat-dépendante. Nous avons étudié la localisation des fusions GFP avec ces proteins. On a observé une localisation double de HemAT selon l état physiologique de la cellule. En phase exponentielle, les cellules de B. subtilis sont généralement présentes sous forme de chaînes dans lesquelles le septum de division a déjà été formé, mais la séparation cellulaire n'a pas encore eu lieu. Une fusion de la GFP à CsbC apparaît de façon homogène dans la membrane.In the years since the cloning of GFP, the field of bacterial cell biology has characterized a variety of specific protein localization patterns in the bacterial membrane. The vast majority of early subcellular localization studies made use of inducible GFP fusions, which generally required the presence of high concentrations of inducer, and can therefore be considered to be overexpressed. An outstanding question remains over the organization of natively expressed proteins in the membrane. Here, we have investigated the localization of functional GFP fusions to proteins catalyzing important membrane processes; the secretion motor protein SecA, the membrane insertase YidC1, and the essential phospholipid synthase PgsA using total internal reflection fluorescence microscopy (TIRFM). This allowed natively expressed proteins to be localized with temporal resolution that can capture their dynamics. We characterized dynamic complexes dispersed throughout the membrane displaying diffusive movement with no preferred trajectories. Further characterization focused upon identifying conditions in which the localization pattern was disturbed. A polar mislocalization was identified in a cardiolipin mutant strain. The yeast two-hybrid (Y2H) approach is a robust approach to detect binary interactions on a proteome-scale. We performed genome-wide Y2H screens as well as targeted Y2H analyses for specific interactions involving components of the Sec and Tat secretion machineries of B. subtilis, revealing an intricate protein-protein interaction network involving 71 proteins. Furthermore, three proteins identified in the Tat network, WprA, CsbC and HemAT, were shown to be important for effective protein secretion via the B. subtilis Tat system, indicating that our yeast two hybrid assays reveal biologically significant interactions involving membrane proteins. The studies provide a novel proteomic view on the interaction network of the secretion systems of B. subtilis.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Role de protéines associées au cytosquelette bactérien

Le cytosquelette bactérien des homologues d actine (protéines de la famille MreB) joue un rôle majeur dans la morphogénèse cellulaire. Des homologues de MreB sont retrouvés chez la plupart des espèces bactériennes non sphériques, où ils sont essentiels pour la viabilité cellulaire. Les bactéries à Gram-positif ont généralement plusieurs isoformes. L organisme modèle Bacillus subtilis en possède trois : MreB, Mbl et MreBH, tous trois impliqués dans la détermination de la forme de la cellule. Le postulat actuel est une organisation, des complexes de synthèse du peptidoglycane, le long des parois latérales par les filaments hélicoïdaux des MreB-like. Cependant, les mécanismes moléculaires et les protéines effectrices impliqués dans cette fonction ne sont pas encore élucidés. Par analogie avec les rôles de l actine eucaryote, des implications dans d autres processus cellulaires cruciaux et la présence de partenaires protéiques sont également attendus pour les actines procaryotes. Afin d explorer les rôles des protéines MreB chez B. subtilis nous avons généré, par des criblages génomiques double hybride chez la levure, un réseau d interaction protéine-protéine centré sur MreB, Mbl et MreBH. Une vérification systématique et drastique de toutes les interactions obtenues lors des criblages a été réalisée afin d éliminer les faux positifs. Les interactions identifiées révèlent des liens entre les protéines MreB-like et seize protéines issues de catégories fonctionnelles variées ou de fonction inconnue. Une étude exploratoire a été menée pour huit des protéines partenaires par des approches in silico et in vivo et nous a permis de sélectionner une seule interaction à caractériser plus en détail. Nous nous sommes principalement intéressés à l interaction physique et directe entre MreB et DapL, une protéine essentielle vraisemblablement impliquée dans la voie de biosynthèse des précurseurs du peptidoglycane, par analogie à DapE d E. coli. La caractérisation approfondie de DapL a confirmé son essentialité dans la synthèse du peptidoglycane. Bien que l interaction MreB-DapL ait été confirmée biochimiquement, son rôle biologique exact n a pas été élucidé. Cependant, nous avons mis en évidence d autres interactions entre MreB et DapG, LysA et MurE, des enzymes également impliquées dans les étapes précoces de la synthèse du peptidoglycane. L existence de telles interactions renforce le rôle du cytosquelette MreB de B. subtilis dans l orchestration des machineries de synthèse de la paroi cellulaire.Bacterial actin homologues (MreB proteins) play a major role in cell morphogenesis in non-spherical bacteria. The prevailing model postulates that helical, membrane-associated MreB-like filaments organize elongation-specific peptidoglycan-synthesizing complexes along the sidewalls. However, the mechanistic details, as well as the effector proteins of MreBs morphogenetic function, remain to be elucidated. MreB proteins are also involved in DNA segregation, cell polarity, cell motility and, by analogy to eukaryotic actins, possibly in other functions that require the targeting and accurate positioning of proteins and molecular complexes in the cell. Gram-positive bacteria usually have more than one MreB isoform. Our model organism, Bacillus subtilis, has three called MreB, Mbl and MreBH. To explore the roles of the MreB cytoskeleton in B. subtilis, we used genome-wide yeast two-hybrid screens to identify proteins that physically associate with MreB, Mbl and MreBH. Stringent specificity assays were systematically performed to remove false positives and confirm the specificity of all potential interactions identified in the screens. A protein-protein interaction network centered on the three MreBs was generated which includes 16 protein partners. This interaction network provides insights into the links of MreB proteins with proteins belonging to several functional categories as well as proteins of unknown function. An exploratory study was conducted in silico and in vivo for 8 of the partner proteins identified in the network and allowed us to select one interaction for a more in-depth analysis. We next focused in the physical interaction between MreB and DapL, an essential protein presumably involved in the early steps of peptidoglycan biosynthesis. The characterization of DapL confirmed its essential role in cell wall synthesis. The MreB-DapL interaction was confirmed biochemically and we showed that MreB also associates with other proteins involved in the synthesis of the PG precursors (DapG, LysA and MurE). Together, these results suggest that B. subtilis MreB orchestrates the PG biosynthetic cytosolic machineries to achieve and maintain its rod shape.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Antibiotic sensitivity reveals that wall teichoic acids mediate DNA binding during competence in Bacillus subtilis

Despite decades of investigation of genetic transformation in the model Gram-positive bacterium Bacillus subtilis, the factors responsible for exogenous DNA binding at the surface of competent cells remain to be identified. Here, we report that wall teichoic acids (WTAs), cell wall-anchored anionic glycopolymers associated to numerous critical functions in Gram-positive bacteria, are involved in this initial step of transformation. Using a combination of cell wall-targeting antibiotics and fluorescence microscopy, we show that competence-specific WTAs are produced and specifically localized in the competent cells to mediate DNA binding at the proximity of the transformation apparatus. Furthermore, we propose that TuaH, a putative glycosyl transferase induced during competence, modifies competence-induced WTAs in order to promote (directly or indirectly) DNA binding. On the basis of our results and previous knowledge in the field, we propose a model for DNA binding and transport during genetic transformation in B. subtilis

Contrasting mechanisms of growth in two model rod-shaped bacteria

How cells control their shape and size is a long-standing question in cell biology. Many rod-shaped bacteria elongate their sidewalls by the action of cell wall synthesizing machineries that are associated to actin-like MreB cortical patches. However, little is known about how elongation is regulated to enable varied growth rates and sizes. Here we use total internal reflection fluorescence microscopy and single-particle tracking to visualize MreB isoforms, as a proxy for cell wall synthesis, in Bacillus subtilis and Escherichia coli cells growing in different media and during nutrient upshift. We find that these two model organisms appear to use orthogonal strategies to adapt to growth regime variations: B. subtilis regulates MreB patch speed, while E. coli may mainly regulate the production capacity of MreB-associated cell wall machineries. We present numerical models that link MreB-mediated sidewall synthesis and cell elongation, and argue that the distinct regulatory mechanism employed might reflect the different cell wall integrity constraints in Gram-positive and Gram-negative bacteria

Virus Evolution toward Limited Dependence on Nonessential Functions of the Host: the Case of Bacteriophage SPP1

All viruses are obligate intracellular parasites and depend on certain host cell functions for multiplication. However, the extent of such dependence and the exact nature of the functions provided by the host cell remain poorly understood. Here, we investigated if nonessential Bacillus subtilis genes are necessary for multiplication of bacteriophage SPP1. Screening of a collection of 2,514 single-gene knockouts of nonessential B. subtilis genes yielded only a few genes necessary for efficient SPP1 propagation. Among these were genes belonging to the yuk operon, which codes for the Esat-6-like secretion system, including the SPP1 receptor protein YueB. In addition, we found that SPP1 multiplication was negatively affected by the absence of two other genes, putB and efp. The gene efp encodes elongation factor P, which enhances ribosome activity by alleviating translational stalling during the synthesis of polyproline-containing proteins. PutB is an enzyme involved in the proline degradation pathway that is required for infection in the post-exponential growth phase of B. subtilis, when the bacterium undergoes a complex genetic reprogramming. The putB knockout shortens significantly the window of opportunity for SPP1 infection during the host cell life cycle. This window is a critical parameter for competitive phage multiplication in the soil environment, where B. subtilis rarely meets conditions for exponential growth. Our results in combination with those reported for other virus-host systems suggest that bacterial viruses have evolved toward limited dependence on nonessential host functions. IMPORTANCE A successful viral infection largely depends on the ability of the virus to hijack cellular machineries and to redirect the flow of building blocks and energy resources toward viral progeny production. However, the specific virus-host interactions underlying this fundamental transformation are poorly understood. Here, we report on the first systematic analysis of virus-host cross talk during bacteriophage infection in Gram-positive bacteria. We show that lytic bacteriophage SPP1 is remarkably independent of nonessential genes of its host, Bacillus subtilis, with only a few cellular genes being necessary for efficient phage propagation. We hypothesize that such limited dependence of the virus on its host results from a constant "evolutionary arms race" and might be much more widespread than currently thought

MreB-dependent inhibition of cell elongation during the escape from competence in Bacillus subtilis

During bacterial exponential growth, the morphogenetic actin-like MreB proteins form membrane-associated assemblies that move processively following trajectories perpendicular to the long axis of the cell. Such MreB structures are thought to scaffold and restrict the movement of peptidoglycan synthesizing machineries, thereby coordinating sidewall elongation. In Bacillus subtilis, this function is performed by the redundant action of three MreB isoforms, namely MreB, Mbl and MreBH. mreB and mbl are highly transcribed from vegetative promoters. We have found that their expression is maximal at the end of exponential phase, and rapidly decreases to a low basal level upon entering stationary phase. However, in cells developing genetic competence, a stationary phase physiological adaptation, expression of mreB was specifically reactivated by the central competence regulator ComK. In competent cells, MreB was found in complex with several competence proteins by in vitro pull-down assays. In addition, it co-localized with the polar clusters formed by the late competence peripheral protein ComGA, in a ComGA-dependent manner. ComGA has been shown to be essential for the inhibition of cell elongation characteristic of cells escaping the competence state. We show here that the pathway controlling this elongation inhibition also involves MreB. Our findings suggest that ComGA sequesters MreB to prevent cell elongation and therefore the escape from competence

MreC and MreD proteins are not required for growth of Staphylococcus aureus

The transmembrane proteins MreC and MreD are present in a wide variety of bacteria and are thought to be involved in cell shape determination. Together with the actin homologue MreB and other morphological elements, they play an essential role in the synthesis of the lateral cell wall in rod-shaped bacteria. In ovococcus, which lack MreB homologues, mreCD are also essential and have been implicated in peripheral cell wall synthesis. In this work we addressed the possible roles of MreC and MreD in the spherical pathogen Staphylococcus aureus. We show that MreC and MreD are not essential for cell viability and do not seem to affect cell morphology, cell volume or cell cycle control. MreC and MreD localize preferentially to the division septa, but do not appear to influence peptidoglycan composition, nor the susceptibility to different antibiotics and to oxidative and osmotic stress agents. Our results suggest that the function of MreCD in S. aureus is not critical for cell division and cell shape determination