Inhibitors and mechanism of phospho-N-acetylmuramyl-pentapeptide translocase (Escherichia coli)

Brandish, Philip Edward

January 1995

No description available.

572

Peptidoglycan synthesis; Antibiotics

Structural Analysis of Bacillus subtilis Spore Peptidoglycan During Sporulation

Meador-Parton, Jennifer L.

14 January 2000

Bacterial spore peptidoglycan (PG) is very loosely cross-linked relative to vegetative PG. Theories suggest that loosely cross-linked spore PG may have a flexibility which contributes to the attainment of spore core dehydration. The structure of the PG found in fully dormant spores has previously been examined in wild type and many mutant strains. These analyses showed little correlation between the degree of spore PG cross-linking and core dehydration. However, these studies only examined the structure of PG from dormant spores and did not allow for the structural analysis of spore PG during sporulation when actual spore PG synthesis and core dehydration occur. Structural analyses of developing spore PG from wild type Bacillus subtilis and eight mutant strains are included in this study. Structural analyses of developing spore PG suggest the following: a) the germ cell wall PG is synthesized first next to the inner forespore membrane; b) cross-linking is relatively high in the first 10% of spore PG synthesized; b) a rapid decrease in cross-linking is observed during synthesis of the next 20% of the spore PG; and c) this decrease is followed by an eightfold rise in the degree of cross-linking during synthesis of the final 70% of the spore PG. This increasing gradient of cross-linking was previously predicted to contribute to the attainment of spore core dehydration. However, analyses of mutant strains indicate this cross-linking gradient is not required for the attainment of spore dehydration. / Master of Science

heat resistance

endospore

cortex

sporulation

Bacillus subtilis

peptidoglycan

spore peptidoglycan synthesis

Bacterial Cell Wall Synthases Require Outer Membrane Lipoprotein Cofactors

Markovski, Monica

21 June 2013

To fortify their cytoplasmic membrane and protect it from osmotic rupture, most bacteria surround themselves with a peptidoglycan (PG) exoskeleton. The PG synthases that build this structure are called penicillin-binding proteins (PBPs). Since they are the targets of penicillin and related antibiotics, the structures and in vitro biochemical functions of the PBPs have been extensively studied. However, the in vivo functions of the PBPs and the factors they work with to build the PG meshwork remain poorly understood. PBPs work in the context of multicomponent complexes organized by cytoskeletal elements. A major outstanding question has been whether or not these complexes contain factors required for PBP function. I addressed this using Escherichia coli as a model system by taking advantage of the synthetic lethal phenotype resulting from simultaneous inactivation of the major PG synthases: PBP1a and PBP1b. Using a screen for mutants synthetically lethal with the inactivation of PBP1b, I identified LpoA as a factor required for PBP1a function. A colleague in the lab performed the analogous screen for mutants synthetically lethal with the inactivation of PBP1a and identified LpoB as a factor required for PBP1b function. We showed that the Lpo factors are outer membrane lipoproteins that form specific trans-envelope complexes with their cognate PBPs in the inner membrane and that LpoB can stimulate the activity of PBP1b in vitro. Our results reveal unexpected complexity in the control of PBP activity and indicate that they likely receive regulatory input from the outer membrane in addition to cytoskeletal elements in the cytoplasm. To investigate the role of LpoB in morphogenesis further, I took a genetic approach that has identified PBP1b* variants capable of functioning in vivo in the absence of LpoB. Preliminary characterization of these variants indicates that LpoB has cellular functions in addition to PBP1b activation and that LpoB may be important for coordinating the two different catalytic activities of PBP1b. Future study of these mutants is likely to uncover important insights into PBP function and their control by the Lpo factors. These insights may open new avenues for the development of novel therapeutics that target the PBPs.

cell envelope

Gram-negative

penicillin-binding proteins

peptidoglycan

peptidoglycan synthesis

peptidoglycan synthetic complex

microbiology

molecular biology

genetics

Rôle de la sérine-thréonine kinase StkP dans la division et la morphogenèse du pneumocoque / Role of the serine‐threonine kinase StkP in cell division and morphogenesis of Streptococcus pneumoniae

Fleurie, Aurore

02 October 2013

La bactérie Streptococcus pneumoniae peut provoquer de sérieuses pathologies chez l'homme telles que des pneumonies, méningites ou septicémies. L'étude de cette bactérie constitue donc un enjeu de santé publique international. Ces dernières années, il a été mis en évidence que les bactéries exprimaient des Sérine/Thréonine Protéine‐Kinases de type eucaryote (STPKs) et que ces dernières intervenaient dans la régulation de nombreux processus cellulaires. Une approche prometteuse serait donc de cibler les mécanismes de régulation contrôlés par les STPKs pour lutter contre les infections à pneumocoque. L'analyse du génome de S. pneumoniae a montré que cette bactérie possède un seul gène codant pour une STPK, la protéine StkP. Mes travaux de thèse ont montré que StkP est un acteur majeur de la division cellulaire et de la morphogenèse du pneumocoque. J'ai montré que son activité kinase est dépendante de la protéine GpsB et qu'elle phosphoryle spécifiquement plusieurs protéines dont la protéine de division DivIVA. L'ensemble de mes travaux permet de proposer un modèle dans lequel la triade StkP/GpsB/DivIVA régulerait finement la division et l'élongation cellulaire du pneumocoque. À plus long terme, ces travaux pourront servir de base à des études plus structurales pour développer des molécules bloquant les processus dépendants de la phosphorylation assurée par StkP, et générer ainsi de nouvelles molécules affectant le pouvoir pathogène du pneumocoque / The bacterium Streptococcus pneumoniae is the causative agent of several diseases such as pneumonia, meningitis or septicemia. The study of this bacterium represents thus an international health challenge. Over the last decade, bacteria have been shown to produce eukaryotic‐like Serine/Threonine Protein‐Kinases (STPKs) that are involved in the regulation of several cellular processes. A promising approach would be to target the regulatory mechanisms controlled by STPKs to combat pneumococcal infections. The pneumococcus possesses a single gene encoding for a STPK, the protein StkP. The aim of my work was to characterize the biological function of StkP. My work shows that StkP plays crucial roles in the cell division and morphogenesis of S. pneumoniae. I show that the cell division protein GpsB is required for the kinase activity of StkP that, in turn, specifically phosphorylates the cell division protein DivIVA. Altogether, I propose a model in which the StkP/GpsB/DivIVA triad finely tunes S. pneumonia cell division and elongation. These data could provide the basis for future structural studies to develop specific inhibitors of StkP‐mediated phosphorylation and affecting pneumococcal virulence

Phosphorylation

Streptococcus pneumoniae

Division bactérienne

Morphogenèse bactérienne

Synthèse du peptidoglycane

Microscopie

Génétique

Phosphorylation

Streptococcus pneumoniae

Bacterial division

Bacterial morphogenesis

Peptidoglycan synthesis

Microscopy

Genetics

571.993

Rôle du domaine extracellulaire de la sérine/thréonine-kinase StkP dans la division cellulaire et la morphogenèse du pneumocoque / Role of the extracellular domain of the serine/threonine-kinase StkP in pneumococcal cell division and morphogenesis

Zucchini, Laure

03 July 2017

Streptococcus pneumoniae (ou pneumocoque) est un agent pathogène humain responsable de maladies invasives et potentiellement mortelles. Les mécanismes impliqués dans le processus d'invasion restent largement inconnus, mais plusieurs observations suggèrent que les processus de signalisation impliquant la phosphorylation des protéines participeraient au caractère invasif du pneumocoque. Le génome de S. pneumoniae code pour une seule tyrosine-kinase (CpsD) et une seule sérine/thréonine-kinase (StkP). Cette dernière serait notamment impliquée dans la virulence, la compétence et la division cellulaire. Elle représente donc une cible thérapeutique potentielle intéressante pour lutter contre les infections liées au pneumocoque. L'objectif de cette thèse a donc été de caractériser le rôle de cette sérine/thréonine-kinase StkP dans la division cellulaire du pneumocoque. StkP est une protéine transmembranaire qui se caractérise par la présence de motifs structuraux conservés dans son domaine catalytique appelés motifs de Hanks. De plus, StkP possède un domaine extracellulaire composé de la répétition de quatre domaines PASTA (Penicillin-binding protein And Serine/Threonine kinase Associated). Le modèle actuel suggère que ces domaines PASTA seraient capables de fixer des fragments de la paroi cellulaire afin de permettre l'activation de StkP qui se comporterait donc comme un récepteur membranaire permettant de réguler la division cellulaire du pneumocoque. Mes travaux de thèse ont permis de revisiter ce modèle en démontrant que les domaines PASTA ne servent pas uniquement à contrôler l'activité protéine-kinase de StkP mais également à contrôler l'épaisseur de la paroi cellulaire et ainsi permettre la constriction de la cellule. Plus précisément, j'ai démontré que le domaine PASTA distal est spécialisé dans l'interaction avec une hydrolase de la paroi cellulaire alors que les trois autres domaines PASTA sont nécessaires à l'activité kinase de StkP mais également au positionnement du domaine PASTA distal. Ainsi, le domaine extracellulaire de StkP se comporterait comme une règle permettant de définir l'épaisseur de la paroi cellulaire de la bactérie. Ces travaux permettent donc de proposer un nouveau modèle d'activation et de régulation de la division cellulaire par la sérine/thréonine-kinase StkP / Streptococcus pneumoniae (the pneumococcus) is one of the most important human pathogens that causes potentially fatal invasive diseases. Mechanisms required for the pneumococcal invasion process remain largely unknown, but several observations suggest that phosphorylation-based signaling processes will be at play in the invasiveness of the pneumococcus. S. pneumoniae encodes only one tyrosine-kinase (CpsD) and one serine/threonine-kinase (StkP). The latter would be involved in virulence, competence, and cell division. StkP represent therefore a promising target to combat pneumococcal infections. My aims were to better understand the role of StkP in pneumococcal cell division. StkP is a transmembrane protein characterized by the presence of a series of conserved structural motifs called Hanks motifs in its catalytic domain. In addition, StkP possesses an extracellular domain composed of the repetition of four PASTA domains (Penicillin-binding protein And Serine/Threonine kinase Associated). The current model proposes that PASTA domains are able to bind cell wall fragments resulting in StkP kinase activation. StkP would thus behave as an authentic kinase receptor regulating cell division. My thesis works has allowed to revisit this model by showing that PASTA domains do not only serve StkP kinase activation. Rather, they contribute to determine the cell wall thickness and govern cell constriction. More precisely, I demonstrated that the distal PASTA domain possesses unique features for the binding of a cell wall hydrolase whereas the other three contributes to StkP kinase activation and the positioning of the distal PASTA domain. Thus, the extracellular domain of StkP acts as a ruler determining the cell wall thickness. This work allows to propose an alternative model of activation and regulation of cell division by the serine/threonine-kinase StkP

Streptococcus pneumoniae

Division cellulaire

Morphogenèse bactérienne

Synthèse du peptidoglycane

Phosphorylation

Sérine/thréonine protéine-kinase

Génétique

Microscopie

Streptococcus pneumoniae

Cell division

Bacterial morphogenesis

Peptidoglycan synthesis

Phosphorylation

Serine/threonine protein-kinase

Genetics

Microscopy

572