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1	Studies on cell wall assembly in Bacillus subtilis Sturman, A. J. January 1981 (has links) No description available. 579 Cell division; Bacterial cell wall
2	Development of a method to generate a soluble substrate for lytic transglycosylases Mark, Adam L. 18 April 2011 (has links) Peptidoglycan, the major component of the bacterial cell wall, is essential for cell viability. Several important antibiotics disrupt peptidoglycan metabolism, including the β-lactams and vancomycin. There are several bacterial enzymes involved in peptidoglycan metabolism that are not yet the target of antibiotics, such as the lytic transglycosylases (LTs). Relatively little experimental characterization has been done on LTs, due largely to the difficulties of working with insoluble, heterogeneous, and highly variable peptidoglycan. This research develops a method for the generation of a soluble, homogeneous oligosaccharide substrate that can be used to study LTs. The approach taken was based on the enzymatic degradation of peptidoglycan into fragments of a specific nature, and their separation by HPLC. This work identifies the challenges associated with this approach, and discusses the potential flaws in the 'top-down' generation of a soluble substrate. / This thesis was typeset with LaTeX using Minion Pro and Myriad Pro typefaces. Peptidoglycan Lytic transglycosylase HPAEC-PAD MALDI-TOF MS Oligosaccharide Bacterial cell wall
3	Structure et assemblage de complexes des enzymes Mur, essentielles pour la synthèse de la paroi bactérienne / Structure and assembly of Mur enzyme complexes, essential for bacterial cell wall biosynthesis Laddomada, Federica 22 December 2017 (has links) Les enzymes de la famille Mur (MurA-MurG) sont essentielles pour la survie bactérienne, car elles catalysent les étapes cytoplasmiques de la biosynthèse du peptidoglycane, la principale composante de la paroi cellulaire. En outre, les Murs métabolisent des molécules qui sont absentes chez les eucaryotes, et ces enzymes sont structurellement et biochimiquement tractables. Cependant, malgré le fait que nombreux inhibiteurs anti-Mur ont été développés, un nombre tres réduit de ces molécules ont montré une activité antibactérienne prometteuse, ce qui a incité l'hypothèse selon laquelle, dans le cytoplasme bactérien, les enzymes Mur peuvent exister dans un complexe où les sites actifs sont à proximité, bloquant donc l'accès de petites molécules venant de l'extérieur. Cette hypothèse est soutenue par l'observation selon laquelle, dans de nombreux organismes, les gènes codant pour les enzymes Mur sont présents dans un seul opéron, souvent dans le même ordre; en outre, souvent des paires de gènes sont fusionnées pour générer un seul polypeptide, préconisant la possibilité que des complexes entre ces enzymes pourraient être formés dès qu'ils sont synthétisés. Nous avons obtenu les premières informations structurales et fonctionnelles sur la forme fusionnée MurE-MurF, présente dans le pathogène humain Bordetella pertussis, et nous avons montré qu'elle interagit avec la glycosyltransférase périphérique MurG, ce qui suggère la présence d'un complexe enzymatique ternaire. De façon intéressante, nous avons constaté que MurG de B. pertussis est capable de s'associer avec elle-même et de former différentes espèces oligomériques. Cette découverte pourrait renforcer le rôle de MurG en tant que protéine agissant comme une plateform capable d'ancrer d'autres enzymes Mur à la face interne de la membrane cytoplasmique bactérienne. Nos resultats pourront également être explorés pour comprendre le rôle potentiel de MurG en tant que régulateur de l'activité des enzymes de synthèse du PG. Ces résultats passionnants ouvriront le chemin vers la compréhension du mecanisme d’interaction des enzymes Mur dans le cytoplasme bactérien et pourraient permettre l'emploi éventuel des Murs comme cibles de facto pour développer de nouveaux antibiotiques. / Enzymes of the Mur family (MurA-MurG) are essential for bacteria, since they catalyse the cytoplasmic steps of peptidoglycan biosynthesis, the major component of bacterial cell wall; they metabolize molecules that do not exist in eukaryotes, and are structurally and biochemically tractable. However, despite the fact that many anti-Mur inhibitors have been developed, few of these molecules have shown promising antibacterial activity, which has prompted the hypothesis that within the bacterial cytoplasm Mur enzymes may exist in a complex where the active sites are in closed proximity, blocking small molecule access from the outside. This suggestion is supported by the observation that in many organisms, genes encoding Mur enzymes are present in a single operon, often in the same order, and often pairs of genes are fused to generate a single polypeptide, advocating the possibility that complexes between these enzymes could be formed as soon as they are synthesized. We have obtained the first structural and functional information on the MurE-MurF fused form, present in the human pathogen Bordetella pertussis, and shown that it interacts with the peripheral glycosyltransferase MurG, suggesting the presence of a ternary enzymatic complex. Interestingly, we have found that B. pertussis MurG is able to self-associate and form different oligomeric species. This finding could strengthen the hypothesis of MurG as a scaffold protein capable of anchoring other Murs to the inner face of bacterial inner membrane, but could be also further explored to understand its potential role as a regulator of the activity of PG synthesis enzymes. These exciting results will open the path towards the understanding of how Mur enzymes interact within the bacterial cytoplasm, and could permit the eventual employment of Mur enzymes as de facto targets for novel antibiotic development. Cristallographie Infection bacterienne Paroi bacterienne Peptidoglycane Crystallography Bacterial infection Bacterial cell wall Peptidoglycan 530 540
4	Characterization of two Bacillus subtilis penicillin-binding protein-coding genes, ykuA (pbpH) and yrrR (pbpI) Wei, Yuping 06 September 2002 (has links) Penicillin-binding proteins (PBPs) are required in the synthesis of the cell wall of bacteria. In Bacillus subtilis, PBPs play important roles in the life cycle, including both vegetative growth and sporulation, and contribute to the formation of the different structures of vegetative cell wall and spore cortex. The B. subtilis genome sequencing project revealed there were two uncharacterized genes, ykuA and yrrR, with extensive sequence similarity to class B PBPs. These two genes are renamed and referred to henceforth as pbpH and pbpI, respectively. A sequence alignment of the predicted product of pbpH against the microbial protein database demonstrated that the most similar protein in B. subtilis is PBP2A and in E. coli is PBP2. This suggested that PbpH belongs to a group of the genes required for maintaining the rod shape of the cell. Study of a pbpH-lacZ fusion showed that pbpH was expressed weakly during vegetative growth and the expression reached the highest level at the transition from exponential phase to stationary phase. The combination of a pbpA deletion and the pbpH deletion was lethal and double mutant strains lacking pbpH and pbpC or pbpI (also named yrrR) were viable. The viable mutants were indistinguishable from the wild-type except that the vegetative PG of the pbpC pbpH strain had a slightly slightly lower amount of disaccharide tetrapeptide with 1 amidation and higher amount of disaccharide tripeptide tetrapeptide with 2 amidations when compared to others strains. This suggests that PbpC (PBP3) is involved in vegetative PG synthesis but only affects the PG structure with a very low efficiency. A pbpA pbpH double mutant containing a xylose-regulated pbpH gene inserted into the chromosome at the amyE locus was constructed. Depletion of PbpH resulted in an arrest in cell growth and a dramatic morphological change in both vegetative cells and outgrowing spores. Vegetative cells lacking pbpA and pbpH expression swelled and cell elongation was arrested, leading to the formation of pleiomorphic spherical cells and eventual lysis. In these cells, cell septations were randomly localized, cell walls and septa were thicker than those seen in wild type cells, and the average cell width and volume were larger than those of cells expressing pbpA or pbpH. The vegetative PG had an increased abundance of one unidentified muropeptide. Spores produced by the pbpA pbpH double mutant were able to initiate germination but the transition of the oval-shaped spores to rod-shape cells was blocked. The outgrowing cells were spherical, gradually enlarged, and eventually lysed. Outgrowth of these spores in the presence of xylose led to the formation of helical cells. Thus, PbpH is apparently required for maintenance of cell shape, specifically for cell elongation. PbpH and PBP2a play a redundant role homologous to that of PBP2 in E. coli. A sequence alignment of the predicted product of pbpI against the microbial protein database demonstrated that the most similar protein in B. subtilis is SpoVD and in E. coli is PBP3. This suggested that PbpI belongs to the group of the genes required for synthesis of the spore or septum PG. PbpI was identified using radio-labeled penicillin and found to run underneath PBP4 on SDS-PAGE. PbpI is therefore renamed PBP4b. Study of a pbpI-lacZ fusion showed that pbpI was expressed predominantly during early sporulation. A putative sigma F recognition site is present in the region upstream of pbpI and studies using mutant strains lacking sporulation-specific sigma factors demonstrated that the expression of pbpI is mainly dependent on sigma factor F. A pbpI single mutant, a pbpI pbpG double mutant, and a pbpI pbpF double mutant were indistinguishable from the wild-type. The sporulation defect of a pbpI pbpF pbpG triple mutant was indistinguishable from that of a pbpF pbpG double mutant. Structure parameters of the forespore PG in a pbpI spoVD strain are similar to that of a spoVD strain. These results indicate that PBP4b plays a unknown redundant role. / Master of Science bacterial cell wall penicillin-binding protein (PBP) yrrR (pbpI) ykuA (pbpH) Bacillus subtilis
5	Using Live Cell Imaging to Probe Biogenesis of the Gram-Negative Cell Envelope Yao, Zhizhong January 2012 (has links) In Gram-negative bacteria, the three-layered cell envelope, including the cell wall, outer and inner membranes, is essential for cell survival in the changing, and often hostile environments. Conserved in all prokaryotes, the cell wall is incredibly thin, yet it functions to prevent osmotic lysis in diluted conditions. Based on observations obtained by genetic and chemical perturbations, time-lapse live cell imaging, quantitative imaging and statistical analysis, Part I of this dissertation explores the molecular and physical events leading to cell lysis induced by division-specific beta-lactams. We found that such lysis requires the complete assembly of all essential components of the cell division apparatus and the subsequent recruitment of hydrolytic amidases. We propose that division-specific beta-lactams lyze cells by inhibiting FtsI (PBP3) without perturbing the normal assembly of the cell division machinery and the consequent activation of cell wall hydrolases. On the other hand, we demonstrated that cell lysis by beta-lactams proceeds through four physical phases: elongation, bulge formation, bulge stagnation and lysis. Bulge formation dynamics is determined by the specific perturbation of the cell wall and outer membrane plays an independent role in stabilizing the bulge once it is formed. The stabilized bulge delays lysis, and allows escape and recovery upon drug removal. Asymmetrical in structure and unique to Gram-negative bacteria, outer membrane prevents the passage of many hydrophobic, toxic compounds. Together with inner membrane and the cell wall, three layers of the Gram-negative cell envelope must be well coordinated throughout the cell cycle to allow elongation and division. Part II of this dissertation explores the essentiality of the LPS layer, the outer leaflet of the outer membrane. Using a conditional mutant severely defective in LPS transport, we found that mutations in the initiation phase of fatty acid synthesis suppress cells defective in LPS transport. The suppressor cells are remarkably small with a 70% reduction in cell volume and a 50 % reduction in growth rate. They are also blind to nutrient excess with respect to cell size control. We propose a model where fatty acid synthesis regulates cell size in response to nutrient availability, thereby influencing growth rate. / Chemistry and Chemical Biology bacterial cell wall beta-lactam antibiotics penicillin-binding protein microbiology biophysics chemistry live cell imaging outer membrane lipopolysaccharide
6	Roentgenstrukturuntersuchungen an Glycopeptid-Antibiotika und ihren Komplexen mit Zellwandpeptiden Gram-positiver Bakterien / Glucopeptidantibiotics and their complexes with cell-wall peptides of gram-positive bacteria Lehmann, Christopher 31 October 2000 (has links) No description available. 540 Chemie Mathematics and Computer Science glycopeptide antibiotics complexes with cell wall models bacterial cell wall 35:25 S
7	Peptidoglycan recycling in the Gram-positive bacterium Staphylococcus aureus and its role in host-pathogen interaction Dorling, Jack January 2018 (has links) Bacteria are enclosed by a peptidoglycan sacculus, an exoskeleton-like polymer composed of glycan strands cross-linked by short peptides. The sacculus surrounds the cell in a closed bag-like structure and forms the main structural component of the bacterial cell wall. As bacteria grow and divide, cell wall remodelling by peptidoglycan hydrolases results in the release of peptidoglycan fragments from the sacculus. In Gram-negative bacteria, these fragments are efficiently trapped and recycled. Gram-positive bacteria however shed large quantities of peptidoglycan fragments into the environment. For nearly five decades, Gram-positive bacteria were thus assumed not to recycle peptidoglycan and this process has remained enigmatic until recently. In this thesis, the occurrence and physiological role of peptidoglycan recycling in the Gram-positive pathogen Staphylococcus aureus was investigated. S. aureus is an important pathogen, and is becoming increasingly resistant to many antibiotics. Through bioinformatic and experimental means it was determined that S. aureus may potentially recycle components of peptidoglycan and novel peptidoglycan recycling components were identified and characterised. Though disruption of putative peptidoglycan recycling in S. aureus appears not affect growth or gross morphology of this bacterium, potential roles for peptidoglycan recycling in cell wall homeostasis and in virulence were identified. This is to my knowledge the first demonstration of a potential role of peptidoglycan recycling in either of these aspects of bacterial physiology in any Gram-positive bacterium. This is an important step forward in understanding the basic biology of Gram-positive bacteria, and in understanding the mechanisms of virulence in S. aureus. Future study of this process in S. aureus and other Gram-positive bacteria promises to reveal yet further facets of this process and its functions, potentially leading to the identification of novel therapeutic approaches to combat infections.
8	Reguläre bakterielle Zellhüllenproteine als biomolekulares Templat Wahl, Reiner 17 May 2003 (has links) (PDF) Bacterial cell wall proteins (S-layer) are - due to both the capability to self-assemble into two-dimensional crystals and their distinct chemical and structural properties - suitable for the deposition of metallic particles at their surface . The cluster growth is subject of this thesis. The binding of metal complexes to S-layers of Bacillus sphaericus and Sporosarcina ureae and their subsequent reduction leads to the formation of regularly arranged platinum or palladium cluster arrays on the biomolecular template. A heterogeneous nucleation mechanism is proposed for this process consisting of the binding of metal complexes and their subsequent reduction. The kinetics of the process and the binding of the complexes to the protein are characterized by UV/VIS spectroscopy. This thesis focuses on structural investigations by means of transmission electron microscopy, electron holography, scanning force microscopy, image analysis, and image processing. Preferred cluster-deposition sites are determined by correlation averaging. A more precise determination and quantification is obtained by Multivariate Statistical Analysis. Furthermore a method for the electron beam induced formation of highly-ordered metallic cluster arrays in the transmission electron microscope and a fast screening method for surface layers of Gram-positive bacteria are presented. / Bakterielle Zellhüllenproteine (S-Layer) eignen sich durch ihre Fähigkeit zur Selbstassemblierung zu zweidimensionalen Kristallen und durch ihre besonderen chemischen und strukturellen Eigenschaften zur Abscheidung regelmäßiger metallischer Partikel auf ihrer Oberfläche. In dieser Arbeit wird das Clusterwachstum auf S-Layern untersucht. Die Anbindung von Metallkomplexen an S-Layer von Bacillus sphaericus und Sporosarcina ureae und deren Reduktion führt zur Abscheidung periodisch angeordneter metallischer Platin- bzw. Palladiumcluster auf dem Biotemplat. Für diese Clusterbildung wird ein heterogener Keimbildungsmechanismus vorgeschlagen, bestehend aus Komplexanbindung und Reduktion. Die Bestimmung der Prozeßkinetik und die Charakterisierung der Anbindung der Komplexe an das Protein erfolgt mittels UV/VIS-Spektroskopie. Den Schwerpunkt dieser Arbeit bilden strukturelle Untersuchungen mit Hilfe der Transmissionselektronenmikroskopie, der Elektronenholographie, der Rasterkraftmikroskopie und der Bildanalyse und Bildverarbeitung. Durch Korrelationsmittelung werden Strukturinformationen gewonnen, die eine Bestimmung der lateral bevorzugten Clusterpositionen ermöglichen. Für die auf S-Layern erzeugten Clusterarrays wird die Belegung der einzelnen Positionen mittels Multivariater Statistischer Analyse genauer quantifiziert. Außerdem werden eine Methode zur Erzeugung hochgeordneter metallischer Partikelarrays unter dem Einfluß des Elektronenstrahles im Transmissionselektronenmikroskop und eine Methode zum schnellen Test Gram-positiver Bakterienstämme auf die Existenz von S-Layern vorgestellt. Bildanalyse Bildverarbeitung Biotemplating S-Layer Transmissionselektronenmikroskopie Bacterial cell wall proteins Biotemplating Image analysis Image processing S-Layer Transmission electron microscopy ddc:29 rvk:UH 6300 Bacillus sphaericus Bildanalyse Bildverarbeitung Cluster Durchstrahlungselektronenmikroskopie Proteine Zelloberfläche
9	Reguläre bakterielle Zellhüllenproteine als biomolekulares Templat Wahl, Reiner 06 June 2003 (has links) Bacterial cell wall proteins (S-layer) are - due to both the capability to self-assemble into two-dimensional crystals and their distinct chemical and structural properties - suitable for the deposition of metallic particles at their surface . The cluster growth is subject of this thesis. The binding of metal complexes to S-layers of Bacillus sphaericus and Sporosarcina ureae and their subsequent reduction leads to the formation of regularly arranged platinum or palladium cluster arrays on the biomolecular template. A heterogeneous nucleation mechanism is proposed for this process consisting of the binding of metal complexes and their subsequent reduction. The kinetics of the process and the binding of the complexes to the protein are characterized by UV/VIS spectroscopy. This thesis focuses on structural investigations by means of transmission electron microscopy, electron holography, scanning force microscopy, image analysis, and image processing. Preferred cluster-deposition sites are determined by correlation averaging. A more precise determination and quantification is obtained by Multivariate Statistical Analysis. Furthermore a method for the electron beam induced formation of highly-ordered metallic cluster arrays in the transmission electron microscope and a fast screening method for surface layers of Gram-positive bacteria are presented. / Bakterielle Zellhüllenproteine (S-Layer) eignen sich durch ihre Fähigkeit zur Selbstassemblierung zu zweidimensionalen Kristallen und durch ihre besonderen chemischen und strukturellen Eigenschaften zur Abscheidung regelmäßiger metallischer Partikel auf ihrer Oberfläche. In dieser Arbeit wird das Clusterwachstum auf S-Layern untersucht. Die Anbindung von Metallkomplexen an S-Layer von Bacillus sphaericus und Sporosarcina ureae und deren Reduktion führt zur Abscheidung periodisch angeordneter metallischer Platin- bzw. Palladiumcluster auf dem Biotemplat. Für diese Clusterbildung wird ein heterogener Keimbildungsmechanismus vorgeschlagen, bestehend aus Komplexanbindung und Reduktion. Die Bestimmung der Prozeßkinetik und die Charakterisierung der Anbindung der Komplexe an das Protein erfolgt mittels UV/VIS-Spektroskopie. Den Schwerpunkt dieser Arbeit bilden strukturelle Untersuchungen mit Hilfe der Transmissionselektronenmikroskopie, der Elektronenholographie, der Rasterkraftmikroskopie und der Bildanalyse und Bildverarbeitung. Durch Korrelationsmittelung werden Strukturinformationen gewonnen, die eine Bestimmung der lateral bevorzugten Clusterpositionen ermöglichen. Für die auf S-Layern erzeugten Clusterarrays wird die Belegung der einzelnen Positionen mittels Multivariater Statistischer Analyse genauer quantifiziert. Außerdem werden eine Methode zur Erzeugung hochgeordneter metallischer Partikelarrays unter dem Einfluß des Elektronenstrahles im Transmissionselektronenmikroskop und eine Methode zum schnellen Test Gram-positiver Bakterienstämme auf die Existenz von S-Layern vorgestellt. info:eu-repo/classification/ddc/29 ddc:29
10	Synthesis of Carbohydrate-based Inhibitors of Antigen 85 Umesiri, Francis E. January 2010 (has links) No description available. Pharmaceuticals Biochemistry Biomedical Research Chemistry Organic Chemistry tuberculosis TB mycobacterium tuberculosis antigen 85' mycobacterial cell wall inhibitors of mycobacterial synthesis bacterial cell wall synthesis mycolyltransferase assay enzyme tuberculosis drugs new TB drugs drug design for TB

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