Precise Timing of Transcription by c-di-GMP Coordinates Cell Cycle and Morphogenesis in Caulobacter

Bacteria adapt their growth rate to their metabolic status and environmental conditions by modulating the length of their G1 period. Here we demonstrate that a gradual increase in the concentration of the second messenger c-di-GMP determines precise gene expression during G1/S transition in Caulobacter crescentus . We show that c-di-GMP stimulates the kinase ShkA by binding to its central pseudo-receiver domain, activates the TacA transcription factor, and initiates a G1/S-specific transcription program leading to cell morphogenesis and S-phase entry. Activation of the ShkA-dependent genetic program causes c-di-GMP to reach peak levels, which triggers S-phase entry and promotes proteolysis of ShkA and TacA. Thus, a gradual increase of c-di-GMP results in precise control of ShkA-TacA activity, enabling G1/S-specific gene expression that coordinates cell cycle and morphogenesis

Cohesive Properties of the Caulobacter crescentus Holdfast Adhesin Are Regulated by a Novel c-di-GMP Effector Protein

When encountering surfaces, many bacteria produce adhesins to facilitate their initial attachment and to irreversibly glue themselves to the solid substrate. A central molecule regulating the processes of this motile-sessile transition is the second messenger c-di-GMP, which stimulates the production of a variety of exopolysaccharide adhesins in different bacterial model organisms. In Caulobacter crescentus, c-di-GMP regulates the synthesis of the polar holdfast adhesin during the cell cycle, yet the molecular and cellular details of this control are currently unknown. Here we identify HfsK, a member of a versatile N-acetyltransferase family, as a novel c-di-GMP effector involved in holdfast biogenesis. Cells lacking HfsK form highly malleable holdfast structures with reduced adhesive strength that cannot support surface colonization. We present indirect evidence that HfsK modifies the polysaccharide component of holdfast to buttress its cohesive properties. HfsK is a soluble protein but associates with the cell membrane during most of the cell cycle. Coincident with peak c-di-GMP levels during the C. crescentus cell cycle, HfsK relocalizes to the cytosol in a c-di-GMP-dependent manner. Our results indicate that this c-di-GMP-mediated dynamic positioning controls HfsK activity, leading to its inactivation at high c-di-GMP levels. A short C-terminal extension is essential for the membrane association, c-di-GMP binding, and activity of HfsK. We propose a model in which c-di-GMP binding leads to the dispersal and inactivation of HfsK as part of holdfast biogenesis progression.IMPORTANCE Exopolysaccharide (EPS) adhesins are important determinants of bacterial surface colonization and biofilm formation. Biofilms are a major cause of chronic infections and are responsible for biofouling on water-exposed surfaces. To tackle these problems, it is essential to dissect the processes leading to surface colonization at the molecular and cellular levels. Here we describe a novel c-di-GMP effector, HfsK, that contributes to the cohesive properties and stability of the holdfast adhesin in C. crescentus We demonstrate for the first time that c-di-GMP, in addition to its role in the regulation of the rate of EPS production, also modulates the physicochemical properties of bacterial adhesins. By demonstrating how c-di-GMP coordinates the activity and subcellular localization of HfsK, we provide a novel understanding of the cellular processes involved in adhesin biogenesis control. Homologs of HfsK are found in representatives of different bacterial phyla, suggesting that they play important roles in various EPS synthesis systems

Charakterization of spontaneous phageresistant Vibrio cholerae O1 El Tor mutants

Vibrio cholerae, der Erreger der Cholera, ist ein Gram-negatives, fakultativ pathogenes Bakterium. In dieser Arbeit konnte die V. cholerae Oberflächenstruktur identifiziert werden, an die der temperente V.cholerae-Phage K139 adsorbiert. Phagenbindungs-Studien mit gereinigtem Lipopolysaccharid (LPS) ergaben, daß das O-Antigen der Serogruppe O1 den Phagenrezeptor darstellt. Zusätzlich wurden phagenresistente Mutanten des transluzenten O1 El Tor Inaba Stammes P27459 nach Inkubation mit einem lytischen K139-Derivat isoliert. Analysen des LPS-Laufverhaltens in Polyacrylamid-Gelen (PAA) zeigten, daß viele der Spontanmutanten defekte LPS-Moleküle synthetisierten, die entweder im O-Antigen, im Kernoligosaccharid oder in beidem betroffen waren.Phagenresistente Mutanten mit offensichtlich unverändertem LPS bildeten entweder transluzente oder opake Kolonien. Weiterhin wurden ausgewählte spontan phagenresistente Stämme genetisch analysiert. O-Antigen Mutanten wurden in Southernblot-Analysen mit spezifischen, gegen das bereits gut charakterisierte O-Antigen-Biosynthese-Gencluster (rfb) gerichtete Sonden untersucht. Zwei der O-Antigen negativen Stämme waren durch Insertion des IS-Elementes IS1004 in das rfb-Gencluster entstanden. Spontan phagenresistente Mutanten mit verändertem Kernoligosaccharid ohne O-Antigen (R-LPS-Mutanten) sind wahrscheinlich im Kernoligosaccharid-Biosynthese-Gencluster (waa) mutiert, das in der V. cholerae Datenbank identifiziert wurde. waaF, das für die Heptosyl-II-Transferase kodiert, wurde durch genetische Manipulation inaktiviert und zeigte im PAA-Gel das gleiche Migrationsverhalten wie zwei spontan phagenresistente Mutanten. In den Spontanmutanten konnte jedoch im Gegensatz zu der konstruierten Mutante durch ein WaaF-exprimierendes Plasmid lediglich das Kernoligosaccharid, nicht aber das O-Antigen wiederhergestellt werden. Weitere genetische Analysen ergaben, daß eine der Spontanmutanten 546 bp deletiert hatte, die Teile von waaF und waaL betrafen, letzteres kodiert dabei vermutlich für die O-Antigen-Ligase. Spontanmutanten mit intaktem O-Antigen aber verändertem Kernoligosaccharid konnten als galU-Mutanten charakterisiert werden, die auch im Galaktosekatabolismus beeinträchtigt waren. Zusätzlich wurden zwei weitere gal-Gene, galE und galK, durch genetische Manipulation inaktiviert. Diese Mutanten konnten ebenfalls keine Galaktose mehr verstoffwechseln, synthetisierten aber ein intaktes LPS. In Gegenwart hoher Galaktosekonzentrationen wurde in galU- und galE- Mutanten aufgrund der Defekte im Gal-Stoffwechsel Lyse beobachtet. Zusätzlich wurde die Rolle von galU und galE in der Biofilmbildung untersucht. Da der transluzente Wildtyp (Wt) im Gegensatz zu Opakvarianten keinen Biofilm bilden konnte, wurden galE und galU auch in einer Opakvariante inaktiviert. galU- und galE-Mutationen erzeugten in der Opakvariante wieder eine transluzente Koloniemorphologie und einen biofilm-negativen Phänotyp an abiotischen Oberflächen. Diese Daten deuten an, daß die Synthese von UDP-Galaktose ausgehend von UDP-Glukose für die Synthese des Exopolysaccharides (VPS) notwendig ist. Virulenzstudien in neugeborenen Mäusen ergaben, daß O-Antigen negative Stämme sowie galU-Mutanten sehr viel schlechter und R-LPS-Mutanten nicht mehr im Dünndarm kolonisieren konnten. Da galE und galEK-Mutanten ebenso gut wie der Wt kolonisierten, konnte ausgeschlossen werden, daß toxische Galaktose-Effekte für den Kolonisierungsdefekt der galU-Mutante verantwortlich waren. Zusätzlich wurde die Überlebensfähigkeit der LPS-Mutanten in Gegenwart von verschiedenen Substanzen, die nachweislich im menschlichen Dünndarm vorkommen, unter „in vitro“ Bedingungen untersucht. R-LPS und galU-Mutanten waren im Vergleich mit dem Wt sensitiver gegenüber schwachen organischen Säuren, Defensinen, dem Komplementsystem und Gallensäuren. O-Antigen negative Stämme waren dagegen weiterhin resistent gegenüber Gallensäuren und schwachen organischen Säuren aber sensitiv gegen die Komponenten des angeborenen Immunsystems. Bisher wurde für keine der LPS-Mutanten eine größere Beeinträchtigung weiterer Virulenzfaktoren, wie z.B. Motilität, Synthese der Pili TCP oder Choleratoxin-Produktion festgestellt. Auch die Zusammensetzung der Proteine in der äußeren Membran war offensichtlich nicht beeinträchtigt, allerdings wurde beobachtet, daß aus galU Mutanten in geringem Maße und aus R-LPS Mutanten in verstärktem Maße periplasmatische Proteine in den Überstand diffundieren können. Diese Ergebnisse deuten an, daß nicht nur das O-Antigen, wie bereits bekannt, sondern auch eine spezifische Kernoligosaccharid-Struktur für eine effektive Kolonisierung von V. cholerae essentiell ist. Der Grund dafür ist höchstwahrscheinlich in der Ausbildung einer stabilen äußeren Membran zu suchen, die die Persistenz in Gegenwart bakteriozider Substanzen des Dünndarms ermöglicht.Vibrio cholerae is a Gram-negative, facultative pathogen and is the causative agent of cholera. In this study the adsorption site of the temperate phage K139 on the bacterial cell surface was determined. Phage-binding studies with purified lipopolysaccharide (LPS) showed that the O-antigen of the serogroup O1 serves as the phage receptor. In addition, phage resistant mutants of the O1 El Tor Inaba strain P27459 were screened by using a virulent isolate of phage K139. Analysis of the LPS by PAGE migration patterns revealed that most of the spontaneous mutants synthesize incomplete LPS molecules, either composed of defective O-antigen or core oligosaccharide. Phage resistent isolates with apparently normal LPS form either translucent or opaque colonies. The genetic nature of spontaneous phage resistant strains was investigated. O-antigen negative strains were investigated by Southern hybridization with probes specific for the well known O1-antigen biosynthesis cluster (rfb). Two of the investigated O-antigen negative mutants revealed insertions of element IS1004 into the rfb-gene cluster. Spontaneous phage resistant R-LPS mutants were found to synthesize an altered core without attached O-antigen. This type of mutants are most likely affected in the core oligosaccharide biosynthesis gene cluster (waa), which was identified by searching the V. cholerae genomic database. waaF, encoding heptosyl-II-transferase, was inactivated and the LPS was found to have the same migration behaviour in PAA gels than two spontaneous mutants. However, in contrast to the constructed waaF mutant complementation with waaF in trans restored only the core oligosaccharide but not the O-antigen synthesis in the spontaneous mutants. Further analysis revealed that one mutant had a deletion of 546 bp affecting waaF and waaL, the latter is thought to encode the putative O-antigen-ligase. Spontaneous mutants with intact O-antigen but altered core oligosaccharide were identified as galU mutants, which were also affected in the galactose catabolism. Other gal genes, galE and galK, were inactivated and these mutants were also found to be defective in the catabolism of exogenous galactose but synthesized an apparently normal LPS. Additionally, galU and galE mutants were found to lyse in the presence of high galactose concentrations. Furthermore the role of galU and galE in biofilm formation was investigated. In contrast to the spontaneous phage resistant opaque colony variant the translucent wt-strain was unable to form a biofilm, therefore the galE and galU mutations were also introduced into the opaque colony variant. galU and galE mutants of the opaque strain were translucent and unable to form a biofilm on abiotic surfaces, suggesting that the synthesis of UDP-galactose, via UDP-glucose, is essential for the biosynthesis of the exopolysaccharide. Virulence studies in infant mice indicated that O-antigen negative mutants, galU and R-LPS mutants but not galE and galEK mutants were defective in colonization of the mouse small intestine, excluding any toxic galactose effects in the gut. By investigating the sensitivity to several substances known to be present in the intestine „in vitro“, it was shown that galU and R-LPS mutants were more sensitive to weak organic acids, cationic antimicrobial peptides, the complement system and bile salts. O-antigen negative strains were found to be sensitive against gut-associated bacteriocidal substances, but they displayed significant resistance to bile salts and organic acids. No gross change in other virulence determinants such as motility, synthesis of pili TCP, choleratoxin production or outer-membrane proteins has yet been found for any of the LPS mutants. However, some periplasmic leakage for galU and significant leakage for R-LPS mutants was observed. These results suggest that not only the O-antigen, as already known, but also a specific core oligosaccharide architecture seems to be required for V. cholerae colonization, most probably in providing resistance against bacteriocidal substances

Expression, crystallization and preliminary X-ray analysis of an outer membrane protein from Thermus thermophilus HB27

The cell envelope of the thermophilic bacterium Thermus thermophilus is multilayered and includes an outer membrane with integral outer membrane proteins that are not well characterized. The hypothetical protein TTC0834 from T. thermophilus HB27 was identified as a 22 kDa outer membrane protein containing eight predicted -strands. TTC0834 was expressed with an N-terminal His tag in T. thermophilus HB8 and detected in the S-layer/outer membrane envelope fraction. His-TTC0834 was purified and crystallized under various conditions. Native data sets were collected to 3.2 Å resolution and the best diffracting crystals belonged to space group P3121 or P3221, with unit-cell parameters a = b = 166.67, c = 97.53 Å

Crystal Structure of a Major Outer Membrane Protein from Thermus thermophilus HB27

The thermophilic eubacterium Thermus thermophilus belongs to one of the oldest branches of evolution and has a multilayered cell envelope that differs from that of modern Gram-negative bacteria. Its outer membrane contains integral outer membrane proteins (OMPs), of which only a few are characterized. TtoA, a new p-barrel OMP, was identified by searching the genome sequence of strain HB27 for the presence of a C-terminal signature sequence. The structure of TtoA was determined to a resolution of 2.8 Å, representing the first crystal structure of an OMP from a thermophilic bacterium. TtoA consists of an eight-stranded p-barrel with a large extracellular part to which a divalent cation is bound. A five-stranded extracellular β-sheet protrudes out of the membrane-embedded transmembrane barrel and is stabilized by a disulfide bridge. The edge of this β-sheet forms crystal contacts that could mimic interactions with other proteins. In modem Gram-negative bacteria, the C-terminal signature sequence of OMPs is required for binding to an Omp85 family protein as a prerequisite for its assembly. We present hints that a similar assembly pathway exists in T. thermophilus by an in vitro binding assay, where unfolded TtoA binds to the Thermus Omp85 family protein TtOmp85, while a mutant without the signature sequence does not