Pathogenesis of 'Cronobacter' Species: Enterotoxin Production, Adhesion and Invasion of the Blood Brain Barrier

Abdesselam, Kahina

21 August 2012

Cronobacter species cause serious infections such as meningitis and enteritis in newborns and neonates, with the major vehicle being contaminated powdered infant formula. The main objectives of this study were i) to identify potential virulence factors, such as enterotoxin production; ii) characterize the gene(s) involved in adhesion and invasion of the human brain microvascular endothelial cells (HBMEC); and iii) determine whether strains from clinical, food, and environmental sources differ in their ability to produce surface-attached bacterial aggregates, known as biofilms. Random transposon mutagenesis was used on strains demonstrating the best adherence and invasion to blood- brain barrier cell lines (BBB). Isogenic mutants were then screened for increased or decreased adherence and invasion. Screening of the transposon library identified one isogenic mutant of a clinical strain which lost the ability to adhere to BBB cells. The transposon rescue revealed the insertion site to be within a diguanylate cyclase (DGC) gene. The major function of DGC in many Gram-negative bacteria is to synthesize cyclic diguanylate (c-di-GMP), a secondary bacterial metabolite known for regulating biofilm formation, motility, and virulence or aspects of microbial pathogenicity. Based on the findings of this study, DGC appears to play an important role in Cronobacter species’ ability to produce biofilms and may also have a role of the pathogenicity in the microorganism.

Cronobacter spp.

Enterotoxin production

Biofilms

Diguanylate cyclase

Threonine Synthase

Characterization of cyclic-di-GMP signaling with the Lyme spirochete, Borrelia burgdorferi

Kostick, Jessica

23 September 2011

Lyme disease is a tick-borne infection caused by Borrelia burgdorferi, B. garinii, and B. afzelii. These spirochetes experience environmental fluctuations as they are passed between mammalian and Ixodes tick hosts throughout their enzootic cycle. Recent studies have suggested cyclic diguanylate (c-di-GMP), a ubiquitous secondary messenger, is a key modulator of B. burgdorferi adaptive responses and may play a significant role in cycle progression. In this study, we examined the impact of the sole diguanylate cyclase (Rrp1), c-di-GMP binding proteins (PlzA and PlzB), and HD-GYP-containing phosphodiesterase (PdeB) in disease establishment of both murine and Ixodes tick systems. Strains harboring targeted gene deletions or plasmid-based constitutive gene expression constructs were generated. Rrp1 was required for tick colonization, yet overexpression abolished murine disease, thus implicating the requirement of finely regulated c-di-GMP levels for enzootic cycle progression. Deletion of rrp1 disrupted translational motion and swarming patterns by causing extended cell runs, eliminating stops/flexes, and reducing swarming capabilities. This was attributed to a defect in N-acetyl-D-glucosamine (NAG) metabolism and chemotaxis. NAG is a major source of nutrition for B. burgdorferi within the tick environment; therefore this defect would impede spirochete migration towards feeding ticks, as well as pathogen uptake and survival within the Ixodes vector. In contrast, the downstream c-di-GMP effector, PlzA, was critical for murine disease but nonessential for survival within ticks nor functionally complemented by PlzB. Deletion of plzA altered strain motility and swarming similarly to the rrp1 deletion mutant, yet had a distinct phenotype with significantly slower translational motion and no affect on NAG chemotaxis and metabolism. This indicates B. burgdorferi could possess alternate c-di-GMP effectors or Rrp1 could be directly influencing these cellular processes. Uniquely, PdeB did not abolish murine infection via needle inoculation, but wasrequired for natural transmission from ticks. This defect was linked to the decreased tick colonization efficiency upon pdeB deletion. Together, these analyses indicate that c-di-GMP signaling is an important virulence mechanism of Borrelia burgdorferi and demonstrate the complexity of this signaling pathway in an arthropod-borne pathogen. The data presented here additionally provide significant new insight into the gene regulatory mechanisms of the Lyme disease spirochetes.

Borrelia

cyclic-di-GMP

enzootic cycle

diguanylate cyclase

phosphodiesterase

Rrp1

PlzA

PlzB

PdeB

Medicine and Health Sciences

ASSESSMENT OF A PREDICTED DIGUANYLATE CYCLASE IN TREPONEMA DENTICOLA

Patel, Dhara T

01 January 2018

Periodontal disease is a progressive inflammatory condition that is characterized by the reabsorption of alveolar bone, the destruction of connective tissue, and edentulism. It is caused by a dysbiosis in the oral microbiome as a result of a shift from a Gram-positive aerobic bacterial population, to one that becomes more Gram-negative and anaerobic. Treponema denticola is thought to drive this diseased state based on its role as a keystone periopathogen. A major component of T.denticola’s invasiveness is its motility, which allows the spirochete to penetrate and disseminate through tissues. This motility, which has been seen to be crucial to the invasiveness in other spirochetes through deletion studies, is often regulated by the second messenger, c-di-GMP. In this study, biochemical and biophysical assays were utilized to determine that the predicted diguanylate cyclase TDE0125 converts GTP to c-di-GMP. This elucidates further function of the c-di-GMP regulatory network in T. denticola.

Treponema denticola

Diguanylate cyclase

c-di-GMP

TDE0125

Spirochete

Bacteriology

Microbiology

Pathogenesis of 'Cronobacter' Species: Enterotoxin Production, Adhesion and Invasion of the Blood Brain Barrier

Abdesselam, Kahina

21 August 2012

Cronobacter species cause serious infections such as meningitis and enteritis in newborns and neonates, with the major vehicle being contaminated powdered infant formula. The main objectives of this study were i) to identify potential virulence factors, such as enterotoxin production; ii) characterize the gene(s) involved in adhesion and invasion of the human brain microvascular endothelial cells (HBMEC); and iii) determine whether strains from clinical, food, and environmental sources differ in their ability to produce surface-attached bacterial aggregates, known as biofilms. Random transposon mutagenesis was used on strains demonstrating the best adherence and invasion to blood- brain barrier cell lines (BBB). Isogenic mutants were then screened for increased or decreased adherence and invasion. Screening of the transposon library identified one isogenic mutant of a clinical strain which lost the ability to adhere to BBB cells. The transposon rescue revealed the insertion site to be within a diguanylate cyclase (DGC) gene. The major function of DGC in many Gram-negative bacteria is to synthesize cyclic diguanylate (c-di-GMP), a secondary bacterial metabolite known for regulating biofilm formation, motility, and virulence or aspects of microbial pathogenicity. Based on the findings of this study, DGC appears to play an important role in Cronobacter species’ ability to produce biofilms and may also have a role of the pathogenicity in the microorganism.

Cronobacter spp.

Enterotoxin production

Biofilms

Diguanylate cyclase

Threonine Synthase

Pathogenesis of 'Cronobacter' Species: Enterotoxin Production, Adhesion and Invasion of the Blood Brain Barrier

Abdesselam, Kahina

January 2012

Cronobacter species cause serious infections such as meningitis and enteritis in newborns and neonates, with the major vehicle being contaminated powdered infant formula. The main objectives of this study were i) to identify potential virulence factors, such as enterotoxin production; ii) characterize the gene(s) involved in adhesion and invasion of the human brain microvascular endothelial cells (HBMEC); and iii) determine whether strains from clinical, food, and environmental sources differ in their ability to produce surface-attached bacterial aggregates, known as biofilms. Random transposon mutagenesis was used on strains demonstrating the best adherence and invasion to blood- brain barrier cell lines (BBB). Isogenic mutants were then screened for increased or decreased adherence and invasion. Screening of the transposon library identified one isogenic mutant of a clinical strain which lost the ability to adhere to BBB cells. The transposon rescue revealed the insertion site to be within a diguanylate cyclase (DGC) gene. The major function of DGC in many Gram-negative bacteria is to synthesize cyclic diguanylate (c-di-GMP), a secondary bacterial metabolite known for regulating biofilm formation, motility, and virulence or aspects of microbial pathogenicity. Based on the findings of this study, DGC appears to play an important role in Cronobacter species’ ability to produce biofilms and may also have a role of the pathogenicity in the microorganism.

Cronobacter spp.

Enterotoxin production

Biofilms

Diguanylate cyclase

Threonine Synthase

Kinetická analýza enzymové aktivity modelových hemových senzorových proteinů / Enzyme activity analysis of function domains belonging to model heme-containing sensor proteins

Prošková, Veronika

January 2018

EN This Ph.D. thesis focuses on the heme containing gas sensor proteins. These proteins are predominantly present in bacteria, in which play an important role in processes like, sporulation, antibiotic resistance and so on. Heme containing sensor proteins composed of two domains. First one is a globin domain, which contains the heme molecule. Interaction of heme with gas molecule acts as a signal for the activation/inactivation of the second functional domain. Part of this thesis is formed by a review, which summarized the current knowledge about heme containing sensor proteins. In the next part of this thesis we focused on three representatives from the group of oxygen sensor proteins - histidine kinase AfGcHK, diguanylate cyclase YddV and phosphodiesterase EcDOS. The main aim of this thesis was to solve the mechanism of interdomain/intraprotein signal transduction in two oxygen sensor proteins with globin fold of their sensor domain (AfGcHK, YddV). For this purpose, we used the kinetic analysis of their functional domain activity and the methods of structural biology. We also studied the mechanism of interprotein signal transduction in AfGcHK and its cognate partner RR protein. It was also tested, how the presence of sodium disulfide affects the functional properties of oxygen sensor proteins...

Identification of AlgZ Regulator, PA2771, and Effects on Motility and Virulence in P. aeruginosa

hughes, abigail, Pritchett, Chris, Dr.

04 April 2018

Pseudomonas aeruginosa is an important nosocomial infection that has the potential to infect almost every tissue of the human body though it is mainly opportunistic, due to the organism’s intrinsic antibiotic resistance is becoming increasingly difficult to treat. Two-component systems (TCS) rely on a signal sensed from the outside environment by the sensor histidine kinase to initiate phosphotransfer to the response regulator, which may then regulate virulence factors in the organism in response to a changing environment. One important two-component system in P. aeruginosa is the AlgZ/R system. AlgZ, the sensor histidine kinase, has been shown to be co-transcribed with its’ response regulator, AlgR, to affect a myriad of virulence factors, including those related to motility. Pseudomonas species is capable of four types of motility: twitching, swimming, swarming, and gliding. Twitching motility is achieved through the expression of the FimU operon and Type VI pilli, and is most useful when attaching to a solid surface in the initial step of pathogenesis: colonization. Conversely, the swimming phenotype relies on the production of a single polar flagellum upon the activation of the FleQ operon, and allows the organism to move through a fluid environment. A previously unidentified regulator of AlgZ, but not AlgR, has been identified via transposon mutagenesis screening, PA2771, which has a GGDEF domain and predicted diguanylate cyclase activity. The mechanism of PA2771’s action within P. aeruginosa has not been previously studied. The nonpolar deletion mutant was first characterized via various phenotypic assays (including biofilm, rhamnolipid, swimming, and swarming assays) and transcriptional fusions to propose a mechanism in which this predicted diguanylate cyclase (DGC) works with AlgZ to determine the switch in motility from twitching to swimming. When PA2771 is present and active in the cell, cyclic di-GMP levels should be high, leading to the production of Type VI pilli and the upregulation of the FimU operon. In the PA2771 mutant a significant decrease in the expression of the FimU operon, and an increase in the expression of the flagellar genes. Subsequent alterations in swimming and swarming phenotypes were observed, as well as the restoration of these effects via complementation studies. Overexpression of AlgZ in the 2771 mutant showed a restoration of AlgZ expression in the nonmucoid background, and the predicted DGC activity was indirectly verified via a cdrA-lacZ transcriptional fusion.

Pseudomonas

diguanylate cyclase

two-component systems

regulation

AlgZ

Bacterial Infections and Mycoses

Biology

Molecular Genetics

Efekt sulfidu sodného na vlastnosti modelových hemových senzorových proteinů s globinovou strukturou senzorové domény / Effect of sodium sulfide on the propreties of model globine-coupled heme-containing sensor proteins

Bartošová, Martina

January 2014

Hydrogen sulfide mediates various physiological functions and along with carbon monoxide and nitric oxide it is an important gaseous signaling molecule. Cellular targets for H2S are proteins, enzymes, transcriptional factors or ion channels. In many cases, the effect of H2S on the regulatory protein is mediated by modifications of its cystein residues. In hemeproteins, the regulation of catalytic activity is induced by formation of the Fe(III)-SH complex or by reduction of the heme iron with subsequent formation of Fe(II)-O2 complex. The effect of Na2S on model sensor heme-containing proteins is presented in this thesis. Protein, isolated from bacterium Anaeromyxobacter sp. strain FW109-5, containing a globine coupled sensor domain and a histidine kinase domain is one of the studied proteins, the second one is protein isolated from bacterium Escherichie coli, containing a globine coupled sensor domain and a diguanylate cyclase domain. The effect of Na2S on both model proteins and their mutants was studied by UV-Vis spectral analysis. Spectra of YddV-HD Y43A were very unique, because thery confirmed formation of a homogenous complex Fe(III)-SH in this protein, whereas only mixtures of varous heme complexes were detected in other tested proteins. Additionally the effect of Na2S on functional domain...

Analysis of CdgC as the major diguanylate cyclase in S. venezuelae

Neumann, Sara Alina

23 August 2021

Die Entwicklung des grampositiven Bodenbakteriums Streptomyces ist in einem komplexen Lebenszyklus koordiniert, bestehend aus drei Stufen: vegetativem Hyphenwachstum, Luftmycelbildung und Sporulation. C-di-GMP kontrolliert die Enwicklung über zwei Effektorproteine: dem Masterregulator BldD und dem Anti-Sigmafaktor RsiG. In dieser Arbeit konnte gezeigt werden, dass das membranständige GGDEF-EAL Protein CdgC eine wichtige aktive Diguanylatzyklase (DGC) in S. venezuelae ist. Chromosomale Deletion von cdgC führte zu einer flachen, gräulichen Koloniemorphologie mit radialen Stegen und hydrophiler Oberfläche sowie zu frühzeitiger Sporulation ohne Lufthyphenbildung. Phänotypische Analysen zeigten, dass die DGC-Aktivität von CdgC essentiell ist für dessen biologische Rolle und deuten auf einen zusätzlichen Protein-spezifischen morphologischen Effekt von CdgC hin. CdgC-FLAG akkumuliert im Laufe des Lebenszyklus und scheint BldD-abhängig über eine c-di-GMP vermittelte Feedbackschleife reguliert zu werden. Frühere RNA-seq Daten, verifiziert für repräsentative Gene mittels qRT-PCR, deuten eine differentielle Expression der Bestandteile des hydrophoben Mantels als Ursache der Lufthyphendefizienz an. Konfokalmikroskopische Aufnahmen des bakteriellen Tubulin-Homologons FtsZ deuten einen c-di-GMP-sensitiven Einfluss von CdgC auf die Koordination der Zellteilung an. Zudem konnte nachgewiesen werden, dass CdgC mit sich selbst sowie drei potentiellen Membranproteinen interagiert. Demnach trägt CdgC zur Koordination von Zellteilungs- und hydrophoben Zelloberflächenproteinen bei und beeinflusst damit c-di-GMP-abhängig den Zeitpunkt der Sporenbildung. Insgesamt führt diese Studie CdgC als GGDEF-EAL-Tandemprotein mit spezifischem Knockout- Phänotyp ein, der von seiner DGC-Aktivität sowie seinem Membrananker bestimmt wird. Zudem ist CdgC, als Reaktion auf eine noch unbekannte Signalübertragungskaskade, an der Koordinierung von Zeitpunkt und Verlauf der Sporulation ausschlaggebend beteiligt. / The proliferation of Gram-positive soil bacteria Streptomyces is temporally and genetically coordinated with a complex developmental life cycle, including three main stages of differentiation: vegetative hyphal growth, formation of aerial mycelium and sporulation. The key factor of Streptomyces developmental control is c-di-GMP with to-date two identified effector proteins: the master regulator BldD and the anti-sigma factor RsiG. In this thesis, the membrane-associated GGDEF-EAL protein CdgC, was identified as a major active diguanylate cyclase (DGC) in S. venezuelae. Deletion of cdgC results in the unique flat gray colony morphology with radial wrinkles and a hydrophilic surface, that shows enhanced sporulation without forming aerial hyphae. Phenotypic analyses suggest, that the DGC activity is essential for its biological role, but hint to an additional protein specific role. The protein levels of CdgC-FLAG were found to accumulate during the life cycle of S. venezuelae. Further investigation of CdgC-FLAG in a strain carrying a DNA-binding deficient BldD_D116A allele indicated, that BldD represses the expression of CdgC in a regulatory feedback loop along with the DGCs CdgA, CdgB and CdgE. RNA‐sequencing data indicated that reduced expression levels of the major compounds of the hydrophobic sheath result in the initiation of sporulation out of the vegetative mycelium and were verified for representative examples via qRT-PCR. Confocal microscopic imaging of the bacterial tubulin homolog FtsZ indicated a contribution of CdgC via its DGC activity in coordination of the cell division. In addition, BTH screenings revealed self-interaction and identified three membrane associated interaction partners. In conclusion, this study introduces the GGDEF-EAL tandem protein CdgC, whose specific knockout phenotype is governed by its DGC activity and membrane association. CdgC seems to drive timing and mode of sporulation in response to an unknown signal to a major extend.

c-di-GMP

Streptomyces

GGDEF

Diguanylatzyklase

Entwicklungsregulation

Proliferation

c-di-GMP

diguanylate cyclase

Streptomyces

GGDEF

proliferation

developmental regulation

570 Biologie

WF 6850

WF 5200

WF 2105

ddc:570

Mechanismus přenosu signálu hemovými senzorovými proteiny detekujícími kyslík / Molecular mechanisms of signal transduction in model heme-containing oxygen sensor proteins

Stráňava, Martin

January 2016

EN Heme containing gas sensor proteins play important role in bacterial physiology in regulating many processes such as cell differentiation, virulence, biofilm formation or intercellular communication. For their structure, typical modular architecture is characteristic where various sensor domains (usually at the N-terminus) regulate the activity of the catalytic or functional domains (usually at the C-terminus). In this dissertation thesis, we focused on three representatives from the group of oxygen sensing proteins, namely histidine kinase AfGcHK, diguanylate cyclase YddV, phosphodiesterase EcDOS and also on protein RR, which is the interaction partner of AfGcHK. The main aim of the thesis was to study intra-protein/inter-domain signal transduction in two representatives of heme sensor proteins with a globin fold of the sensor domain (AfGcHK, YddV) and in one representative with PAS fold of the sensor domain (EcDOS). Another objective was to describe inter-protein signal transduction in the two component signaling system AfGcHK-RR and structurally characterize these two interacting partners. Emphasis was also placed on the study of the interaction between model sensor domains and different signaling molecules and also on function of individual amino acids involved in the binding of these...