Characterizing Stress-Induced Outer Membrane Vesicle Production in Pseudomonas aeruginosa

MacDonald, Ian Alexander

January 2013

<p>As an opportunistic Gram-negative pathogen, Pseudomonas aeruginosa must be able to adapt to changes and survive stressors in its environment during the course of infection. To aid survival in the hostile host environment, P. aeruginosa has evolved a myriad of virulence factors including the production of an exopolysaccharide capsule, as well as secretion of degradative proteases and lipases that also function as defense mechanisms. Outer membrane vesicles (OMVs) acts as a secretion system to disseminate virulence factors and function as a general bacterial stress response to remove accumulated periplasmic waste. Despite the growing insights of the field into the potential functions of OMVs, the mechanism for formation remains to be fully elucidated. The three proposed mechanisms for OMV formation in P. aeruginosa are mediated by the Pseudomonas quinolone signal PQS, the AlgU envelope stress response pathway, and the periplasmic chaperone MucD. This report investigates how P. aeruginosa responds to sublethal physiological stressors with regards to OMV production levels and whether the proposed mechanisms for OMV formation are required for stress-induced OMV formation. We concluded that exposure to cell wall directed stressors increased OMV production and activity of the sigma factor that controls MucD expression, AlgU. AlgU was shown to be sufficient to induced OMV production upon overexpression; however, stress-induced OMV production was not dependent on activation of AlgU as vesiculation could be induced in strains lacking AlgU. Furthermore, MucD levels were not inversely proportional to OMV production under acute stress, and the ability to produce PQS was not required for OMV production. Finally, an investigation of the response of P. aeruginosa to oxidative stress revealed that hydrogen peroxide-induced OMV production requires the presence of B-band but not A-band lipopolysaccharide. We also demonstrated that the ability for P. aeruginosa to sense oxidative stress via OxyR, was important for hydrogen peroxide-induced OMV production, by a yet to be determined method. Together these results demonstrate that current proposed mechanisms for OMV formation do not universally apply under all stress conditions, and that additional mechanisms for OMV formation are still to be identified and fully elucidated during acute stress in P. aeruginosa.</p> / Dissertation

Microbiology

Biochemistry

OMV

OxyR

Pseudomonas aeruginosa

stress

Response of intestinal Escherichia coli to dietary factors in the mouse intestine

Rothe, Monique

January 2013

Diet is a major force influencing the intestinal microbiota. This is obvious from drastic changes in microbiota composition after a dietary alteration. Due to the complexity of the commensal microbiota and the high inter-individual variability, little is known about the bacterial response at the cellular level. The objective of this work was to identify mechanisms that enable gut bacteria to adapt to dietary factors. For this purpose, germ-free mice monoassociated with the commensal Escherichia coli K-12 strain MG1655 were fed three different diets over three weeks: a diet rich in starch, a diet rich in non-digestible lactose and a diet rich in casein. Two dimensional gel electrophoresis and electrospray tandem mass spectrometry were applied to identify differentially expressed proteins of E. coli recovered from small intestine and caecum of mice fed the lactose or casein diets in comparison with those of mice fed the starch diet. Selected differentially expressed bacterial proteins were characterised in vitro for their possible roles in bacterial adaptation to the various diets. Proteins belonging to the oxidative stress regulon oxyR such as alkyl hydroperoxide reductase subunit F (AhpF), DNA protection during starvation protein (Dps) and ferric uptake regulatory protein (Fur), which are required for E. coli’s oxidative stress response, were upregulated in E. coli of mice fed the lactose-rich diet. Reporter gene analysis revealed that not only oxidative stress but also carbohydrate-induced osmotic stress led to the OxyR-dependent expression of ahpCF and dps. Moreover, the growth of E. coli mutants lacking the ahpCF or oxyR genes was impaired in the presence of non-digestible sucrose. This indicates that some OxyR-dependent proteins are crucial for the adaptation of E. coli to osmotic stress conditions. In addition, the function of two so far poorly characterised E. coli proteins was analysed: 2 deoxy-D gluconate 3 dehydrogenase (KduD) was upregulated in intestinal E. coli of mice fed the lactose-rich diet and this enzyme and 5 keto 4 deoxyuronate isomerase (KduI) were downregulated on the casein-rich diet. Reporter gene analysis identified galacturonate and glucuronate as inducers of the kduD and kduI gene expression. Moreover, KduI was shown to facilitate the breakdown of these hexuronates, which are normally degraded by uronate isomerase (UxaC), altronate oxidoreductase (UxaB), altronate dehydratase (UxaA), mannonate oxidoreductase (UxuB) and mannonate dehydratase (UxuA), whose expression was repressed by osmotic stress. The growth of kduID-deficient E. coli on galacturonate or glucuronate was impaired in the presence of osmotic stress, suggesting KduI and KduD to compensate for the function of the regular hexuronate degrading enzymes under such conditions. This indicates a novel function of KduI and KduD in E. coli’s hexuronate metabolism. Promotion of the intracellular formation of hexuronates by lactose connects these in vitro observations with the induction of KduD on the lactose-rich diet. Taken together, this study demonstrates the crucial influence of osmotic stress on the gene expression of E. coli enzymes involved in stress response and metabolic processes. Therefore, the adaptation to diet-induced osmotic stress is a possible key factor for bacterial colonisation of the intestinal environment. / Sowohl Humanstudien als auch Untersuchungen an Tiermodellen haben gezeigt, dass die Ernährung einen entscheidenden Einfluss auf die Zusammensetzung der Darmmikrobiota hat. Aufgrund der Komplexität der Mikrobiota und der inter individuellen Unterschiede sind die zellulären Mechanismen, die dieser Beobachtung zugrunde liegen, jedoch weitgehend unbekannt. Das Ziel dieser Arbeit war deshalb, Anpassungsmechanismen von kommensalen Darmbakterien auf unterschiedliche Ernährungsfaktoren mittels eines simplifizierten Modells zu untersuchen. Dazu wurden keimfreie Mäuse mit Escherichia coli MG1655 besiedelt und drei Wochen mit einer stärkehaltigen, einer laktosehaltigen oder einer kaseinhaltigen Diät gefüttert. Mittels zwei dimensionaler Gelelektrophorese und Elektrospray Ionenfallen-Massenspektrometrie wurde das Proteom der intestinalen E. coli analysiert und differentiell exprimierte bakterielle Proteine in Abhängigkeit der gefütterten Diät identifiziert. Die Funktion einiger ausgewählter Proteine bei der Anpassung von E. coli auf die jeweilige Diät wurde im Folgenden in vitro untersucht. E. coli Proteine wie z.B. die Alkylhydroperoxid Reduktase Untereinheit F (AhpF), das DNA Bindeprotein Dps und der eisenabhängige Regulator Fur, deren Expression unter der Kontrolle des Transkriptionsregulators OxyR steht, wurden stärker exprimiert, wenn die Mäuse mit der laktosehaltigen Diät gefüttert wurden. Reportergenanalysen zeigten, dass nicht nur oxidativer Stress, sondern auch durch Kohlenhydrate ausgelöster osmotischer Stress zu einer OxyR abhängigen Expression der Gene ahpCF and dps führte. Weiterhin wiesen E. coli Mutanten mit einer Deletion der ahpCF oder oxyR Gene ein vermindertes Wachstum in Gegenwart von nicht fermentierbarer Saccharose auf. Das spricht dafür, dass OxyR abhängige Proteine eine wichtige Rolle bei der Anpassung von E. coli an osmotischen Stress spielen. Weiterhin wurde die Funktion von zwei bisher wenig charakterisierten E. coli Proteinen untersucht: die 2 Deoxy D Glukonate 3 Dehydrogenase (KduD) wurde im Darm von Mäusen, die mit der laktosehaltigen Diät gefüttert wurden, induziert, während dieses Protein und die 5 Keto 4 Deoxyuronate Isomerase (KduI) nach Fütterung der kaseinhaltigen Diät herunterreguliert wurden. Mittels Reportergenanalysen wurde gezeigt, dass Galakturonat und Glukuronat die kduD und kduI Expression induzierten. KduI begünstigte die Umsetzung dieser Hexuronate. In E. coli wird die Umsetzung von Galakturonat und Glukuronat typischerweise von den Enzymen Uronate Isomerase (UxaC), Altronate Oxidoreduktase (UxaB), Altronate Dehydratase (UxaA), Mannonate Oxidoreduktase (UxuB) und Mannonate Dehydratase (UxuA) katalysiert. Weitere Experimente verdeutlichten, dass osmotischer Stress die Expression der Gene uxaCA, uxaB und uxuAB verminderte. Darüber hinaus zeigten kduID defiziente E. coli Mutanten in Gegenwart von Galakturonat oder Glukuronat und durch Saccharose ausgelösten osmotischen Stress eine Verlangsamung des Wachstums. Das deutet darauf hin, dass KduI und KduD die durch osmotischen Stress bedingten Funktionseinschränkungen der regulären hexuronatabbauenden Enzyme kompensieren. Die beobachtete Bildung von intrazellulären Hexuronaten während des Laktosekatabolismus in vitro stellt eine Verbindung zu dem ursprünglichen Tierexperiment her und deutet darauf hin, dass der Ernährungsfaktor Laktose die Verfügbarkeit von Hexuronat für intestinale E. coli beeinflusst. Diese Studie weist somit den Einfluss von osmotischem Stress auf die Expression von OxyR abhängigen Genen, die für Stressantwortproteine sowie für metabolische Enzymen kodieren, in E. coli nach. Durch Nahrungsfaktoren entstandener osmotischer Stress stellt demnach einen entscheidenden Faktor für die bakterielle Kolonisation des Darmes dar.

Mikrobiota

Escherichia coli

Proteom

Ernährungsfaktoren

OxyR

microbiota

Escherichia coli

proteome

dietary factors

OxyR

Life sciences

The oxidative stress response of Francisella tularensis / The oxidative stress response of Francisella tularensis

Honn, Marie

January 2016

Francisella tularensis is capable of infecting numerous cell types, including professional phagocytes. Upon phagocytosis, F. tularensis resides within the phagosome before escaping into the cytosol to replicate. Phagocytes constitute a hostile environment rich in ROS, which are employed as a means of killing pathogens. ROS interact with and disrupt the function of vital molecules such as DNA, proteins and bacterial structures. Iron potentiates the danger of ROS through the Fenton reaction where ferrous iron reduces H2O2 causing the formation of highly reactive hydroxyl radicals and anions. Low levels of ROS are formed during normal aerobic metabolism and pathogens thus have a need for defense mechanisms to handle the ever present levels of ROS but even more so to combat the onslaught of ROS experienced within a host. This thesis was focused on the investigation of the iron status and oxidative stress response of F. tularensis; thereby identifying key players controlling the bacterial iron content, its adaptation to oxygen-rich environments and defense against ROS. We identified subspecies-specific differences in iron content, where F. tularensis subsp. tularensis was found to contain significantly less iron than strains of subsp. holarctica. The reduced iron content resulted in an increased tolerance to H2O2, despite simultaneously causing a decrease in the activity of catalase - the iron-dependent enzyme responsible for degrading H2O2 in F. tularensis. This strongly suggests that the restricted iron uptake and storage by subsp. tularensis strains is beneficial by rendering the bacteria less susceptible to H2O2, thereby evading the toxic effects of the iron-driven Fenton reaction. This evasion is likely to be an important part of the higher virulence displayed by subsp. tularensis as compared to subsp. holarctica. We further identified that the global regulator, MglA, is important for the adaptation of LVS to oxygen-rich environments. Deletion of mglA from LVS resulted in a mutant, ΔmglA, with impaired defense to oxidative stress, as manifested by an inability to grow to wild-type levels under aerobic conditions, an accumulation of proteins with oxidative damage, a suppressed expression of iron-uptake related genes, an increased catalase activity, and an increased tolerance to H2O2. This phenotype was reversed in a microaerobic environment. We therefore conclude that MglA is an important factor for the defense of LVS to oxidative damage under aerobic conditions and speculate that MglA is of greatest importance in oxygen-rich foci. We also studied the role of OxyR in LVS by creating a ΔoxyR mutant as well as a double mutant, ΔoxyR/ΔkatG. The in vitro response of these mutants, as well as of ΔkatG, to defined ROS was assessed using H2O2, the O2- generating agent paraquat, and the ONOO- generator SIN-1. ΔoxyR was more susceptible to all ROS than LVS as was ΔkatG, with the exception of O2- Strikingly, ΔoxyR/ΔkatG was significantly more susceptible to all ROS tested compared to either single deletion mutant. LVS, ΔoxyR and ΔkatG replicated efficiently in bone marrow-derived macrophages whereas ΔoxyR/ΔkatG showed no replication. In mice, the ΔoxyR mutant displayed impaired replication in liver, but intact replication vs. LVS in spleen. Collectively, our results demonstrate an important role of OxyR in the oxidative stress response and virulence of F. tularensis, and further reveal overlapping roles of OxyR and catalase in the defense against ROS. The results thus shed new light on the complexity of ROS defense in F. tularensis.

Francisella tularensis

FupA

MglA

OxyR

ROS

oxidative stress

Investigating the transcriptional regulation by OxyR in Porphyromonas gingivalis.

Paranjape, Anuya R.

06 August 2012

Periodontal diseases are bacterially induced, inflammatory diseases which are responsible for loss of alveolar bone and connective tissue supporting the teeth which results in loss of teeth. Gram negative anaerobic bacteria are highly associated with these diseases. One of them is Porphyromonas gingivalis belonging to the phylum Bacteroidetes. Infection by P. gingivalis is recurrent after physical removal of the bacteria from the oral cavity and even after antibiotic treatment as development of resistance is not rare. Hence complete understanding the biology of this bacterium is of significance. This gram negative obligate anaerobe, being aerotolerant, manages to survive inside the oral cavity, where oxidative stress is ubiquitous. Genome sequence of P. gingivalis shows the presence of a transcriptional regulator OxyR which is a homologue of OxyR present in E. coli. P. gingivalis OxyR induces the expression of antioxidant defense genes like sod, ahpC-F, dps to protect the bacteria from oxidative stress. Expression of P. gingivalis OxyR regulon is not very well understood. Microarray studies carried out in our lab using P. gingivalis W83 to study gene regulation by OxyR, indicated that several genes in P. gingivalis are co-regulated by iron-and OxyR. Literature also supports that in iron deplete conditions genes involved in oxidative stress are down-regulated. These studies formed the basis of our hypothesis that OxyR might regulate the genes in P. gingivalis in an iron dependent manner. To study the mechanism of regulation by P. gingivalis OxyR and to determine whether OxyR regulation is iron dependent, two approaches were applied - in vitro characterization of binding and in vivo characterization. First step of in vitro characterization was to perform CHIP-chip assay to determine OxyR-binding sites present on the genomic DNA of P. gingivalis. As this assay was performed under completely anaerobic conditions, the target fragments to which OxyR was found to bind during this assay were not same as reported in literature. These and the fragments reported in literature were used for EMSA. EMSAs carried out using crude cell lysates and in vitro OxyR protein preparations showed expected results but the results were not reproducible. In vivo expressed and purified P. gingivalis OxyR never bound to the target fragments used. Preparation of a stable protein preparation and improvement in the parameters of EMSA is very important to further investigate the binding in vitro. The second approach is based on in vivo characterization of binding. This requires tagging the P. gingivalis OxyR at its C-terminus with fluorescent protein to observe its binding to the target DNA sequences. Fluorescently tagged OxyR, is expected to emit fluorescence from a highly localized area to produce sharp fluorescent spots when it is bound to its target sequences. Unbound OxyR is expected to emit a fluorescent signal which is spread over the entire area of the cell. This technique will help to determine the conditions under which OxyR binds to its target DNA sequences. This provides a means to confirm the results obtained from in vitro characterization instead of just extrapolating them.

OxyR

Porphyromonas gingivalis

oxidative stress

periodontitis

Medicine and Health Sciences

The Study of the Regulon of OxyR in Escherichia coli and Porphyromonas gingivalis

Pham, Christopher K

01 January 2016

The facultative anaerobe, Escherichia coli and the obligate anaerobe, Porphyromonas gingivalis are two bacteria that reside in our body. Although they reside in separate environments, they are both subject to hydrogen peroxide stress and have mechanisms to regulate the stress. OxyR is the primary transcriptional regulator/sensor of oxidative stress response caused by hydrogen peroxide. OxyR in P. gingivalis is not well-characterized compared to OxyR in E. coli. We sought to characterize and compare the two forms of OxyR in order to gain a better understanding of the protein. We determined the oligomeric state of both proteins: primarily a tetramer for E. coli and primarily a tetramer for P. gingivalis OxyR.. We demonstrated DNA binding with E. coli OxyR, indicating purification of the functional form of E. coli OxyR.Through pulldown assays we discovered potential novel binding targets, mobB for E. coli OxyR and PG1209 for P. gingivalis OxyR. Many of the other targets corresponded to intergenic regions within genes, which may pertain to small RNAs or small proteins. These results show that OxyR in E. coli and P. gingivalis has novel function and properties indicating an expanded role in addition to the well-characterized oxidative stress response.

Escherichia coli

Porphyromonas gingivalis

OxyR

regulon

Biochemistry

Oral Biology and Oral Pathology

Stress Response In Salmonella And Its Role In Pathogenesis

Lahiri, Amit

07 1900

Chapter: 1 Introduction Genus Salmonella is a Gram-negative rod shaped facultative anaerobic bacteria that can survive inside the host macrophages and cause persistent infection. Salmonella Typhimurium, Salmonella Typhi and Salmonella Enteritidis are the serovars, which belong to the Salmonella enterica species. S. Typhi causes typhoid fever in humans. S. Typhimurium is one of the important causes for food poisoning in humans. It causes typhoid like fever in mice and serves as a good model system to study Salmonella pathogenesis. Salmonella infection occurs via the orofecal route following which it invades the intestinal mucosa through several ways, namely by antigen sampling M cells, CD18+ macrophages present in the intestinal lumen or via a forced entry in the non phagocytic enterocytes. Upon entry Salmonella resides in an intracellular phagosomal compartment called the Salmonella containing vacuole (SCV). The SCV only transiently acquires endocytic markers like TfnR, EEA1, Rab4, Rab5, Rab11 and Rab7. It eventually uncouples from the endocytic pathway to avoid lysosomal fusion and ultimately reaches the golgi apparatus achieving a perinuclear position. The mechanisms by which phagocytes kill the virulent Salmonella are not completely understood, however the role of nicotinamide-adenine dinucleotide phosphate (NADPH) phagocytic oxidase system has been strongly implicated. The generation of reactive oxygen species (ROS) occurs via a membrane-bound flavocytochrome b558, consisting of two phagocytic oxidase components (gp91phox and p22phox) and four cytosolic components, p40phox, p47phox, p67phox, and a GTP-binding Rac protein. Further, professional phagocytes like macrophages generate nitric oxide (NO) that acts as a potent agent to limit the growth of many intracellular pathogens including Salmonella. Chapter:2 Resistance to host Nitrosative stress in Salmonella by quenching L-arginine. Arginine is a common substrate for both inducible nitric oxide synthase (iNOS) and arginase. The competition between iNOS and arginase for arginine contributes to the outcome of several parasitic and bacterial infections. Salmonella infection in macrophage cell line RAW264.7 induces iNOS. Because the availability of L-arginine is a major determinant for nitric oxide (NO) synthesis, we hypothesize that in the Salmonella infected macrophages NO production may be regulated by arginase. Here we report for the first time that Salmonella up-regulates arginase II but not arginase I isoform in RAW264.7 macrophages. Blocking arginase increases the substrate L-arginine availability to iNOS for production of more nitric oxide and perhaps peroxynitrite molecules in the infected cells allowing better killing of virulent Salmonella in a NO dependent manner. RAW264.7 macrophages treated with iNOS inhibitor aminoguanidine reverts the attenuation in arginase blocked condition. Further, the NO block created by Salmonella was removed by increasing concentration of L-arginine. In the whole-mice system arginase I, although constitutive, is much more abundant than the inducible arginase II isoform. Inhibition of arginase activity in mice during the course of Salmonella infection reduces the bacterial burden and delays the disease outcome in a NO dependent manner. Chapter:3 Hrg (hydrogen peroxide resistant gene), a LysR type transcriptional regulator confers resistance to oxidative stress in Salmonella LysR type transcriptional regulators are one of the key players that help bacteria adapt to different environments. We have christened STM0952, a putative LysR type transcriptional regulator in Salmonella enterica serovar Typhimurium as the hydrogen peroxide resistance gene (hrg). By generating a knock out of the hrg gene, we demonstrate that the hrg mutant serovar Typhimurium is sensitive to oxidative products of the respiratory burst, specifically to hydrogen peroxide. The hrg mutant is profoundly attenuated in the murine model of infection and shows decreased intracellular proliferation in macrophages. It was also found to induce increased amount of reactive oxygen species and co-localization with gp91phox in the macrophage cell line, when compared to the wild type. An overproducing strain of this gene showed a survival advantage over the wild type Salmonella under hydrogen peroxide induced stress condition. Microarray analysis suggested the presence of a Hrg regulon, which is required for resistance to the toxic oxidative products of the reticulo-endothelial system. Chapter:4 Importance of the host oxidative stress in antigen presentation and its modulation by Salmonella: Role of TLR Synthetic CpG containing oligodeoxynucleotide TLR-9 agonist (CpG ODN) activates innate immunity and can stimulate antigen presentation against numerous intracellular pathogens. We report that Salmonella Typhimurium growth can be inhibited by the CpG ODN treatment in the murine dendritic cells. This inhibitory effect was shown to be mediated by an increased reactive oxygen species (ROS) production. We further show that the CpG ODN treatment of the dendritic cells during Salmonella infection leads to a ROS dependent increased antigen presentation. In addition, TLR-9 signaling inhibitor was able to inhibit the CpG ODN mediated increased antigen presentation, ROS production and pathogen killing. These data indicate that CpG ODN can improve the ability of the murine dendritic cells to contain the growth of the virulent Salmonella through ROS dependent killing and could as well be used as an effective adjuvant in vaccines against Salmonella infection.

Salmonella Pathogenesis

Salmonellosis

Salmonella Bacteria

Salmonella - Stress Response

Salmonella Virulence

Salmonella Typhimurium

LysR

Hrg

OxyR

L-arginine

Microbiology