Global ETD Search

11	Investigation of the Molecular Mechanisms of the Shigella Type III Secretion System Tip Complex Bernard, Abram R. 01 December 2018 (has links) Shigella are bacteria that are responsible for millions of infections and hundreds of thousands of deaths every year. The emergence of antibiotic resistant Shigella adds to the potentially devastating effect that these bacteria can have on human health. Shigella flexneri utilize specialized molecular machinery called the Type III secretion system to infect humans and cause disease. Research of this machinery promises to provide the knowledge, tools, and direction for the development of new avenues to combat shigellosis. This dissertation presents studies of two Shigella proteins, invasion plasmid antigens C and D (IpaC and IpaD). These proteins are part of a syringe and needle like protein structure that allows Shigella to secrete proteins directly into the host that hijack host cells to benefit support Shigella infections. IpaC and IpaD are part of a protein tip complex that is directly involved in these Shigella-host (e.g. human) interactions. We have advanced the biochemical tools for the in vitro study of IpaC by utilizing a new way to isolate it. This purification methodology allowed us to look at one of IpaC’s main roles, to interact with the host cell membranes. We examined IpaC’s role and tried to identify the parts of IpaC responsible for some specific interactions. We found that the parts of IpaC we believed were responsible were not but that the composition of the membrane IpaC is interacting with is more important than we previously believed. Finally, we examined a rare part of IpaD structure to determine its role. We determined that this rare feature is required for IpaD to sense Shigella’s host environment and prepare the bacteria to infect, making a promising target for anti-infective treatments against Shigella infections. Our findings advance the understanding of key molecular mechanisms that are required for Shigella virulence. We expect that our findings will aid future researchers as the pursuit for new treatments for shigellosis continues. IpaC IpaD deoxycholate pi-helix type three secretion system Biochemistry
12	Molecular mechanisms of cytotoxicity regulation in pseudomonas aeruginosa by the magnedium transporter MGTE Chakravarty, Shubham 07 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The Gram-negative bacterium Pseudomonas aeruginosa causes numerous acute and chronic opportunistic infections in humans. One of its most formidable weapons is a type III secretion system (T3SS), a multi-protein molecular syringe that injects powerful toxins directly into host cells. The toxins lead to cell dysfunction and, ultimately, cell death. Identification of regulatory pathways that control T3SS gene expression may lead to the discovery of novel therapeutics to treat P. aeruginosa infections. In a previous study, it was found that expression of the magnesium transporter gene mgtE inhibits T3SS gene transcription. MgtE-dependent inhibition appeared to interfere with the synthesis or function of the master T3SS transcriptional activator ExsA, although the exact mechanism was unclear. In this work, we demonstrate that mgtE expression acts through the GacAS two-component system to activate transcription of the small regulatory RNAs RsmY and RsmZ. This event ultimately leads to inhibition of exsA translation. Moreover, our data reveal that MgtE acts solely through this pathway to regulate T3SS gene transcription. Our study reveals an important mechanism that may allow P. aeruginosa to fine-tune T3SS activity in response to certain environmental stimuli. In addition, a previous study has shown that the P. aeruginosa gene algR abrogates mgtE mediated regulation of cytotoxicity. AlgR has pleiotropic effects in P. aeruginosa, including regulation of synthesis of the exopolysaccharide alginate. In the second part of my thesis, I show that algR and mgtE genetically crosstalk to inhibit ExsA driven T3SS gene transcription. This genetic interaction between algR and mgtE seems to be specifically directed towards regulation of T3SS gene expression rather than having an indiscriminate effect on multiple virulence attributes in P. aeruginosa. Additionally, we have further demonstrated that AlgR inhibits mgtE transcription. These studies suggest the presence of a T3SS inhibitor that is inhibited by both AlgR and MgtE. Future work will involve transcriptomic and proteomic analysis to identify such an inhibitor. Taken together, this study provides important insight into the molecular mechanisms of mgtE expression and function in P. aeruginosa. We have established that mgtE has pleiotropic effects on cytotoxicity in P. aeruginosa. Thus, given the role that cytotoxicity regulation plays in shaping P. aeruginosa pathogenesis and associated clinical outcomes, mgtE might be an interesting drug target, though extensive future studies are required to validate this proposition. Nevertheless, this research, provides clues for identification of novel therapeutic targets in P. aeruginosa. Hence this work, in the long run, serve to ameliorate the morbidity and mortality in patients infected with P. aeruginosa. Pseudomonas aeruginosa type III secretion system MgtE Cystic Fibrosis cytotoxicity
13	Studying the effects of bile salts on an unknown virulence gene of Shigella flexneri Poore, Kender 20 January 2023 (has links) The Shigella species is responsible for many diarrheal infections and deaths across the world each year, with the largest impact on less industrialized countries, especially in children under 5 years of age. The battle between the lack of a targeted treatment or vaccine and the significant rise of antibiotic resistance in Shigella underscores the importance of fully understanding mechanisms of Shigella virulence. Past research clearly demonstrates that Shigella flexneri strain 2457T utilizes host physiology to regulate pathogenesis, including increasing virulence during exposure to bile salts at concentrations found in the small intestine. This study aimed to further characterize the effects of bile salts exposure in Shigella by focusing on a particular gene induced in the presence of bile salts. Growth curve analyses were performed with S. flexneri wild-type and mutant strains to examine the role of the unknown protein in the growth of Shigella during bile salts exposure. To examine the effects of the mutation on virulence, a Congo red secretion assay was also used as a measure of type-III secretion system function as well as invasion assays, both of which used bile salts in the subculture conditions to mimic small intestinal transit of wild-type and the mutant strain prior to infection in the colon. The mutant displayed no change in growth patterns in comparison to WT in the presence or absence of bile salts. However, the mutant displayed increased protein secretion and invasion rates relative to wild-type. Overall, the data suggest that this bile salts-induced gene encodes a protein that negatively regulates S. flexneri virulence, likely providing protection against a hypervirulent phenotype of Shigella. This work has succeeded in further characterizing an unknown protein that is induced by bile salts, and could provide insight for future therapeutic and vaccine development. / 2025-01-19T00:00:00Z Microbiology Diarrhea Enteric Enterobactericiae Shigella Shigellosis Type-III secretion system
14	Characterization of interactions of the Type IV secretion system core component VirB8 Sivanesan, Durga 09 1900 (has links) <p> Type IV secretion systems (T4SS) are essential for the virulence of many gram-negative pathogens. The systems studied here comprise eleven VirB proteins in case of Agrobacterium tumefaciens and twelve in case of Brucella suis. The VirB proteins associate in the cell envelope and form a complex that mediates the translocation of virulence factors into host cells. In this report, VirB8, a core component of T4SS, is characterized with regards to its interaction with itself and with other VirB proteins. </p> <p> VirB8 was found to exist in monomer-dimer equilibrium and the self-association was demonstrated by analytical ultracentrifugation, analytical gel filtration, surface plasmon resonance and bacterial two-hybrid assay. The above experiments demonstrated that residues M102, Y105 and E214 o fVirB8 from B. suis are involved in self-association and mutagenesis of these residues led to the impairment of T4SS function in B. suis. Furthermore, this information was utilized to unravel the contribution of VirB8 self-association towards T4SS assembly and function. To this end dimerization variants of VirB8 from Agrobacterium tumefaciens were created and the effects were assessed with purified proteins in vitro. Following this, the effects of VirB8 dimer site changes were assessed in vivo. Introduction of a cysteine residue at the predicted interface (V97C) supported DNA transfer but not T-pilus formation. Variants that reduced the self-association did not support T4SS functions and T-pilus formation. Moreover, VirB2- VirB5 co-fractionated with high molecular mass components from membranes of A. tumefaciens and VirB8 dimerization was shown to be necessary for VirB2 association with the high molecular mass components. Using purified VirB8 and VirB5 it was shown that VirB5 interacts with VirB8 via its globular domain and this interaction dissociates VirB8 dimers. Taking these results together, a mechanistic contribution of VirB8 dimerization to T4SS assembly was proposed. </p> <p> Next, the interactions of VirB8 with other core components (VirB9 and VirBlO) were analyzed by using various in vitro and in vivo experiments. Purified soluble periplasmic domains of VirB8, VirB9 and VirB10 were used in enzyme-linked immunosorbent assays, circular dichroism, and surface plasmon resonance experiments. The pair-wise interactions and self-association of VirB8, VirB9 and VirB 10 were demonstrated with the in vitro experiments. In addition, a ternary complex formation between VirB8, VirB9, and VirBlO was identified. Using the bacterial two-hybrid system, the dynamics of the interactions between VirB8-VirB9-VirB 10 full-length proteins were analyzed demonstrating that VirB9 stimulates VirB8 self-association, but that it inhibits the VirB10-VirB10 as well as the VirB8-VirB10 interaction. Based on these results, a dynamic model for secretion system assembly is proposed where VirB8 plays a role as an assembly factor that is not closely associated with the functional core complex comprising VirB9 and VirB10. </p> <p> The work reported in this thesis advances the understanding of VirB8 self-association and its contribution to T4SS assembly and function. Furthermore, the establishment of the bacterial two-hybrid system to detect VirB interactions has helped identify inhibitors for the VirB8 dimerization through collaboration with Dr. Athanasios Paschos. Moreover, techniques such as ELISA, analytical ultracentrifugation, circular dichroism and surface plasmon resonance will be utilized routinely to characterize other VirB-VirB interactions in future. </p> / Thesis / Doctor of Philosophy (PhD) Type IV secretion system core component VirB8 biology
15	The Role of Cellular Autophagy and Type IV Secretion System in <i>Anaplasma phagocytophilum</i> Infection Niu, Hua 21 August 2008 (has links) No description available. Microbiology Anaplasma phagocytophilum Type IV Secretion System Autophagy
16	Molecular Interactions of Type III Secretion System Transcriptional Regulators in Pseudomonas aeruginosa: ExsA and ExsD Bernhards, Robert Cory 03 June 2013 (has links) The opportunistic pathogen Pseudomonas aeruginosa ranks among the leading causes of nosocomial infections. The type III secretion system (T3SS) aids acute P. aeruginosa infections by injecting potent cytotoxins (effectors) into host cells to suppress the host's innate immune response. Expression of all T3SS-related genes is strictly dependent upon the transcription factor ExsA. Consequently, ExsA and the biological processes that regulate ExsA function are of great biomedical interest. The ExsA-ExsC-ExsD-ExsE signaling cascade ties host cell contact to the up-regulation of T3SS gene expression. Prior to T3SS induction, the antiactivator protein ExsD binds to ExsA and blocks ExsA-dependent transcription by interfering with ExsA dimerization and promoter interactions. Upon host cell contact, ExsD is sequestered by the T3SS chaperone ExsC, resulting in the release of ExsA and an up-regulation of the T3SS. ExsA is an AraC/XylS-type transcriptional regulator and belongs to a subfamily of activators that regulate the T3SS in a variety of Gram-negative pathogens. These regulators are characteristically difficult to purify due to the low solubility of their C-terminal DNA binding domains. A new method for purifying ExsA was developed and produced ExsA with improved solubility. The interaction of ExsA and its PexsD promoter was examined using fluorescence anisotropy. An in vitro transcription assay was developed and it was determined that ExsA is sufficient to activate T3SS transcription. Next, the ExsD--ExsA inhibitory mechanism was examined. It was demonstrated for the first time that ExsD alone is sufficient to inhibit ExsA-dependent transcription in vitro without the aid of any other cellular factors. More significantly and contrary to previously published results, it was discovered that independently folded ExsD and ExsA are capable of interacting, but only at 37 degrees C and not at 30 degrees C. Guided by the crystal structure of ExsD, a monomeric variant of the protein was designed to demonstrate that ExsD trimerization prevents ExsD from inhibiting ExsA-dependent transcription at 30 degrees C. To further elucidate the ExsD-ExsA inhibitory mechanism, the ExsD-ExsA interface was examined. ExsD variants were generated and used to determine which region of ExsD interacts with ExsA. Interestingly, ExsD was also found to bind DNA, although it is unclear whether or not this plays a role in ExsA inhibition. Fully understanding the mechanism by which ExsD inhibits ExsA may enable the development of drugs that target ExsA in order to shut down the T3SS, thereby eliminating P. aeruginosa infection. / Ph. D. Pseudomonas aeruginosa ExsA ExsD type III secretion system transcriptional regulation
17	The role of type VI secretion systems in the competitive ability of Escherichia coli strain D12 Cekol, Ana January 2024 (has links) No description available. type VI secretion system bacterial competition Microbiology Mikrobiologi
18	Identification and characterization of Pseudomonas syringae mutants altering the induction of type III secretion system Deng, Xin January 1900 (has links) Doctor of Philosophy / Genetics Interdepartmental Program, Plant Pathology / Xiaoyan Tang / Pseudomonas syringae bacteria utilize the type III secretion system (T3SS) to deliver effector proteins into host cells. The T3SS and effector genes (together called the T3 genes hereafter) are repressed in nutrient rich medium but are rapidly induced after the bacteria are transferred into minimal medium (MM) or infiltrated into the plant. The induction of the T3 genes is mediated by HrpL, an alternative sigma factor that recognizes the conserved hrp box motif in the T3 gene promoters. The induction of hrpL is mediated by HrpR and HrpS, two homologous proteins that bind the hrpL promoter. To identify additional genes involved in regulation of the T3 genes, P. s. pv. phaseolicola (Psph) NPS3121 transposon insertion mutants were screened for reduced induction of avrPto-luc and hrpL-luc, reporter genes for promoters of effector gene avrPto and hrpL, respectively. Determination of the transposon-insertion sites led to the identification of genes with putative functions in signal transduction and transcriptional regulation, protein synthesis, and basic metabolism. A transcriptional regulator (AefRNPS3121) identified in the screen is homologous to AefR, a regulator of the quorum sensing signal and epiphytic (plant-associated) traits that was not known previously to regulate the T3 genes in P. s. pv. syringae (Psy) B728a. AefRNPS3121 in Psph NPS3121 and AefR in Psy B728a are similar in regulating the quorum sensing signal in liquid medium but different in regulating epiphytic traits such as swarming motility, entry into leaves, and survival on the leaf surface. The two component system RhpRS was identified in Pseudomonas syringae as a regulator of the T3 genes (Xiao et al. 2007). In the rhpS- mutant, the response regulator RhpR represses the induction of the T3 gene regulatory cascade, but induces its own promoter in a phosphorylation-dependent manner. Deletion and mutagenesis analyses revealed an inverted repeat (IR) element GTATC-N6-GATAC in the rhpR promoter that confers the RhpR-dependent induction. Computational search of the P. syringae genomes for the putative IR elements and Northern blot analysis of the genes with a putative IR element in the promoter region uncovered five genes that were upregulated (PSPTO2036, PSPTO2767, PSPTO3477, PSPTO3574, and PSPTO3660) and two genes that were down-regulated (PSPTO0536 and PSPTO0897) in an RhpR-dependent manner. ChIP assays indicated that RhpR binds the promoters containing a putative IR element but not the hrpR and hrpL promoters that do not have an IR element, suggesting that RhpR indirectly regulates the transcriptional cascade of hrpRS, hrpL, and the T3 genes. To identify additional genes involved in the rhpRS pathway, suppressor mutants were screened that restored the induction of the avrPto-luc reporter gene in the rhpS- mutant. Determination of the transposon-insertion sites led to the identification of rhpR, an ATP-dependent Lon protease, a sigma 70 family protein (PSPPH1909), and other metabolic genes. A lon- rhpS- double mutant exhibited phenotypes typical of a lon- mutant, suggesting that rhpS acts with or through lon. The expression of lon was elevated in rhpS- and other T3-deficient mutants, indicating a negative feedback mechanism. Both the lon- rhpS- and the PSPPH1909- rhpS- double mutant displayed enhanced transcription of hrpL in MM than did the rhpS- mutant. Pseudomonas syringae Type III secretion system Gene regulation AefR RhpRS Biology, Genetics (0369)
19	Comparative Phenotypic and Genomics Approaches Provide Insight into the Tripartite Symbiosis of Xenorhabdus bovienii with Steinernema Nematode and Lepidopteran Insect Hosts McMullen, John George II January 2015 (has links) Nematodes are highly diverse animals capable of interacting with almost every other form of life on Earth from general trophic interactions to intimate and persistent symbiotic associations. Much of their recognition originates from their various parasitic lifestyles. From an agricultural standpoint, plant parasitic nematodes are widely known for the destruction they can cause to crop plants, such as the case of the root-knot nematode Meloidogyne incognita, or livestock animals, like the Trichinella spiralis, which infects pigs and other animals. From a human health perspective, nematodes can cause many debilitating diseases, for example Wuchereria bancrofti, which is a causative agent of lymphatic filariasis or elephantiasis. However, not all parasitic nematodes have bad implications for human health. For instance, the diverse interactions of insect parasitic nematodes can be used to our benefit. Many of these species have been considered as biological control alternatives to different insect pests that wreak havoc on human, animal, and plant health. There still remain many questions surrounding their evolution, ecology, and physiological capabilities. Many of these taxa are hard to cultivate in the lab due to their complex and intimate lifestyles. Entomopathogenic nematodes (EPNs) are of great interest in agriculture because they vector insect pathogenic bacteria, which are capable of causing death to an insect host within 48 hours post-infection. Much of the molecular underpinnings in this system still remain to be discovered, from understanding the basic ability of these two organisms to associate with one another to genetically engineering more robust and host specific pathogens for application in the field. The focus of the research presented herein is on Steinernematidae nematodes and their bacterial symbionts. Specifically, it focused on the relationship between Xenorhabdus bovienii and its Steinernema hosts. Bioassays were designed to investigate insect virulence of X. bovienii alone in two Lepidoptera insect species with known differential susceptibility to Steinernema-Xenorhabdus pairs. A comparative genomic analysis was performed to compare different Xenorhabdus bovienii strains with observed variation in insect virulence. Results from this analysis demonstrated that virulent strains possess a type VI secretion system (T6SS) locus that is completely absent in strains with attenuated virulence. Bacterial competition assays between T6SS+ and T6SS- strains suggest this locus is involved in bacterial competition. Additionally, symbiont preference assays were carried out to investigate whether Steinernema hosts are able to discern between virulent and attenuated X. bovienii strains. Results from these assays revealed that Steinernema nematodes are able to distinguish between cognate and non-cognate X. bovienii symbionts, giving preference to virulent strains over those with attenuated virulence. Altogether these results provide further evidence that supports the notion that symbiont-switching events have occurred over the Steinernema-Xenorhabdus co-evolutionary history. Specifically, the competitive virulence of certain X. bovienii strains may have conferred them the ability to be selected by different Steinernema hosts, therefore contributing to the success of the nematode-bacterium partnership in being pathogenic to diverse insect hosts. insect virulence Steinernema type VI secretion system Microbiology host-symbiont switching
20	Study of expression and function of SepL, a regulator of type 3 secretion in enterohaemorrhagic Escherichia coli O157 Wang, Dai January 2011 (has links) Enterohaemorrhagic Escherichia coli (EHEC) are a recently emerged group of pathogens that can cause fatal infections in the young and elderly. EHEC utilize a virulence factor delivery organelle called a ’Type 3 secretion system’ that results in the formation of characteristic ‘pedestal structures’ on epithelial cells allowing colonization in the human or ruminant gastrointestinal tract. To achieve this, effector proteins have to be injected into host cells. The SepL-SepD complex has been shown to be key for controlling T3-related protein secretion in EHEC. Lack of either protein results in effector hypersecretion and strongly impaired secretion of EspADB translocon proteins. Therefore, the expression and function of SepL was the focus of my PhD research. The expression of SepL was shown to be heterogeneous and co-expressed with EspA filaments in EHEC O157 strains. My work revealed two transcriptional regulators (Ler and SepD) and two putative posttranscriptional regulators (Hfq and CsrA) of SepL expression. Further experiments mapped a key mRNA region required for heterogeneous expression of SepL. This sequence forms a predicted hairpin structure around the Shine-Dalgarno (SD) site of sepL. A model has been formed based on my data in which Hfq and CsrABCD bind to the mRNA potentially competing to control translation. Functionally, the C-terminus of SepL was found to be expendable for 1) SepD binding; 2) SepL membrane localization and 3) translocon export, however it was required for 1) limiting effector secretion via (2) a Tir interaction which might be disassociated by (3) an EscD interaction once host cell signals are sensed. Previously, the concept of two different types of T3 secretion signal were demonstrated in Yersinia spp, I tested this hypothesis in EHEC using both wild type and SepL/SepD deficient EHEC strains. SepL/SepD is required for the N-terminal signal pathway but not a chaperone binding domain signal pathway. A 12aa NleA which only contained an N-terminal signal was shown to bind to SepD and so did the multi-functional T3 chaperone ― CesT. Finally, Far-Western assays demonstrated that SepL only interacted with Tir while SepD could bind other effector proteins indicating that SepL/SepD may act as a targeting hub for effector protein secretion. 616.9

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