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Role of type IV secretion systems in trafficking of virulence determinants of Burkholderia cenocepaciaEngledow, Amanda Suzanne 02 June 2009 (has links)
Type IV secretion systems have been identified in several human pathogens including Bordetella pertussis, Helicobacter pylori, and Legionella pneumophila. These systems are responsible for the translocation of virulence proteins and/or DNA, thereby playing an important role in the pathogenesis of infection and plasticity of genomes. Burkholderia cenocepacia is an important opportunistic human pathogen, particularly in persons with cystic fibrosis (CF). Respiratory tract infection by B. cenocepacia in CF patients is often associated with a decline in respiratory function, and can result in acute systemic infection. Burkholderia cenocepacia strain K56-2 is part of the epidemic and clinically problematic ET12 lineage. Two type IV secretion systems have been identified in this strain; one system is plasmid encoded (designated the Ptw type IV secretion system) whereas the other is chromosomally encoded (designated the VirB/D type IV secretion system) and shows homology to the Agrobacterium tumefaciens VirB/D4 type IV secretion system. It was determined that the plasmid encoded Ptw system is a chimeric type IV secretion system composed of VirB/D4-like elements and F-specific subunits. More recently, it was found that this system translocates a protein effector (PtwE1) that is cytotoxic to plant cells. It was also determined that the positively charged C-terminal region of PtwE1 is important for translocation via the Ptw type IV secretion system. Strains of the epidemic B. cenocepacia PHDC lineage contain only a chromosomal VirB/D4-like type IV secretion system (designated BcVirB/D); and a putative effector protein associated with this system has been identified that has C-terminal transport signal and sequences different from the effectors of the Ptw type IV secretion system. It has also been shown that a competing plasmid substrate and a plasmid fertility inhibition factor act to render B. cenocepacia of the PHDC lineage incapable of expressing a plant phenotype. Thus, three type IV secretion systems have been identified in epidemic B. cenocepacia lineages. From two of these, an effector has been identified that has cytotoxic effects on eukaryotic cells, and at least one of these type IV secretion systems is able to translocate DNA substrates.
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Role of type IV secretion systems in trafficking of virulence determinants of Burkholderia cenocepaciaEngledow, Amanda Suzanne 02 June 2009 (has links)
Type IV secretion systems have been identified in several human pathogens including Bordetella pertussis, Helicobacter pylori, and Legionella pneumophila. These systems are responsible for the translocation of virulence proteins and/or DNA, thereby playing an important role in the pathogenesis of infection and plasticity of genomes. Burkholderia cenocepacia is an important opportunistic human pathogen, particularly in persons with cystic fibrosis (CF). Respiratory tract infection by B. cenocepacia in CF patients is often associated with a decline in respiratory function, and can result in acute systemic infection. Burkholderia cenocepacia strain K56-2 is part of the epidemic and clinically problematic ET12 lineage. Two type IV secretion systems have been identified in this strain; one system is plasmid encoded (designated the Ptw type IV secretion system) whereas the other is chromosomally encoded (designated the VirB/D type IV secretion system) and shows homology to the Agrobacterium tumefaciens VirB/D4 type IV secretion system. It was determined that the plasmid encoded Ptw system is a chimeric type IV secretion system composed of VirB/D4-like elements and F-specific subunits. More recently, it was found that this system translocates a protein effector (PtwE1) that is cytotoxic to plant cells. It was also determined that the positively charged C-terminal region of PtwE1 is important for translocation via the Ptw type IV secretion system. Strains of the epidemic B. cenocepacia PHDC lineage contain only a chromosomal VirB/D4-like type IV secretion system (designated BcVirB/D); and a putative effector protein associated with this system has been identified that has C-terminal transport signal and sequences different from the effectors of the Ptw type IV secretion system. It has also been shown that a competing plasmid substrate and a plasmid fertility inhibition factor act to render B. cenocepacia of the PHDC lineage incapable of expressing a plant phenotype. Thus, three type IV secretion systems have been identified in epidemic B. cenocepacia lineages. From two of these, an effector has been identified that has cytotoxic effects on eukaryotic cells, and at least one of these type IV secretion systems is able to translocate DNA substrates.
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Characterization of interactions of the Type IV secretion system core component VirB8Sivanesan, 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)
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The Role of Cellular Autophagy and Type IV Secretion System in <i>Anaplasma phagocytophilum</i> InfectionNiu, Hua 21 August 2008 (has links)
No description available.
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The Human Cell as an Environment for Horizontal Gene TransferFerguson, Gayle Christy January 2002 (has links)
Horizontal gene transfer (HGT) is now indisputably the predominant driving force, if not the sole force, behind speciation and the evolution of novelty in bacteria. Of all mechanisms of horizontal gene transfer (HGT), conjugation, the contact-dependent plasmid-mediated transfer of DNA from a bacterial donor to a recipient cell, is probably the most universal. First observed between bacteria, conjugation also mediates gene transfer from bacteria to yeast, plant and even animal cells. The range of environments in which bacteria naturally exchange DNA has not been extensively explored. The interior of the animal cell represents a novel and potentially medically relevant environment for gene transfer. Since most antibiotics are ineffective inside mammalian cells, our cells may be a niche for the evolution of resistance and virulence in invasive pathogens. Invading bacteria accumulate in vacuoles inside human cells, protected from antibiotics. Herein, I demonstrate the ability of intracellular Salmonella typhimurium to meet and exchange plasmid DNA by conjugation within animal cells, revealing the animal intracellular milieu as a permissive environment for gene exchange. This finding evokes a model for the simultaneous dissemination of virulence and antibiotic resistance within a niche protected from both antibiotics and the immune system and extends the variety of environments in which bacteria are known to exchange genes. Unlike conjugation between bacteria, conjugation between bacteria and eukaryotic cells requires the import of transferred DNA into the nucleus before the transferred genes can be expressed and inherited. Plant-cell nuclear transformation by the conjugation system of the Agrobacterium tumefaciens Ti plasmid is believed to be mediated by nuclear localization sequences (NLSs) carried within the proteins that accompany the T-DNA during transfer. Whether NLSs are equally important for transmission of other conjugative plasmids to eukaryotic cells is unknown. Herein, I demonstrate nuclear localization potential within the putative conjugative escort protein TraI of the IncPa plasmid RP4. In contrast, MobA, the putative escort protein from the IncQ plasmid RSF1010, lacked any clear nuclear localization potential. It is therefore likely that specific nuclear localization signals within conjugative proteins are not essential for nuclear transformation per se, although they may assist in efficient plasmid transmission.
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The Human Cell as an Environment for Horizontal Gene TransferFerguson, Gayle Christy January 2002 (has links)
Horizontal gene transfer (HGT) is now indisputably the predominant driving force, if not the sole force, behind speciation and the evolution of novelty in bacteria. Of all mechanisms of horizontal gene transfer (HGT), conjugation, the contact-dependent plasmid-mediated transfer of DNA from a bacterial donor to a recipient cell, is probably the most universal. First observed between bacteria, conjugation also mediates gene transfer from bacteria to yeast, plant and even animal cells. The range of environments in which bacteria naturally exchange DNA has not been extensively explored. The interior of the animal cell represents a novel and potentially medically relevant environment for gene transfer. Since most antibiotics are ineffective inside mammalian cells, our cells may be a niche for the evolution of resistance and virulence in invasive pathogens. Invading bacteria accumulate in vacuoles inside human cells, protected from antibiotics. Herein, I demonstrate the ability of intracellular Salmonella typhimurium to meet and exchange plasmid DNA by conjugation within animal cells, revealing the animal intracellular milieu as a permissive environment for gene exchange. This finding evokes a model for the simultaneous dissemination of virulence and antibiotic resistance within a niche protected from both antibiotics and the immune system and extends the variety of environments in which bacteria are known to exchange genes. Unlike conjugation between bacteria, conjugation between bacteria and eukaryotic cells requires the import of transferred DNA into the nucleus before the transferred genes can be expressed and inherited. Plant-cell nuclear transformation by the conjugation system of the Agrobacterium tumefaciens Ti plasmid is believed to be mediated by nuclear localization sequences (NLSs) carried within the proteins that accompany the T-DNA during transfer. Whether NLSs are equally important for transmission of other conjugative plasmids to eukaryotic cells is unknown. Herein, I demonstrate nuclear localization potential within the putative conjugative escort protein TraI of the IncPa plasmid RP4. In contrast, MobA, the putative escort protein from the IncQ plasmid RSF1010, lacked any clear nuclear localization potential. It is therefore likely that specific nuclear localization signals within conjugative proteins are not essential for nuclear transformation per se, although they may assist in efficient plasmid transmission.
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Roles of Type IV Secretion Effector Etf-2 and Etf-3 in Ehrlichia chaffeensis InfectionYan, Qi January 2020 (has links)
No description available.
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ROLES OF TYPE IV SECRETION EFFECTOR ECH0825 IN EHRLICHIA CHAFFEENSIS INFECTIONLiu, Hongyan January 2013 (has links)
No description available.
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Lifestyle and Genome Evolution in Vector-Borne Bacteria : A Comparison of Three Bartonella Species / Livsstil och genomevolution i vektorburna bakterier : en jämförelse av tre Bartonella-arterFrank, Anna Carolin January 2005 (has links)
Bacterial genomes provide records of the molecular processes associated with emergence and evolution of different bacterial lifestyles. This thesis is based on whole-genome comparisons within the genus Bartonella, an excellent model system for studies of host- and vector-specificity and infection outcome in animal-associated bacteria. The louse-borne human specialist and trench fever agent Bartonella quintana was contrasted to the flea-borne generalist relatives Bartonella henselae and Bartonella grahamii, which cause asymptomatic infection in cat and mouse respectively. While B. henselae is commonly isolated from humans, and causes cat scratch disease, there is only one reported case of B. grahamii human infection. The gene complements of the three species are nested like Russian dolls with the smaller genome (B. quintana) being entirely contained in the medium sized (B. henselae), which in turned is contained in the largest (B. grahamii). Size differences reflect differences in the horizontally and vertically acquired gene content, and in the number of genus- and species- specific genes, owing to differential impact of bacteriophages and plasmids, and to different degrees of genome decay. These processes can be attributed to the three distinct lifestyles. Comparisons with other alpha-proteobacteria suggest that the Bartonella genus as a whole evolved from plant-associated species, and that horizontal transfer, in particular of genes involved in interaction with the host, played a key role in the transition to animal intracellular lifestyle. The long-term genome decay associated with this lifestyle is most advanced in the host-restricted B. quintana. The broad host-range species B. grahamii has the largest genome and the largest proportion of auxiliary DNA of the three, probably because it has access to a larger gene pool. In encodes all the known pathogenicity determinants found in the genomes of B. henselae and B. quintana, suggesting that these genes primarily evolved to facilitate colonization in the reservoir host.
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Transcriptional regulators of <i>Ehrlichia chaffeensis</i> during intracellular development and the roles of OmpA in the bacterial infection and survivalCheng, Zhihui 08 December 2008 (has links)
No description available.
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