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cAMP-independent and dependent regulation of Pseudomonas aeruginosa twitching motilityBuensuceso, Ryan Nicholas Carlos January 2017 (has links)
Type IVa pili (T4aP) are long, retractile, filamentous, surface appendages involved in cellular surface adhesion, biofilm formation, DNA uptake, and a unique form of motility called ‘twitching’. They are a critical virulence factor in a number of bacteria, including the opportunistic pathogen Pseudomonas aeruginosa, a major cause of hospital-acquired infections. T4aP function is controlled by a number of different regulatory proteins and systems. A putative chemosensory system termed ‘Chp’, controls levels of the second messenger molecule cyclic adenosine monophosphate (cAMP). cAMP works with a cAMP receptor protein called Vfr to control expression of ~200 virulence genes, including those that are required to make T4aP. cAMP levels are regulated by proteins outside the Chp system, including the bitopic inner membrane protein, FimV. This study examines the role of the Chp system and FimV in T4aP regulation. Both proteins are required for regulation of cAMP levels, while the Chp system also has a cAMP-independent role in regulating twitching. FimV has been shown to regulate cAMP levels, possibly connecting to the Chp system through a scaffold protein, FimL. We present the structure of a conserved cytoplasmic region of FimV, and show that this region is required for connecting FimV to the Chp system. We also characterize the cAMP-independent role of FimV, confirming that it is distinct from that of the Chp system, and is involved in localizing T4P regulatory proteins. We also provide evidence that the cAMP-independent role of the Chp system is to mediate the balance between T4P extension and retraction, possibly through denoting the ‘front’ of a motile cell. Together, these data help to resolve the cAMP-independent and –dependent pathways controlling twitching motility. / Thesis / Doctor of Philosophy (PhD) / Pseudomonas aeruginosa is a bacterium that causes infection in people with weakened immune systems. One key factor it uses to cause infection is the type IVa pilus (T4aP), a filamentous appendage displayed on the cell surface. T4aP can repeatedly extend and retract, and are involved in attachment to host cells, and movement along surfaces. When T4aP cannot extend or retract, the bacteria cannot cause infection. Many proteins work together to control T4aP function – this study focuses on two of them. They have one overlapping function, controlling levels of a signalling molecule needed to make T4aP. We also show that they have a second, non-overlapping function. One is involved in controlling the extension/retraction balance, possibly by marking the front of a cell, while the other may localize pilus-related proteins within a cell. This work helps us understand how P. aeruginosa makes T4aP, and provides information helpful to understanding control of virulence.
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Single point mutations in type IV pilus fiber proteins restore twitching in ΔpilU mutantsBarnshaw, Rebecca 11 1900 (has links)
Type IV pili (T4P) are long adhesive surface filaments produced by bacteria and are a key virulence factor for many pathogens. T4P are produced by a dynamic intracellular nanomachine that facilitates the assembly (extension) and disassembly (retraction) of pili. Pilus dynamics are enabled by the motor subcomplex of the nanomachine, where cytoplasmic ATPases power pilus assembly (PilB) and disassembly (PilT and PilU). In many, but not all, T4P expressing bacteria – including our model organism Pseudomonas aeruginosa – two retraction ATPases are required for functional retraction, which can be assessed by measuring twitching motility. Deletion of pilT results in loss of twitching and phage susceptibility (another hallmark of pilus function) while deletion of pilU results in loss of twitching but retention of phage susceptibility, indicating pili can still be retracted. We hypothesized that PilU adds to the force of pilus retraction, facilitating disassembly when the fiber is under tension. We mutated ΔpilU and pilU::Tn5 strains with ethyl methanesulfonate and screened for gain-of-twitching mutants. Whole genome sequencing revealed multiple point mutations in the major pilin protein PilA or the pilus adhesin, PilY1. These point mutations were recapitulated in a ΔpilU strain and restored twitching to varying degrees. Complementation of pilA point mutants with pilU in trans influenced the twitching zone of only one mutant, and in trans expression of wild-type pilA resulted in a significant reduction in twitching in most. The contribution of PilU to the force of pilus retraction was further investigated by a polyacrylamide micropillar assay, where no pulling events could be detected for either ΔpilT or ΔpilU mutants. Exopolysaccharide production, a proxy for surface sensing, was uncoupled from twitching motility in the pilA point mutants. These results are a significant step forward to understanding what PilU does and, provides insight to the dynamics of the pilus fiber. / Thesis / Master of Science (MSc) / Pseudomonas aeruginosa is a bacterium that causes serious infections. P. aeruginosa uses adhesive, “grappling hook” filaments called Type IV pili (T4P) to stick to its hosts. T4P can be repeatedly extended and retracted, allowing the bacteria to crawl on surfaces (twitching) but making them susceptible to bacteriophages, viruses that attach to pili then kill the bacterial cells. The motor proteins PilT and PilU are required for twitching, but only PilT is essential for phage killing, implying that pili are retracted even when PilU is missing. Here we hypothesized that PilU is important for twitching because it helps generate force for retraction when pili are under tension. We isolated multiple mutations in pilus components that restored twitching in the absence of PilU, and propose that these mutations allow for easier retraction of pili. This information helps us understand how T4P help the bacteria to spread during infection.
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Estudo funcional e estrutural dos reguladores da biossíntese do Pilus Tipo IV de Xanthomonas citri subsp. citri / Functional and structural studies of the regulators of Type IV Pilus biogenesis in Xanthomonas citri subsp. citriCornejo, Edgar Enrique Llontop 13 June 2019 (has links)
O pilus tipo IV (T4P) são finos e flexíveis filamentos encontrados na superfície de uma ampla gama de bactérias Gram-negativas, Gram-positivas e archaea. O T4P desempenha um rol crucial no estilo de vida bacteriano ao estar envolvido em uma variedade de funções incluindo motilidade, aderência, formação de biofilme, patogenicidade, transformação natural e na infecção por fagos. Várias das proteínas requeridas para a biossíntese e regulação do T4P se estendem através do periplasma conectado a membrana interna e externa. O T4P são estruturas dinâmicas que sofrem ciclos de extensão e retração energizados por duas ATPases associadas com a membrana interna bacteriana. Durante a extensão, PilB, a ATPase de biossíntese do T4P, estimula a polimerização do pilus a partir de monômeros de pilinas localizados na membrana interna, através de um mecanismo ainda desconhecido. Duas proteínas, FimX e PilZ estão envolvidas na regulação da biossíntese do T4P via interações com PilB e nocautes de esses genes acabam com a biogênese e função do T4P. Neste trabalho, nós determinamos a estrutura cristalográfica do complexo binário formado pelo domínio N-terminal de PilB (PilBNt, resíduos 12-163) e a PilZ com uma resolução de 1.7 Å. As interações entre PilB e PilZ envolve uma superfície hidrofóbica formada por aminoácidos altamente conservados na família não canônica de domínios PilZ. Mutações ou deleções de alguns destes resíduos em PilZ enfraquecem a interação PilB-PilZ e afeta a função do T4P. Nós também observamos que esta interação induz mudanças conformacionais no domínio PilBNt, revelando a possibilidade de um rearranjo estrutural funcionalmente relevante da região Nterminal de PilB permitindo a sua interação com PilM, conectando a ATPase PilB como a maquinaria do T4P. Nós mostramos que PilB, PilZ e FimX podem formar um complexo ternário estável com uma massa molar aparente de ~600 kDa, sugerindo uma estequiometria de 6PilB:6PilZ:2FimX. Também observamos que FimX incrementa a atividade ATPase do complexo PilB-PilZ. O c-di-GMP e o ATPγS (um análogo não hidrolisável do ATP) induz mudanças conformacionais em FimX e no complexo PilB-PilZ, respectivamente, e estabiliza o complexo ternário PilB-PilZ-FimX. Além disso, PilB, PilZ e FimX localizam em um dos polos da célula (polo líder) em células de X. citri e a localização polar dirige a orientação da motilidade twitching. Finalmente, o T4P é necessário para a exitosa infecção de X. citri pelo fago ΦXacm4-11. Nossos resultados sugerem que asinterações entre PilB-PilZ-FimX estariam envolvidas na regulação da função de PilB, onde sinais especificas sentidas pelos domínios de FimX seriam transmitidas por PilZ até PilB. / Bacterial type IV pili (T4P) are thin and flexible filaments found on the surface of a wide range of Gram-negative bacteria and play a crucial role in their lifestyles due to their involvement in a variety of functions including motility, adherence, biofilm formation, pathogenicity, natural transformation and phage infection. Several proteins required for the biogenesis and regulation of T4P span the periplasm connecting both the inner and outer membranes. T4P are dynamic structures that undergo cycles of extension and retraction powered by two hexameric ATPases associated with the bacterial inner membrane. During extensions, the T4P assembly ATPase PilB stimulates the polymerization of pilin monomers from the inner membrane, though the precise mechanism is unknown. Two proteins, FimX and PilZ are involved in the regulation of T4P biogenesis via interactions with the PilB and knockouts of these proteins abolish T4P biogenesis. Here, we determined the crystal structure of the binary complex made up of the PilB N-terminal domain (PilBNt, residues 12- 163) bound to PilZ at 1.7Å resolution. PilZ interactions with PilB involve a hydrophobic surface made up of amino acids conserved in a non-canonical family of PilZ domains. Mutations or deletion of some these amino acids in PilZ weaken the PilZ-PilB interaction and affect T4P function. This interaction induces significant conformational changes in the PilBNt domain, suggesting that structural rearrangements of the PilB N-terminal domains could be important for its interaction with PilM, connecting the ATPase PilB with T4P machinery. We show also that full-length PilB, PilZ and FimX can form a stable ternary complex with apparent molecular weight of ~600 kDa, suggestive of a 6PilB:6PilZ:2FimX stoichiometry and that FimX increases the ATPase activity of the PilB PilZ complex. C-diGMP and ATPγS (non-hydrolysable analog of ATP) induce conformational changes in FimX and in PilB-PilZ, respectively, and stabilize the ternary PilB-PilZ-FimX complex. In addition, we show that PilB, PilZ and FimX localize at one cell pole (leading pole) that drives the movement in X. citri. Finally, the T4P is necessary for successful infection of X. citri cells by phage ΦXacm4-11. Our results suggest how FimXPilZPilB interactions could be involved in the regulation of PilB function, where specific environmental signals sensed by FimX domains could be transmitted via PilZ to PilB.
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A Study of Surface Motility and Biofilm Formation in Pseudomonas aeruginosa: Quorum Sensing and Photodynamic Antimicrobial ChemotherapyCollins, Tracy Lynn January 2010 (has links)
No description available.
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Investigating AmrZ-mediated activation of <i>Pseudomonas aeruginosa</i> twitching motility and alginate productionXu, Binjie January 2015 (has links)
No description available.
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