Phage Shock Protein C (PspC) of Yersinia enterocolitica Is a Polytopic Membrane Protein with Implications for Regulation of the Psp Stress Response

Phage shock proteins B (PspB) and C (PspC) are integral cytoplasmic membrane proteins involved in inducing the Yersinia enterocolitica Psp stress response. A fundamental aspect of these proteins that has not been studied in depth is their membrane topologies. Various in silico analyses universally predict that PspB is a bitopic membrane protein with the C terminus inside. However, similar analyses yield conflicting predictions for PspC: a bitopic membrane protein with the C terminus inside, a bitopic membrane protein with the C terminus outside, or a polytopic protein with both termini inside. Previous studies of Escherichia coli PspB-LacZ and PspC-PhoA fusion proteins supported bitopic topologies, with the PspB C terminus inside and the PspC C terminus outside. Here we have used a series of independent approaches to determine the membrane topologies of PspB and PspC in Y. enterocolitica. Our data support the predicted arrangement of PspB, with its C terminus in the cytoplasm. In contrast, data from multiple independent approaches revealed that both termini of PspC are located in the cytoplasm. Additional experiments suggested that the C terminus of PspC might be the recognition site for the FtsH protease and an interaction interface with PspA, both of which would be compatible with its newly proposed cytoplasmic location. This unexpected arrangement of PspC allows a new model for events underlying activation of the Psp response, which is an excellent fit with observations from various previous studies.     

PspB and PspC of Yersinia enterocolitica are dual function proteins: regulators and effectors of the phage-shock-protein response

The phage-shock-protein (Psp) stress-response system is conserved in many bacteria and has been linked to important phenotypes in Escherichia coli, Salmonella enterica and also Yersinia enterocolitica, where it is essential for virulence. It is activated by specific extracytoplasmic stress events such as the mislocalization of secretin proteins. From studies of the Psp system in E. coli, the cytoplasmic membrane proteins PspB and PspC have only been proposed to act as positive regulators of psp gene expression. However, in this study we show that PspB and PspC of Y. enterocolitica are dual function proteins, acting both as regulators and effectors of the Psp system. Consistent with the current model, they positively control psp gene expression in response to diverse inducing cues. PspB and PspC must work together to achieve this regulatory function, and bacterial two-hybrid (BACTH) analysis demonstrated a specific interaction between them, which was confirmed by in vivo cross-linking. We also show that PspB and PspC play a second role in supporting growth when a secretin protein is overexpressed. This function is independent from their role as regulators of psp gene expression. Furthermore, whereas PspB and PspC must work together for their regulatory function, they can apparently act independently to support growth during secretin production. This study expands the current understanding of the roles played by PspB and PspC, and demonstrates that they cannot be considered only as positive regulators of psp gene expression in Y. enterocolitica.     

The Yersinia enterocolitica phage shock proteins B and C can form homodimers and heterodimers in vivo with the possibility of close association between multiple domains

The Yersinia enterocolitica phage shock protein (Psp) stress response is essential for virulence and for survival during the mislocalization of outer membrane secretin proteins. The cytoplasmic membrane proteins PspB and PspC are critical components involved in regulating psp gene expression and in facilitating tolerance to secretin-induced stress. Interactions between PspB and PspC monomers might be important for their functions and for PspC stability. However, little is known about these interactions and there are conflicting reports about the ability of PspC to dimerize. To address this, we have used a combination of independent approaches to systematically analyze the ability of PspB and PspC to form dimers in vivo. Formaldehyde cross-linking of the endogenous chromosomally encoded proteins in Y. enterocolitica revealed discrete complexes corresponding in size to PspB-PspB, PspC-PspC, and PspB-PspC. Bacterial two-hybrid analysis corroborated these protein associations, but an important limitation of the two-hybrid approach was uncovered for PspB. A series of PspB and PspC proteins with unique cysteine substitutions at various positions was constructed. In vivo disulfide cross-linking experiments with these proteins further supported close association between PspB and PspC monomers. Detailed cysteine substitution analysis of predicted leucine zipper-like amphipathic helices in both PspB and PspC suggested that their hydrophobic faces could form homodimerization interfaces.     

Physical, functional and conditional interactions between ArcAB and phage shock proteins upon secretin-induced stress in Escherichia coli

The phage shock protein (Psp) system found in enterobacteria is induced in response to impaired inner membrane integrity (where the Psp response is thought to help maintain the proton motive force of the cell) and is implicated in the virulence of pathogens such as Yersinia and Salmonella . We provided evidence that the two-component ArcAB system was involved in induction of the Psp response in Escherichia coli and now report that role of ArcAB is conditional. ArcAB, predominantly through the action of ArcA regulated genes, but also via a direct ArcB–Psp interaction, is required to propagate the protein IV (pIV)-dependent psp -inducing signal(s) during microaerobiosis, but not during aerobiosis or anaerobiosis. We show that ArcB directly interacts with the PspB, possibly by means of the PspB leucine zipper motif, thereby allowing cross-communication between the two systems. In addition we demonstrate that the pIV-dependent induction of psp expression in anaerobiosis is independent of PspBC, establishing that PspA and PspF can function as a minimal Psp system responsive to inner membrane stress.     

Phage shock proteins B and C prevent lethal cytoplasmic membrane permeability in Yersinia enterocolitica

The bacterial phage shock protein (Psp) stress response system is activated by events affecting the cytoplasmic membrane. In response, Psp protein levels increase, including PspA, which has been implicated as the master effector of stress tolerance. Yersinia enterocolitica and related bacteria with a defective Psp system are highly sensitive to the mislocalization of pore-forming secretin proteins. However, why secretins are toxic to psp null strains, whereas some other Psp inducers are not, has not been explained. Furthermore, previous work has led to the confounding and disputable suggestion that PspA is not involved in mitigating secretin toxicity. Here we have established a correlation between the amount of secretin toxicity in a psp null strain and the extent of cytoplasmic membrane permeability to large molecules. This leads to a morphological change resembling cells undergoing plasmolysis. Furthermore, using novel strains with dis-regulated Psp proteins has allowed us to obtain unequivocal evidence that PspA is not required for secretin-stress tolerance. Together, our data suggest that the mechanism by which secretin multimers kill psp null cells is by causing a profound defect in the cytoplasmic membrane permeability barrier. This allows lethal molecular exchange with the environment, which the PspB and PspC proteins can prevent.     

PspG, a new member of the Yersinia enterocolitica phage shock protein regulon

The Yersinia enterocolitica phage shock protein (Psp) system is induced when the Ysc type III secretion system is produced or when only the YscC secretin component is synthesized. Some psp null mutants have a growth defect when YscC is produced and a severe virulence defect in animals. The Y. enterocolitica psp locus is made up of two divergently transcribed cistrons, pspF and pspABCDycjXF. pspA operon expression is dependent on RpoN (sigma(54)) and the enhancer-binding protein PspF. Previous data indicated that PspF also controls at least one gene that is not part of the psp locus. In this study we describe the identification of pspG, a new member of the PspF regulon. Predicted RpoN-binding sites upstream of the pspA genes from different bacteria have a common divergence from the consensus sequence, which may be a signature of PspF-dependent promoters. The Y. enterocolitica pspG gene was identified because its promoter also has this signature. Like the pspA operon, pspG is positively regulated by PspF, negatively regulated by PspA, and induced in response to the production of secretins. Purified His(6)-PspF protein specifically interacts with the pspA and pspG control regions. A pspA operon deletion mutant has a growth defect when the YscC secretin is produced and a virulence defect in a mouse model of infection. These phenotypes were exacerbated by a pspG null mutation. Therefore, PspG is the missing component of the Y. enterocolitica Psp regulon that was previously predicted to exist.     

小肠结肠炎耶尔森菌对多粘菌素B的压力应答

【背景】小肠结肠炎耶尔森菌(Yersinia enterocolitica)是重要的人畜共患食源性病原菌。由于其生存环境与传染性生活方式,小肠结肠炎耶尔森菌暴露在各种生存压力中,而胞膜压力应答能力对维持其环境耐受性和毒力发挥着重要作用。【目的】探究小肠结肠炎耶尔森菌在胞膜压力应答中的调节机制。【方法】通过使用多粘菌素B破坏小肠结肠炎耶尔森菌细胞膜的稳定性,并从生长能力、运动能力、生物被膜形成能力以及相关基因表达的变化探讨Rcs (Regulator of Capsule Synthesis)系统对多粘菌素B产生的胞膜压力的应答。【结果】多粘菌素B引起的细胞胞膜压力抑制了小肠结肠炎耶尔森菌的运动和生物被膜形成能力;而阻断Rcs信号途径后,小肠结肠炎耶尔森菌的运动和生物被膜形成能力有所恢复。对flhC、hmsS、hmsT等关键下游表型基因的表达水平的分析结果表明Rcs双组分系统对由多粘菌素B诱导的胞膜压力作出响应,通过感知胞膜胁迫向胞内传递信号,积极地调控细菌增强对抗菌肽的抗性。【结论】明确了Rcs双组分系统在响应多粘菌素B压力胁迫中的特异性调控作用,加深了对小肠结肠炎耶尔森菌环境应答机制的认识。     

The Tat System for Membrane Translocation of Folded Proteins Recruits the Membrane-stabilizing Psp Machinery in Escherichia coli

Tat systems transport folded proteins across energized membranes of bacteria, archaea, and plant plastids. In Escherichia coli, TatBC complexes recognize the transported proteins, and TatA complexes are recruited to facilitate transport. We achieved an abstraction of TatA from membranes without use of detergents and observed a co-purification of PspA, a membrane-stress response protein. The N-terminal transmembrane domain of TatA was required for the interaction. Electron microscopy displayed TatA complexes in direct contact with PspA. PspB and PspC were important for the TatA-PspA contact. The activator protein PspF was not involved in the PspA-TatA interaction, demonstrating that basal levels of PspA already interact with TatA. Elevated TatA levels caused membrane stress that induced a strictly PspBC- and PspF-dependent up-regulation of PspA. TatA complexes were found to destabilize membranes under these conditions. At native TatA levels, PspA deficiency clearly affected anaerobic TMAO respiratory growth, suggesting that energetic costs for transport of large Tat substrates such as TMAO reductase can become growth limiting in the absence of PspA. The physiological role of PspA recruitment to TatA may therefore be the control of membrane stress at active translocons.     

<Emphasis Type="Italic">S</Emphasis>. Typhimurium <Emphasis Type="Italic">sseJ</Emphasis> gene decreases the <Emphasis Type="Italic">S</Emphasis>. Typhi cytotoxicity toward cultured epithelial cells

Background  

Salmonella enterica serovar Typhi and Typhimurium are closely related serovars as indicated by >96% DNA sequence identity between shared genes. Nevertheless, S. Typhi is a strictly human-specific pathogen causing a systemic disease, typhoid fever. In contrast, S. Typhimurium is a broad host range pathogen causing only a self-limited gastroenteritis in immunocompetent humans. We hypothesize that these differences have arisen because some genes are unique to each serovar either gained by horizontal gene transfer or by the loss of gene activity due to mutation, such as pseudogenes. S. Typhi has 5% of genes as pseudogenes, much more than S. Typhimurium which contains 1%. As a consequence, S. Typhi lacks several protein effectors implicated in invasion, proliferation and/or translocation by the type III secretion system that are fully functional proteins in S. Typhimurium. SseJ, one of these effectors, corresponds to an acyltransferase/lipase that participates in SCV biogenesis in human epithelial cell lines and is needed for full virulence of S. Typhimurium. In S. Typhi, sseJ is a pseudogene. Therefore, we suggest that sseJ inactivation in S. Typhi has an important role in the development of the systemic infection.     

Possible use of <Emphasis Type="Italic">ail</Emphasis> and <Emphasis Type="Italic">foxA</Emphasis> polymorphisms for detecting pathogenic <Emphasis Type="Italic">Yersinia enterocolitica</Emphasis>

Background  

Yersinia enterocolitica is an enteric pathogen that invades the intestinal mucosa and proliferates within the lymphoid follicles (Peyer's patches). The attachment invasion locus (ail) mediates invasion by Y. enterocolitica and confers an invasive phenotype upon non-invasive E. coli; ail is the primary virulence factor of Y. enterocolitica. The ferrioxamine receptor (foxA) located on the Y. enterocolitica chromosome, together with its transport protein, transports a siderophore specific for ferric ion. Currently, ail is the primary target gene for nucleic acid detection of pathogenic Y. enterocolitica.     

Dissipation of Proton Motive Force is not Sufficient to Induce the Phage Shock Protein Response in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Phage shock proteins (Psp) and their homologues are found in species from the three domains of life: Bacteria, Archaea and Eukarya (e.g. higher plants). In enterobacteria, the Psp response helps to maintain the proton motive force (PMF) of the cell when the inner membrane integrity is impaired. The presumed ability of ArcB to sense redox changes in the cellular quinone pool and the strong decrease of psp induction in ΔubiG or ΔarcAB backgrounds suggest a link between the Psp response and the quinone pool. The authors now provide evidence indicating that the physiological signal for inducing psp by secretin-induced stress is neither the quinone redox state nor a drop in PMF. Neither the loss of the H⁺-gradient nor the dissipation of the electrical potential alone is sufficient to induce the Psp response. A set of electron transport mutants differing in their redox states due to the lack of a NADH dehydrogenase and a quinol oxidase, but retaining a normal PMF displayed low levels of psp induction inversely related to oxidised ubiquinone levels under microaerobic growth and independent of PMF. In contrast, cells displaying higher secretin induced psp expression showed increased levels of ubiquinone. Taken together, this study suggests that not a single but likely multiple signals are needed to be integrated to induce the Psp response.