Analysis of membrane protein interaction: ToxR can dimerize the amino terminus of phage lambda repressor

The ToxR protein of Vibrio cholerae is an integral membrane protein that co-ordinately regulates virulence determinant expression. ToxR directiy activates the cholera toxin operon, but maximal activation is achieved in the presence of ToxS, an integral membrane protein thought to interact with ToxR periplasmic sequences. Studies that substitute alkaline phosphatase sequences for the periplasmic domain of ToxR have led to a model for ToxR activation based on dimerization and ToxS interaction. We constructed λ-ToxR chimeric proteins using the DNA-binding domain of the phage λ repressor, which cannot effectively dimerize by itself, to assess the ability of ToxR to form dimers in Escherichia coli The results suggest that ToxR sequences can propagate dimerization, and that ToxS can influence the ability to dimerize.     

霍乱弧菌ToxS蛋白间的互作增强ToxR蛋白诱导毒力基因的表达

【目的】阐明霍乱弧菌ToxR蛋白功能调控的分子机制。【方法】利用巯基捕获(thiol-trapping)的方法分析DsbA蛋白对ToxR周质空间结构域半胱氨酸残基的氧化作用;采用定点突变的方法构建ToxR半胱氨酸突变株(ToxR_(C236/293S));利用荧光素酶基因作为报告基因分析ToxR野生型(ToxR_(wt))和半胱氨酸突变体(ToxR_(C236/293S))诱导下游基因表达的活性;通过细菌双杂交系统分析ToxR_(wt)和ToxR_(C236/293S)蛋白之间、ToxR与ToxS之间以及ToxS之间的相互作用。【结果】ToxR周质空间结构域半胱氨酸残基确实可以被DsbA蛋白氧化,且当ToxR与ToxS共表达时,ToxR诱导ctxAB转录表达的活性显著增强,且在dsbA基因缺失突变株中ToxR诱导ctxAB转录表达的活性更高;成功构建株霍乱弧菌ToxR半胱氨酸突变株(ToxR_(C236/293S)),在没有ToxS存在的条件下,ToxR_(C236/293S)诱导毒力基因表达的活性与ToxRwt相当;细菌双杂交系统分析发现当ToxR与ToxS共转录表达时,ToxS极大增强ToxR蛋白之间的互作;在dsbA基因缺失突变株中,ToxS之间的相互作用显著增强。【结论】ToxR蛋白本身的氧还状态对其诱导毒力基因表达的活性没有影响;ToxS通过增强ToxR形成二聚体的能力从而增强其诱导毒力基因的表达,而DsbA对ToxS蛋白之间的相互作用具有抑制作用,DsbA通过影响ToxS的蛋白互作从而影响ToxR蛋白的功能。本文为进一步阐明霍乱弧菌毒力基因表达调控的分子机制提供重要的理论依据。     

A family of modular type mannuronan C-5-epimerase genes controls alginate structure in Azotobacter vinelandii

The ToxR protein is a transmembrane protein that regulates the expression of several virulence factors of Vibrio cholerae. Previous analysis of fusion proteins between ToxR and alkaline phosphatase (ToxR-PhoA) suggested that ToxR was active as a dimer. In order to determine whether dimerization of the ToxR periplasmic domain was essential for activity, this domain was replaced by monomeric and dimeric protein domains. Surprisingly, PhoA (dimeric), β-lactamase (monomeric, ToxR–Bla), or the leucine zipper of GCN4 (dimeric, ToxR-GCN4-M) could substitute functionally for the ToxR periplasmic domain. ToxR-GCN4 fusion proteins, in which the ToxR trans-membrane domain was eliminated (ToxR-GCN4-C), were inactive, but an additional fusion protein that contained a heterologous membrane-spanning domain retained activity. Strains containing each of these ToxR fusion proteins were analysed for in vivo colonization properties and response to in vitro growth conditions that are known to affect expression of the ToxR regulon. Strains containing ToxR-GCN4-M and ToxR-Bla responded like wild-type strains to in vitro growth conditions. In the infant-mouse colonization model, strains containing ToxR fusion proteins were all deficient in colonization relative to strains containing wild-type ToxR, and strains containing monomeric ToxR-Bla were most severely outcompeted. These results suggest that, under in vitro conditions, ToxR does not require a dimerized periplasmic domain, but that, under in vivo conditions, the correct conformation of the ToxR periplasmic domain may be more important for function.     

The ToxR protein of Vibrio cholerae forms homodimers and heterodimers.

The ToxR protein of Vibrio cholerae regulates the expression of several virulence factors that play important roles in the pathogenesis of cholera. Previous experiments with ToxR-alkaline phosphatase (ToxR-PhoA) fusion proteins suggested a model for gene regulation in which the inactive form of ToxR was a monomer and the active form of ToxR was a dimer (V. L. Miller, R. K. Taylor, and J. J. Mekalanos, Cell 48:271-279, 1987). In order to examine whether ToxR exists in a dimeric form in vivo, biochemical cross-linking analyses were carried out. Different dimeric cross-linked species were detected depending on the expression level of ToxR: when overexpressed, ToxR+ToxR homodimers and ToxR+ToxS heterodimers were detected, and when ToxR was expressed at normal levels, exclusively ToxR+ToxS heterodimers were detected. The amount of overexpression was quantitated by using ToxR-PhoA fusion proteins and was found to correspond to 2.7-fold the normal level of ToxR. The formation of both homodimeric ToxR species and heterodimeric ToxR+ToxS species is consistent with previously reported genetic data that suggested that both types of ToxR oligomeric interactions occur. However, variation in the amount of either the homodimeric or heterodimeric form detectable by this cross-linking analysis was not observed to correlate with laboratory culture conditions known to modulate ToxR activity. Thus, genetic and biochemical data indicate that ToxR is able to interact with both itself and ToxS but that these interactions may not explain mechanistically the observed changes in ToxR activity that occur in response to environmental conditions.     

A ToxR homolog from Vibrio anguillarum serotype O1 regulates its own production, bile resistance, and biofilm formation

ToxR, a transmembrane regulatory protein, has been shown to respond to environmental stimuli. To better understand how the aquatic bacterium Vibrio anguillarum, a fish pathogen, responds to environmental signals that may be necessary for survival in the aquatic and fish environment, toxR and toxS from V. anguillarum serotype O1 were cloned. The deduced protein sequences were 59 and 67% identical to the Vibrio cholerae ToxR and ToxS proteins, respectively. Deletion mutations were made in each gene and functional analyses were done. Virulence analyses using a rainbow trout model showed that only the toxR mutant was slightly decreased in virulence, indicating that ToxR is not a major regulator of virulence factors. The toxR mutant but not the toxS mutant was 20% less motile than the wild type. Like many regulatory proteins, ToxR was shown to negatively regulate its own expression. Outer membrane protein (OMP) preparations from both mutants indicated that ToxR and ToxS positively regulate a 38-kDa OMP. The 38-kDa OMP was shown to be a major OMP, which cross-reacted with an antiserum to OmpU, an outer membrane porin from V. cholerae, and which has an amino terminus 75% identical to that of OmpU. ToxR and to a lesser extent ToxS enhanced resistance to bile. Bile in the growth medium increased expression of the 38-kDa OMP but did not affect expression of ToxR. Interestingly, a toxR mutant forms a better biofilm on a glass surface than the wild type, suggesting a new role for ToxR in the response to environmental stimuli.     

Role of ToxS in the proteolytic cascade of virulence regulator ToxR in Vibrio cholerae

Two of the primary virulence regulators of Vibrio cholerae, ToxR and TcpP, function together with cognate effector proteins. ToxR undergoes regulated intramembrane proteolysis (RIP) during late stationary phase in response to nutrient limitation at alkaline pH; however, the specific function of its cognate ToxS remains unresolved. In this work, we found that ToxR rapidly becomes undetectable in a ΔtoxS mutant when cultures are exposed to either starvation conditions or after alkaline pH shock individually. A ΔtoxS mutant enters into a dormant state associated with the proteolysis of ToxR at a faster rate than wild‐type, closely resembling a ΔtoxR mutant. Using a mutant with a periplasmic substitution in ToxS, we found that the proteases DegS and DegP function additively with VesC and a novel protease, TapA, to degrade ToxR in the mutant. Overall, the results shown here reveal a role for ToxS in the stabilization of ToxR by protecting the virulence regulator from premature proteolysis.     

Septal Localization of FtsQ, an Essential Cell Division Protein in Escherichia coli

Septation in Escherichia coli requires several gene products. One of these, FtsQ, is a simple bitopic membrane protein with a short cytoplasmic N terminus, a membrane-spanning segment, and a periplasmic domain. We have constructed a merodiploid strain that expresses both FtsQ and the fusion protein green fluorescent protein (GFP)-FtsQ from single-copy chromosomal genes. The gfp-ftsQ gene complements a null mutation in ftsQ. Fluorescence microscopy revealed that GFP-FtsQ localizes to the division site. Replacing the cytoplasmic and transmembrane domains of FtsQ with alternative membrane anchors did not prevent the localization of the GFP fusion protein, while replacing the periplasmic domain did, suggesting that the periplasmic domain is necessary and sufficient for septal targeting. GFP-FtsQ localization to the septum depended on the cell division proteins FtsZ and FtsA, which are cytoplasmic, but not on FtsL and FtsI, which are bitopic membrane proteins with comparatively large periplasmic domains. In addition, the septal localization of ZipA apparently did not require functional FtsQ. Our results indicate that FtsQ is an intermediate recruit to the division site.     

Transmembrane signalling by a hybrid protein: communication from the domain of chemoreceptor Trg that recognizes sugar-binding proteins to the kinase/phosphatase domain of osmosensor EnvZ.

Chemoreceptor Trg and osmosensor EnvZ of Escherichia coli share a common transmembrane organization but have essentially unrelated primary structures. We created a hybrid gene coding for a protein in which Trg contributed its periplasmic and transmembrane domains as well as a short cytoplasmic segment and EnvZ contributed its cytoplasmic kinase/phosphatase domain. Trz1 transduced recognition of sugar-occupied, ribose-binding protein by its periplasmic domain into activation of its cytoplasmic kinase/phosphatase domain as assessed in vivo by using an ompC-lacZ fusion gene. Functional coupling of sugar-binding protein recognition to kinase/phosphatase activity indicates shared features of intramolecular signalling in the two parent proteins. In combination with previous documentation of transduction of aspartate recognition by an analogous fusion protein created from chemoreceptor Tar and EnvZ, the data indicate a common mechanism of transmembrane signal transduction by chemoreceptors and EnvZ. Signalling through the fusion proteins implies functional interaction between heterologous domains, but the minimal sequence identity among relevant segments of EnvZ, Tar, and Trg indicates that the link does not require extensive, specific interactions among side chains. The few positions of identity in those three sequences cluster in transmembrane segment 1 and the short chemoreceptor sequence in the cytoplasmic part of the hybrid proteins. These regions may be particularly important in physical and functional coupling. The specific cellular conditions necessary to observe ligand-dependent activation of Trz1 can be understood in the context of the importance of phosphatase control in EnvZ signalling and limitations on maximal receptor occupancy in binding protein-mediated recognition.