Regulation of the expression of the Vibrio parahaemolyticus peuA gene encoding an alternative ferric enterobactin receptor.

A pvsB-vctA-irgA triple deletion mutant of Vibrio parahaemolyticus can utilize enterobactin under iron-limiting conditions by inducing a previously undescribed receptor, PeuA (VPA0150), in response to extracellular alkaline pH and enterobactin. In silico analyses revealed the existence of a two-component regulatory system operon, peuRS, immediately upstream of peuA, which constitutes an operon with the TonB2 system genes. Both the peuRS and peuA-tonB2 operons were found to be upregulated under iron-limiting conditions in a ferric uptake regulator (Fur)-dependent manner. The involvement of peuA and peuRS in enterobactin utilization was analyzed by complementation experiments using deletion mutants. Primer extension analysis indicated that, under iron-limiting conditions, the transcription of peuA was initiated from the +1 site at pH 7.0 and from both the +1 and +39 sites at pH 8.0 in the presence of enterobactin. The +39 transcript was absent from the peuRS deletion mutant. Secondary structure prediction of their 5'-untranslated regions suggested that translation initiation is blocked in the +1 transcript, but not in the +39 transcript. Consistent with this, in vitro translation analysis demonstrated that production of PeuA was determined only by the +39 transcript. These studies establish a novel gene regulation mechanism in which the two-component regulatory system PeuRS enhances expression of the alternative +39 transcript that possesses non-inhibitory structure, allowing the peuA expression to be regulated at the translation stage.

Characterization of Vibrio parahaemolyticus genes encoding the systems for utilization of enterobactin as a xenosiderophore.

We determined the ability of Vibrio parahaemolyticus to utilize enterobactin (Ent) as a xenosiderophore. Homology searches of the V. parahaemolyticus genomic sequence revealed the presence of genes that are homologous to the V. cholerae ferric Ent utilization genes, which consist of the iron-repressible outer-membrane protein genes irgA and vctA, and the ATP-binding cassette transport system operon vctPDGC. Moreover, the irgB and vctR genes, which encode transcriptional regulators, were also found immediately upstream of irgA and vctA, respectively. Growth assays of V. parahaemolyticus indicated that both irgA and vctA mutants grew well in the presence of Ent under iron-limiting conditions, whereas both the irgA/vctA double mutant and the vctPDGC mutant barely grew under the same conditions. In addition, growth assays of three isogenic tonB mutants demonstrated that the TonB2 system, and to a lesser extent the TonB1 system, can provide energy for both IrgA and VctA to transport ferric Ent. SDS-PAGE analysis showed that expression of both IrgA and VctA was enhanced by the presence of Ent. Complementation of the irgB and vctR mutants with their respective genes resulted in the increased expression of IrgA and VctA, respectively. Finally, reverse transcriptase-quantitative PCR revealed that transcription of the Ent utilization system genes is iron-regulated, and that transcription of irgA and vctA under iron-limiting conditions is further activated by proteins encoded by irgB and vctR, respectively, together with Ent.

Identification and characterization of genes required for utilization of desferri-ferrichrome and aerobactin in Vibrio parahaemolyticus.

During the course of our investigation on the iron acquisition systems in Vibrio parahaemolyticus, a causative agent of seafood-related gastroenteritis, we found that this species utilizes desferri-ferrichrome for growth as a heterologous siderophore (a siderophore produced by other bacteria and fungi) under iron-limiting conditions. N-Terminal amino acid sequence analysis of the iron-repressible outer membrane proteins followed by searches of the reported genomic sequences of this species identified four relevant genes (called fhuACDB) forming an operon. Deletion analysis of the fhuA and fhuD genes indicated that the most upstream gene fhuA and the three downstream genes fhuCDB encode the ferrichrome receptor and the ATP-binding cassette transport components, respectively. Moreover, it was found that the fhuCDB genes are also required for transport of ferric aerobactin which restores growth of this species under iron-limiting conditions.

Identification and characterization of two contiguous operons required for aerobactin transport and biosynthesis in Vibrio mimicus.

In response to iron deprivation, Vibrio mimicus produces aerobactin as a major siderophore. Application of the Fur titration assay to a V. mimicus genomic DNA library followed by further cloning of the surrounding regions led to the identification of two adjacent, iron-regulated operons. One contains three genes encoding homologs of the Escherichia coli FhuCDB and the other, five genes encoding homologs of the E. coli IucABCD IutA. Construction of the V. mimicus polar disruptants in the respective operons allowed us to confirm their functions. The genetic arrangement of the aerobactin-mediated iron acquisition system in V. mimicus is unique in that the aerobactin operon (iucABCD iutA ) is contiguous to the operon (matCDB ) encoding components of an ATP-binding cassette transport system for ferric aerobactin. This is the first report demonstrating that aerobactin transport and biosynthesis genes are present in a species outside the family Enterobacteriaceae.