Characterization of the angR gene of Vibrio anguillarum: essential role in virulence.

The ability to utilize the iron bound by high-affinity iron-binding proteins in the vertebrate host is an important virulence factor for the marine fish pathogen Vibrio anguillarum. Virulence in septicemic infections is due to the presence of a highly efficient plasmid-encoded iron transport system. AngR, a 110-kDa protein component of this system, appears to play a role in both regulation of the expression of the iron transport genes fatDCBA and the production of the siderophore anguibactin. Therefore, study of the expression of the angR gene and the properties of its product, the AngR protein, may contribute to the understanding of the mechanisms of virulence of this pathogen. In this work, we present genetic and molecular evidence from transposition mutagenesis experiments and RNA analysis that angR, which maps immediately downstream of the fatA gene, is part of a polycistronic transcript that also includes the iron transport genes fatDCBA and angT, a gene located downstream of angR which showed domain homology to certain thioesterases involved in nonribosomal peptide synthesis of siderophores and antibiotics. In order to dissect the specific domains of AngR associated with regulation of iron transport gene expression, anguibactin production, and virulence, we also generated a panel of site-directed angR mutants, as well as deletion derivatives. Both virulence and anguibactin production were dramatically affected by each one of the angR modifications. In contrast to the need for an intact AngR molecule for anguibactin production and virulence, the regulation of iron transport gene expression does not require the entire AngR molecule, since truncation of the carboxy terminus carrying the nonribosomal peptide synthetase cores, as well as the site-directed mutations, resulted in derivatives that retained their ability to regulate gene expression which was only abolished after truncation of amino-terminal sequences containing helix-turn-helix and leucine zipper motifs and a specialized heterocyclization and condensation domain found in certain nonribosomal peptide synthetases. The evidence, while not rigorously eliminating the possibility that a separate regulatory polypeptide exists and is encoded somewhere within the 5'-end region of the angR gene, strongly supports the idea that AngR is a bifunctional protein and that it plays an essential role in the virulence mechanisms of V. anguillarum. We also show in this study that the angT gene, found downstream of angR, intervenes in the mechanism of anguibactin production but is not essential for virulence or iron transport gene expression.

The AngR protein and the siderophore anguibactin positively regulate the expression of iron-transport genes in Vibrio anguillarum.

Vibrio anguillarum virulence is associated with the presence of a plasmid-mediated iron-uptake system expressed under iron-limiting conditions, which consists of the siderophore anguibactin and specific iron-transport proteins. This system is maximally expressed under iron-limiting conditions and requires the AngR protein that acts as a positive regulator of anguibactin biosynthesis and also possess an EntE-like enzymatic function that may play a role in anguibactin biosynthesis. In this work, we demonstrate that in addition to possessing these functions related to anguibactin production, AngR also positively regulated transcription of the iron-transport genes fatA and fatB. We also show that transcription of angR is repressed by Fur under iron-rich conditions. In addition, we present evidence that anguibactin itself enhanced transcription of the iron-transport genes fatA and fatB, independently of AngR and the trans-acting factor (TAF) product(s). The presence of either AngR (together with the TAF product(s)) or anguibactin alone led to a partial level of expression of the iron-transport genes fatA and fatB, while full expression is achieved when AngR, the TAF products and anguibactin are all present.

Structural and functional analyses of mutant Fur proteins with impaired regulatory function.

Vibrio anguillarum Fur mutants, 775met9 and 775met11, were characterized. V. anguillarum 775met9 had a change of D to G at position 104 located in the carboxy terminus resulting in impaired Fur activity. Computer analysis predicts perturbation of an alpha-helix in the carboxy terminus which may interfere with Fur protein conformation. Strain 775met11 had a change in the start codon resulting in no protein synthesis. The mutants are unstable, and reversion to the wild type occurs frequently.

Characterization of the Vibrio anguillarum fur gene: role in regulation of expression of the FatA outer membrane protein and catechols.

The chromosomally encoded Vibrio anguillarum fur gene was characterized. The amino acid sequence of the Fur protein showed a very high degree of homology with those of V. cholerae and V. vulnificus. The degree of homology was lower, although still high, with the Escherichia coli and Yersinia pestis Fur amino acid sequences, while the lowest degree of homology was found with the Pseudomonas aeruginosa Fur protein. The C-terminal portion of Fur is the least conserved region among these Fur proteins. Within this portion, two regions spanning amino acids 105 to 121 and 132 to the end are the least conserved. A certain degree of variation is also present in the N termini spanning amino acids 28 to 46. Regulation of expression of the V. anguillarum fur gene by iron was not detected by immunoblot analysis. Mutations in the cloned fur gene were generated either by site-directed mutagenesis (the Lys-77 was changed to a Gly to generate the derivative FurG77) or by insertion of a DNA fragment harboring the aph gene in the same position. FurG77 was impaired in its ability to regulate a reporter gene with the Fur box in its promoter, while the insertion mutant was completely inactive. V. anguillarum fur mutants were obtained by isolating manganese-resistant derivatives. In one of these mutants, which encoded a Fur protein with an apparent lower molecular weight, the regulation of the production of catechols and synthesis of the outer membrane protein FatA were partially lost. In the case of another mutant, no protein was detected by anti-Fur serum. This derivative showed a total lack of regulation of biosynthesis of catechols and FatA protein by iron.