Virulence of Yersinia enterocolitica is closely associated with siderophore production, expression of an iron-repressible outer membrane polypeptide of 65 000 Da and pesticin sensitivity

Iron-repressible outer membrane proteins (Irp) and siderophore production of Yersinia enterocolitica, serotype 08, were subjected to analysis. Here four Irps of apparent molecular weights of 62000, 65000, 74000 and 75000 could be identified which were expressed constitutively by a fur mutant. Production of a novel catechol-containing siderophore (denoted yersiniabactin) was detected by siderophore-indicator agar (chrome azurol S) and feeding experiments. Growth support by yersiniabactin under iron-restricted conditions was TonB- and Irp65-dependent and correlated with pesticin-sensitivity of Yersinia enterocolitica and Escherichia coliø. From these results we conclude that Irp65 of Y. enterocolitica functions as yersiniabactin receptor (FyuA) and as pesticin receptor. By immunoblotting using rabbit antibodies against Irp65 and chrome azurol S-agar, we were able to demonstrate that all tested mouse-lethai Y. enterocoiitica and Yersinia pseudotuberculosis strains of different serotypes express siderophores and Irp65. Moreover, the anti-lrp65 rabbit serum did not cross-react with the known iron-repressible high-molecular-weight proteins (HMWPs). Evidently, the mouse lethality trait in enteropathogenic Yersinia spp. is closely associated with a novel iron-uptake system, comprising the production of a siderophore and a siderophore receptor of apparent molecular mass 65 000 Da.     

The Yersiniabactin Biosynthetic Gene Cluster of Yersinia enterocolitica: Organization and Siderophore-Dependent Regulation

The ability to synthesize and uptake the Yersinia siderophore yersiniabactin is a hallmark of the highly pathogenic, mouse-lethal species Yersinia pestis, Y. pseudotuberculosis, and Y. enterocolitica 1B. We have identified four genes, irp1, irp3, irp4, and irp5, on a 13-kb chromosomal DNA fragment of Y. enterocolitica O8, WA-314. These genes constitute the yersiniabactin biosynthetic gene cluster together with the previously defined irp2. The irp1 gene consists of 9,486 bp capable of encoding a 3,161-amino-acid high-molecular-weight protein 1 (HMWP1) polypeptide with a predicted mass of 384.6 kDa. The first 3,000 bp of irp1 show similarity to the corresponding regions of the polyketide synthase genes of Bacillus subtilis and Streptomyces antibioticus. The remaining part of irp1 is most similar to irp2, encoding HMWP2, which might be the reason for immunological cross-reactivity of the two polypeptides. Irp4 was found to have 41.7% similarity to thioesterase-like protein of the anguibactin biosynthetic genes of Vibrio anguillarum. Irp5 shows 41% similarity to EntE, the 2,3-dihydroxybenzoic acid-activating enzyme utilized in enterobactin synthesis of Escherichia coli. Irp4 and Irp5 are nearly identical to YbtT and YbtE, recently identified in Y. pestis. irp3 has no similarity to any known gene. Inactivation of either irp1 or irp2 abrogates yersiniabactin synthesis. Mutations in irp1 or fyuA (encoding yersiniabactin/pesticin receptor) result in downregulation of irp2 that can be upregulated by the addition of yersiniabactin. A FyuA-green fluorescent protein translational fusion was downregulated in an irp1 mutant. Upregulation was achieved by addition of yersiniabactin but not desferal, pesticin, or pyochelin, which indicates high specificity of the FyuA receptor and autoregulation of genes involved in synthesis and uptake of yersiniabactin.     

The TonB-dependent ferrichrome receptor FcuA of Yersinia enterocolitica: evidence against a strict co-evolution of receptor structure and substrate specificity

A Yersinia enterocolitica receptor mutant was isolated which is impaired in ferrichrome uptake. The receptor-encoding gene fcuA was cloned in Escherichia coli K-12. A fcuA mutant of Y. enterocolitica could be complemented by the cloned DNA fragment. The FcuA-encoding region was sequenced and an open reading frame encoding 758 amino acids including a signal sequence of 36 amino acids was found. FcuA shared 34.6% amino acid sequence homology with FatA, the anguibactin receptor of Vibrio anguillarum, but only 20.6% homology with FhuA, the ferrichrome receptor of E. coli Since the structure of anguibactin differs strongly from that of ferrichrome there seems to be no co-evolution of receptor structure and substrate specificity. The ferrichrome receptors FcuA from Y. enterocolitica and FhuA from E. coli had slightly different substrate specificities. In contrast to FhuA from E. coli, FcuA from Y. enterocolitica was more stereoselective and failed to transport enantio ferrichrome. Three additional ferrichrome receptors were cloned from Pantoea aggiomerans (formerly Erwinia herbicola), Salmonella paratyphi B and Salmonella typhimurium. Their substrate specificity was similar but not identical.     

The TonB protein of Yersinia enterocolitica and its interactions with TonB-box proteins

Summary The tonB gene is required for energy-dependent transport processes across the outer membrane of gram-negative bacteria. Using the antibiotics albomycin and ferrimycin, a tonB mutant of Yersinia enterocolitica was isolated. Comparison of the tonB mutant with the parent strain revealed that in Y. enterocolitica the uptake of ferrioxamine, ferrichrome, pesticin and heme is TonB-dependent. The tonB gene from Y. enterocolitica was sequenced and found to be similar to those of other Enterobacteria. The Y. enterocolitica tonB gene complemented a Y. enterocolitica tonB mutant. In contrast, some Tong functions of an Escherichia coli tonB mutant were not restored by the tonB gene of Y. enterocolitica. The observed differences in the ability to complement E. coli Tong functions correlated with the degree to which the Tong boxes of the receptors and colicins differed from the TonB box consensus sequence. Furthermore, the N-terminal membrane anchor of the TonB proteins and the TolA protein are likely to form an -helix with an identical sequence motif (SHLS) located at one face of the a-helix, suggesting this region to be involved in the functional cross-talk between the TonB-ExbBD-and TolABQR-dependent transport systems across the outer membrane.     

Design,expression, and characterization of the hybrid antimicrobial peptide T‐catesbeianin‐1 based on FyuA

The overuse of antibiotics has resulted in the emergence of antibiotic‐resistant bacteria, which presents an urgent need for new antimicrobial agents. At present, antimicrobial peptides have attracted a great deal of attention from researchers. However, antimicrobial peptides often affect a broad range of microorganisms, including the normal flora in a host organism. In the present study, we designed a novel hybrid antimicrobial peptide, expressed the hybrid peptide, and studied its specific target. The hybrid peptide, named T‐catesbeianin‐1, which includes the FyuA‐binding domain of pesticin and the peptide catesbeianin‐1, was designed and expressed in Pichia pastoris X‐33. Then, we determined the antimicrobial activity, cytotoxicity, and specific target of the peptide. T‐catesbeianin‐1 has strong antimicrobial activity and binds to FyuA to inhibit or kill Escherichia coli present in clinical specimens and mixed‐species culture. In summary, these findings suggested that T‐catesbeianin‐1 might be promising and specific antibiotic agent for therapeutic application against fyuA⁺ E. coli.     

Analysis of the Epitopes Recognized by Mouse Monoclonal Antibodies Directed to Yersinia enterocolitica Heat-Shock Protein 60

To determine amino acid sequences of the epitopes recognized by monoclonal antibodies (mAbs) 3C8 and 5C3 directed against Yersinia enterocolitica heat-shock protein (HSP60), a dot blot analysis was perfomed using synthesized peptides of Y. enterocolitica HSP60 such as peptides p316-342, p327-359, p340-366, p316-326, p316-321, p319-323, and p321-326 which represent positions of amino acids in Y. enterocolitica HSP60. The dot blot analysis revealed that 5C3 mAb reacted with p316-342, p316-326 and p321-326, and 3C8 mAb p316-342 and p316-326. These results indicate that the epitopes recognized by the mAbs were associated with eleven amino acids, Asp Leu Gly Gln Ala Lys Arg Val Val Ile Asn, of p316-326. The sequence homology between p316-326 of Y. enterocolitica HSP60 and the rest of the HSP60 family suggests that the five amino acids of Lys, Arg, Val, Ile and Asn, which are highly conserved in the HSP60 family, might be related with the epitope recognized by 3C8. In contrast, it was also demonstrated that three amino acids of Leu, Gly and Val, which are not well conserved in the HSP60 family, might be related to the epitope recognized by 5C3.     

Ferrioxamine uptake in Yersinia enterocolitica: characterization of the receptor protein FoxA

The gene for the high-affinity outer membrane ferrioxamine receptor FoxA of Yersinia enterocolitica was cloned in Escherichia coli K-12. A foxA mutant of Yersinia could be complemented by the cloned DNA fragment. The FoxA encoding region was sequenced and an open reading frame encoding 710 amino acids, including a signal sequence of 26 amino acids, was deduced. The mature FoxA protein consisted of 684 amino acids and had a molecular mass of 75,768 Da. FoxA shared 33% amino acid sequence homology with FhuA, the ferrichrome receptor of Escherichia coli. Based on the homologies with FhuA and other TonB-dependent receptors a topological model of FoxA is presented.     

Analysis of the pesticin receptor from Yersinia pestis: role in iron-deficient growth and possible regulation by its siderophore.

We have sequenced a region from the pgm locus of Yersinia pestis KIM6+ that confers sensitivity to the bacteriocin pesticin to certain strains of Escherichia coli and Y. pestis. The Y. pestis sequence is 98% identical to the pesticin receptor from Yersinia enterocolitica and is homologous to other TonB-dependent outer membrane proteins. Y. pestis strains with an in-frame deletion in the pesticin receptor gene (psn) were pesticin resistant and no longer expressed a group of iron-regulated outer membrane proteins, IrpB to IrpD. In addition, this strain as well as a Y. pestis strain with a mutation constructed in the gene (irp2) encoding the 190-kDa iron-regulated protein HMWP2 could not grow at 37 degrees C in a defined, iron-deficient medium. However, the irp2 mutant but not the psn mutant could be cross-fed by supernatants from various Yersinia cultures grown under iron-deficient conditions. An analysis of the proteins synthesized by the irp2 mutant suggests that HMWP2 may be indirectly required for maximal expression of the pesticin receptor. HMWP2 likely participates in synthesis of a siderophore which may induce expression of the receptor for pesticin and the siderophore.     

Cloning and Nucleotide Sequence of the Endoinulinase-Encoding Gene, inu2, from Aspergillus ficuum

A 2.3 kb DNA fragment that contains a gene encoding endoinulinase, inu2, from Aspergillus ficuum ATCC 16882 was isolated and analyzed. It includes an open reading frame of 1,551 bp, coding for a polypeptide with calculated molecular weight of 55,790 Da, including a putative signal peptide of 22 amino acids. Alignment of amino acid sequences revealed 73.3% identity and 93.9% similarity between A. ficuum and Penicillium purpurogenum endoinulinase.     

Analysis of the Structural Gene Encoding a Hemolysin in Vibrio mimicus

An environmental isolate of V. mimicus, strain E-33, has been reported to produce and secrete a hemolysin of 63 kDa. The hemolysin is enterotoxic in test animals. The nucleotide sequence of the structural gene of the hemolysin was determined. We found a 2,232 bp open reading frame, which codes a peptide of 744 amino acids, with a calculated molecular weight of 83,903 Da. The sequence for the structural gene was closely related to the V. cholerae el tor hlyA gene, coding an exocellular hemolysin. The amino terminal amino-acid sequence of the 63 kDa hemolysin, purified from V. mimicus, was determined by the Edman degradation method and found to be NH₂-S-V-S-A-N-N-V-T-N-N-N-E-T. This sequence is identical from S-152 to T-164 predicted from the nucleotide sequence. So, it seems that the mature hemolysin in V. mimicus is processed upon deleting the first 151 amino acids, and the molecular mass is 65,972 Da. Analyzing the deduced amino-acid sequence, we also found a potential signal sequence of 24 amino acids at the amino terminal. Our results suggest that, like V. cholerae hemolysin, two-step processing also exists in V. mimicus hemolysin.