Gene_locus Report for: yerpe-IRP1

Yersinia pestis, the causative agent of plague, is a highly uniform clone that diverged recently from the enteric pathogen Yersinia pseudotuberculosis. Despite their close genetic relationship, they differ radically in their pathogenicity and transmission. Here, we report the complete genomic sequence of Y. pseudotuberculosis IP32953 and its use for detailed genome comparisons with available Y. pestis sequences. Analyses of identified differences across a panel of Yersinia isolates from around the world reveal 32 Y. pestis chromosomal genes that, together with the two Y. pestis-specific plasmids, to our knowledge, represent the only new genetic material in Y. pestis acquired since the the divergence from Y. pseudotuberculosis. In contrast, 149 other pseudogenes (doubling the previous estimate) and 317 genes absent from Y. pestis were detected, indicating that as many as 13% of Y. pseudotuberculosis genes no longer function in Y. pestis. Extensive insertion sequence-mediated genome rearrangements and reductive evolution through massive gene loss, resulting in elimination and modification of preexisting gene expression pathways, appear to be more important than acquisition of genes in the evolution of Y. pestis. These results provide a sobering example of how a highly virulent epidemic clone can suddenly emerge from a less virulent, closely related progenitor.

The Gram-negative bacterium Yersinia pestis is the causative agent of the systemic invasive infectious disease classically referred to as plague, and has been responsible for three human pandemics: the Justinian plague (sixth to eighth centuries), the Black Death (fourteenth to nineteenth centuries) and modern plague (nineteenth century to the present day). The recent identification of strains resistant to multiple drugs and the potential use of Y. pestis as an agent of biological warfare mean that plague still poses a threat to human health. Here we report the complete genome sequence of Y. pestis strain CO92, consisting of a 4.65-megabase (Mb) chromosome and three plasmids of 96.2 kilobases (kb), 70.3 kb and 9.6 kb. The genome is unusually rich in insertion sequences and displays anomalies in GC base-composition bias, indicating frequent intragenomic recombination. Many genes seem to have been acquired from other bacteria and viruses (including adhesins, secretion systems and insecticidal toxins). The genome contains around 150 pseudogenes, many of which are remnants of a redundant enteropathogenic lifestyle. The evidence of ongoing genome fluidity, expansion and decay suggests Y. pestis is a pathogen that has undergone large-scale genetic flux and provides a unique insight into the ways in which new and highly virulent pathogens evolve.

BACKGROUND: Virulence in the pathogenic bacterium Yersinia pestis, causative agent of bubonic plague, has been correlated with the biosynthesis and transport of an iron-chelating siderophore, yersiniabactin, which is induced under iron-starvation conditions. Initial DNA sequencing suggested that this system is highly conserved among the pathogenic Yersinia. Yersiniabactin contains a phenolic group and three five-membered thiazole heterocycles that serve as iron ligands.
RESULTS: The entire Y. pestis yersiniabactin region has been sequenced. Sequence analysis of yersiniabactin biosynthetic regions (irp2-ybtE and ybtS) reveals a strategy for siderophore production using a mixed polyketide synthase/nonribosomal peptide synthetase complex formed between HMWP1 and HMWP2 (encoded by irp1 and irp2). The complex contains 16 domains, five of them variants of phosphopantetheine-modified peptidyl carrier protein or acyl carrier protein domains. HMWP1 and HMWP2 also contain methyltransferase and heterocyclization domains. Mutating ybtS revealed that this gene encodes a protein essential for yersiniabactin synthesis.
CONCLUSIONS: The HMWP1 and HMWP2 domain organization suggests that the yersiniabactin siderophore is assembled in a modular fashion, in which a series of covalent intermediates are passed from the amino terminus of HMWP2 to the carboxyl terminus of HMWP1. Biosynthetic labeling studies indicate that the three yersiniabactin methyl moieties are donated by S-adenosylmethionine and that the linker between the thiazoline and thiazolidine rings is derived from malonyl-CoA. The salicylate moiety is probably synthesized using the aromatic amino-acid biosynthetic pathway, the final step of which converts chorismate to salicylate. YbtS might be necessary for converting chorismate to salicylate.

Yersinia pestis, the causative agent of plague, is a highly uniform clone that diverged recently from the enteric pathogen Yersinia pseudotuberculosis. Despite their close genetic relationship, they differ radically in their pathogenicity and transmission. Here, we report the complete genomic sequence of Y. pseudotuberculosis IP32953 and its use for detailed genome comparisons with available Y. pestis sequences. Analyses of identified differences across a panel of Yersinia isolates from around the world reveal 32 Y. pestis chromosomal genes that, together with the two Y. pestis-specific plasmids, to our knowledge, represent the only new genetic material in Y. pestis acquired since the the divergence from Y. pseudotuberculosis. In contrast, 149 other pseudogenes (doubling the previous estimate) and 317 genes absent from Y. pestis were detected, indicating that as many as 13% of Y. pseudotuberculosis genes no longer function in Y. pestis. Extensive insertion sequence-mediated genome rearrangements and reductive evolution through massive gene loss, resulting in elimination and modification of preexisting gene expression pathways, appear to be more important than acquisition of genes in the evolution of Y. pestis. These results provide a sobering example of how a highly virulent epidemic clone can suddenly emerge from a less virulent, closely related progenitor.

Genomics provides an unprecedented opportunity to probe in minute detail into the genomes of the world's most deadly pathogenic bacteria- Yersinia pestis. Here we report the complete genome sequence of Y. pestis strain 91001, a human-avirulent strain isolated from the rodent Brandt's vole-Microtus brandti. The genome of strain 91001 consists of one chromosome and four plasmids (pPCP1, pCD1, pMT1 and pCRY). The 9609-bp pPCP1 plasmid of strain 91001 is almost identical to the counterparts from reference strains (CO92 and KIM). There are 98 genes in the 70,159-bp range of plasmid pCD1. The 106,642-bp plasmid pMT1 has slightly different architecture compared with the reference ones. pCRY is a novel plasmid discovered in this work. It is 21,742 bp long and harbors a cryptic type IV secretory system. The chromosome of 91001 is 4,595,065 bp in length. Among the 4037 predicted genes, 141 are possible pseudo-genes. Due to the rearrangements mediated by insertion elements, the structure of the 91001 chromosome shows dramatic differences compared with CO92 and KIM. Based on the analysis of plasmids and chromosome architectures, pseudogene distribution, nitrate reduction negative mechanism and gene comparison, we conclude that strain 91001 and other strains isolated from M. brandti might have evolved from ancestral Y. pestis in a different lineage. The large genome fragment deletions in the 91001 chromosome and some pseudogenes may contribute to its unique nonpathogenicity to humans and host-specificity.

The Gram-negative bacterium Yersinia pestis is the causative agent of the systemic invasive infectious disease classically referred to as plague, and has been responsible for three human pandemics: the Justinian plague (sixth to eighth centuries), the Black Death (fourteenth to nineteenth centuries) and modern plague (nineteenth century to the present day). The recent identification of strains resistant to multiple drugs and the potential use of Y. pestis as an agent of biological warfare mean that plague still poses a threat to human health. Here we report the complete genome sequence of Y. pestis strain CO92, consisting of a 4.65-megabase (Mb) chromosome and three plasmids of 96.2 kilobases (kb), 70.3 kb and 9.6 kb. The genome is unusually rich in insertion sequences and displays anomalies in GC base-composition bias, indicating frequent intragenomic recombination. Many genes seem to have been acquired from other bacteria and viruses (including adhesins, secretion systems and insecticidal toxins). The genome contains around 150 pseudogenes, many of which are remnants of a redundant enteropathogenic lifestyle. The evidence of ongoing genome fluidity, expansion and decay suggests Y. pestis is a pathogen that has undergone large-scale genetic flux and provides a unique insight into the ways in which new and highly virulent pathogens evolve.

BACKGROUND: Virulence in the pathogenic bacterium Yersinia pestis, causative agent of bubonic plague, has been correlated with the biosynthesis and transport of an iron-chelating siderophore, yersiniabactin, which is induced under iron-starvation conditions. Initial DNA sequencing suggested that this system is highly conserved among the pathogenic Yersinia. Yersiniabactin contains a phenolic group and three five-membered thiazole heterocycles that serve as iron ligands.
RESULTS: The entire Y. pestis yersiniabactin region has been sequenced. Sequence analysis of yersiniabactin biosynthetic regions (irp2-ybtE and ybtS) reveals a strategy for siderophore production using a mixed polyketide synthase/nonribosomal peptide synthetase complex formed between HMWP1 and HMWP2 (encoded by irp1 and irp2). The complex contains 16 domains, five of them variants of phosphopantetheine-modified peptidyl carrier protein or acyl carrier protein domains. HMWP1 and HMWP2 also contain methyltransferase and heterocyclization domains. Mutating ybtS revealed that this gene encodes a protein essential for yersiniabactin synthesis.
CONCLUSIONS: The HMWP1 and HMWP2 domain organization suggests that the yersiniabactin siderophore is assembled in a modular fashion, in which a series of covalent intermediates are passed from the amino terminus of HMWP2 to the carboxyl terminus of HMWP1. Biosynthetic labeling studies indicate that the three yersiniabactin methyl moieties are donated by S-adenosylmethionine and that the linker between the thiazoline and thiazolidine rings is derived from malonyl-CoA. The salicylate moiety is probably synthesized using the aromatic amino-acid biosynthetic pathway, the final step of which converts chorismate to salicylate. YbtS might be necessary for converting chorismate to salicylate.