Comparative Genomic Analysis of Three Strains of
            <i>Ehrlichia ruminantium</i>
            Reveals an Active Process of Genome Size Plasticity

Frutos, Roger; Viari, Alain; Ferraz, Conchita; Morgat, Anne; Eychenié, Sophie; Kandassamy, Yane; Chantal, Isabelle; Bensaid, Albert; Coissac, Éric; Vachiéry, Nathalie; Demaille, Jacques; Martinez, Dominique

doi:10.1128/jb.188.7.2533-2542.2006

Cited by 87 publications

(96 citation statements)

References 67 publications

(78 reference statements)

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“…Indeed, the duplicationloss model suggests that the background frequency of tandem duplications is high, but that the copy number is normally kept in balance by an equally rapid collapse unless there is selection for more than one copy (36,37). Speaking against such a scenario is that the tra clusters are not situated in tandem, that there are few tandem gene repeats inside the clusters, and that the sizes of the repeated clusters is Ͼ10-fold longer than normally found for tandem repeats, such as for example in E. ruminantium (38,39). Furthermore, subsequent intragenomic recombination events must be invoked to explain the current distribution of the tra clusters across the genome.…”

Section: Expansion Of Genes For Conjugative Type IV Secretion Systemsmentioning

confidence: 99%

The Orientia tsutsugamushi genome reveals massive proliferation of conjugative type IV secretion system and host–cell interaction genes

Cho

Kim

Lee

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

212

259

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Scrub typhus is caused by the obligate intracellular rickettsiaOrientia tsutsugamushi (previously called Rickettsia tsutsugamushi). The bacterium is maternally inherited in trombicuid mites and transmitted to humans by feeding larvae. We report here the 2,127,051-bp genome of the Boryong strain, which represents the most highly repeated bacterial genome sequenced to date. The repeat density of the scrub typhus pathogen is 200-fold higher than that of its close relative Rickettsia prowazekii, the agent of epidemic typhus. A total of 359 tra genes for components of conjugative type IV secretion systems were identified at 79 sites in the genome. Associated with these are >200 genes for signaling and host-cell interaction proteins, such as histidine kinases, ankyrin-repeat proteins, and tetratrico peptide-repeat proteins. Additionally, the O. tsutsugamushi genome contains >400 transposases, 60 phage integrases, and 70 reverse transcriptases. Deletions and rearrangements have yielded unique gene combinations as well as frequent pseudogenization in the tra clusters. A comparative analysis of the tra clusters within the genome and across strains indicates sequence homogenization by gene conversion, whereas complexity, diversity, and pseudogenization are acquired by duplications, deletions, and transposon integrations into the amplified segments. The results suggest intragenomic duplications or multiple integrations of a massively proliferating conjugative transfer system. Diversifying selection on host-cell interaction genes along with repeated population bottlenecks may drive rare genome variants to fixation, thereby short-circuiting selection for low complexity in bacterial genomes.bacterial genome ͉ duplication ͉ repeats

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Section: Expansion Of Genes For Conjugative Type IV Secretion Systemsmentioning

confidence: 99%

The Orientia tsutsugamushi genome reveals massive proliferation of conjugative type IV secretion system and host–cell interaction genes

Cho

Kim

Lee

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

212

259

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“…Interestingly, the VLPT ortholog that we identified in E. canis in this study lacks the tandem repeats found in the E. chaffeensis VLPT gene, but it has a Ser/Thr/Glu-rich patch that is similar in size and composition to that of a single VLPT repeat unit. The addition and deletion of tandem repeats are considered a major source of change and instability in ehrlichial genomes (11). The fact that the E. canis gp19 protein lacks tandem repeats while the E. chaffeensis VLPT protein has variable numbers is indicative of these genes being affected by this process.…”

Section: Vol 75 2007mentioning

confidence: 99%

“…The genomes of E. canis and other organisms in the genus, including Ehrlichia chaffeensis and Ehrlichia ruminantium, exhibit a high degree of genomic synteny, paralogous protein families, a large proportion of proteins with transmembrane helices and/or signal sequences, tandem repeats and ankyrin domains in proteins associated with host-pathogen interactions, and a unique serine-threonine bias associated with a potential for O glycosylation and phosphorylation (6,10,11,18). A small subset of the approximately 1,000 proteins (including hypothetical proteins) encoded by each of these genomes is recognized by antibody (8,20,25,32).…”

mentioning

confidence: 99%

“…Extensive variability in the number and/or sequence of tandem repeats in the E. chaffeensis immunoreactive proteins (gp120, gp47, and VLPT) as well as E. canis gp36 is well documented (5,7,8,32). The presence of tandem repeats in both coding and noncoding regions of the genome has been linked to an active process of expansion and reduction of ehrlichial genomes (11) and is considered a major source of genomic change and instability (4).…”

mentioning

confidence: 99%

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Identification of a Glycosylated Ehrlichia canis 19-Kilodalton Major Immunoreactive Protein with a Species-Specific Serine-Rich Glycopeptide Epitope

McBride

Doyle²,

Zhang³

et al. 2007

Infect Immun

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Ehrlichia canis has a small subset of major immunoreactive proteins that includes a 19-kDa protein that elicits an early Ehrlichia-specific antibody response in infected dogs. We report herein the identification and molecular characterization of this highly conserved 19-kDa major immunoreactive glycoprotein (gp19) ortholog of the Ehrlichia chaffeensis variable-length PCR target (VLPT) protein. E. canis gp19 has substantial carboxyl-terminal amino acid homology (59%) with E. chaffeensis VLPT and the same chromosomal location; however, the E. chaffeensis VLPT gene (594 bp) has tandem repeats that are not present in the E. canis gp19 gene (414 bp). Consistent with other ehrlichial glycoproteins, the gp19 protein exhibited a larger-thanpredicted mass (ϳ3 kDa), O-linked glycosylation sites were predicted in an amino-terminal serine/threonine/ glutamate (STE)-rich patch (26 amino acids), carbohydrate was detected on the recombinant gp19 protein, and the neutral sugars glucose and galactose were detected on the recombinant amino-terminal polypeptide. E. canis gp19 composition consists of five predominant amino acids, cysteine, glutamate, tyrosine, serine, and threonine, concentrated in the STE-rich patch and a carboxyl-terminal domain predominated by cysteine and tyrosine (55%). The amino-terminal STE-rich patch contained a major species-specific antibody epitope strongly recognized by serum from an E. canis-infected dog. The recombinant glycopeptide epitope was substantially more reactive with antibody than the synthetic (nonglycosylated) peptide, and periodate treatment of the recombinant glycopeptide epitope reduced its immunoreactivity, demonstrating the importance of a carbohydrate immunodeterminant(s). The gp19 protein was present on reticulate and dense-cored cells, and it was found extracellularly in the fibrillar matrix and associated with the morula membrane, the host cell cytoplasm, and the nucleus.Ehrlichia canis is a tick-transmitted obligately intracellular bacterium that causes moderate to severe and sometimes fatal disease in wild and domestic canids. The genomes of E. canis and other organisms in the genus, including Ehrlichia chaffeensis and Ehrlichia ruminantium, exhibit a high degree of genomic synteny, paralogous protein families, a large proportion of proteins with transmembrane helices and/or signal sequences, tandem repeats and ankyrin domains in proteins associated with host-pathogen interactions, and a unique serine-threonine bias associated with a potential for O glycosylation and phosphorylation (6,10,11,18). A small subset of the approximately 1,000 proteins (including hypothetical proteins) encoded by each of these genomes is recognized by antibody (8,20,25,32). Several of the major immunoreactive proteins identified and molecularly characterized are serine-rich glycoproteins that are secreted. Many of these glycoproteins have tandem repeats; however, one has numerous eukaryote-like ankyrin domains (7,20,25,27,31,35).Numerous proteins that contain tandem repeats have been identified in E. ...

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“…However, differences also emerge relating to host pathology, the presence or absence of transovarial transmission and adaptation to a haematophagous vector [3], as well as the expansion of families of immunodominant outer membrane proteins, facilitating antigenic variation. The generation of multiple E. ruminantium genome sequences has enabled a third series of comparative approaches [4,5] (Frutos et al, this issue) to understanding the active process of genome evolution.…”

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confidence: 99%

Advances in the genomics of ticks and tick-borne pathogens

Jongejan

Nene²,

Fuente

et al. 2007

Trends in Parasitology

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Comparative Genomic Analysis of Three Strains of Ehrlichia ruminantium Reveals an Active Process of Genome Size Plasticity

Cited by 87 publications

References 67 publications

The Orientia tsutsugamushi genome reveals massive proliferation of conjugative type IV secretion system and host–cell interaction genes

The Orientia tsutsugamushi genome reveals massive proliferation of conjugative type IV secretion system and host–cell interaction genes

Identification of a Glycosylated Ehrlichia canis 19-Kilodalton Major Immunoreactive Protein with a Species-Specific Serine-Rich Glycopeptide Epitope

Advances in the genomics of ticks and tick-borne pathogens

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