Background: Bartonella species cospeciate with mammals and live within erythrocytes. Even in these specific niches, it has been recently suggested by bioinformatic analysis of full genome sequences that Lateral Gene Transfer (LGT) may occur but this has never been demonstrated biologically. Here we describe the sequence of the B. rattaustraliani (AUST/NH4 T) circular plasmid (pNH4) that encodes the tra cluster of the Type IV secretion system (T4SS) and we eventually provide evidence that Bartonella species may conjugate and exchange this plasmid inside amoeba. Principal Findings: The T4SS of pNH4 is critical for intracellular viability of bacterial pathogens, exhibits bioinformatic evidence of LGT among bacteria living in phagocytic protists. For instance, 3 out of 4 T4SS encoding genes from pNH4 appear to be closely related to Rhizobiales, suggesting that gene exchange occurs between intracellular bacteria from mammals (bartonellae) and plants (Rhizobiales). We show that B. rattaustraliani and Rhizobium radiobacter both survived within the amoeba Acanthamoeba polyphaga and can conjugate together. Our findings further support the hypothesis that tra genes might also move into and out of bacterial communities by conjugation, which might be the primary means of genomic evolution for intracellular adaptation by cross-talk of interchangeable genes between Bartonella species and plant pathogens. Conclusions: Based on this, we speculate that amoeba favor the transfer of genes as phagocytic protists, which allows fo

A Babic

A Beranek

A Seubert

A Shamaei-Tousi

AC Frank

B Ewing

B La Scola

B Nystedt

Bernard La Scola

C Moliner

Catherine Robert

CM Alsmark

D Raoult

Didier Raoult

DL Burns

DW Frank

E Angelakis

EC Berglund

G Blanc

G Greub

G Schroder

H Engelberg-Kulka

H Ogata

H Ohnishi

HL Saenz

I Chen

I Padmalayam

Immo A. Hansen

J Guglielmini

J Koesling

Jean-Marc Rolain

JM Rolain

KA Schandel

KW Jeon

M Chien

M Couturier

M Juhas

M Llosa

M Maurin

M Schmiederer

MB Yarmolinsky

MC Schmid

PE Fournier

PJ Christie

R Schulein

RB Jensen

S Biswas

S Halary

T Kaneko

V Anantharaman

V Merhej

V Thomas

VA Gundi

W Deng

Watcharee Saisongkorh

YA Wang

PLoS ONE

English

PubMed

BACKGROUND: Bartonella species cospeciate with mammals and live within erythrocytes. Even in these specific niches, it has been recently suggested by bioinformatic analysis of full genome sequences that Lateral Gene Transfer (LGT) may occur but this has never been demonstrated biologically. Here we describe the sequence of the B. rattaustraliani (AUST/NH4(T)) circular plasmid (pNH4) that encodes the tra cluster of the Type IV secretion system (T4SS) and we eventually provide evidence that Bartonella species may conjugate and exchange this plasmid inside amoeba. PRINCIPAL FINDINGS: The T4SS of pNH4 is critical for intracellular viability of bacterial pathogens, exhibits bioinformatic evidence of LGT among bacteria living in phagocytic protists. For instance, 3 out of 4 T4SS encoding genes from pNH4 appear to be closely related to Rhizobiales, suggesting that gene exchange occurs between intracellular bacteria from mammals (bartonellae) and plants (Rhizobiales). We show that B. rattaustraliani and Rhizobium radiobacter both survived within the amoeba Acanthamoeba polyphaga and can conjugate together. Our findings further support the hypothesis that tra genes might also move into and out of bacterial communities by conjugation, which might be the primary means of genomic evolution for intracellular adaptation by cross-talk of interchangeable genes between Bartonella species and plant pathogens. CONCLUSIONS: Based on this, we speculate that amoeba favor the transfer of genes as phagocytic protists, which allows for intraphagocytic survival and, as a consequence, promotes the creation of potential pathogenic organisms

Directory of Open Access Journals

Evidence of transfer by conjugation of type IV secretion system genes between Bartonella species and Rhizobium radiobacter in amoeba.

 species may conjugate and exchange this plasmid inside amoeba. species and plant pathogens.Based on this, we speculate that amoeba favor the transfer of genes as phagocytic protists, which allows for intraphagocytic survival and, as a consequence, promotes the creation of potential pathogenic organisms

Saisongkorh Watcharee

Robert Catherine

La Scola Bernard

Raoult Didier

Rolain Jean-Marc

Public Library of Science (PLOS)

 in Amoeba

Crossref

Evidence of Transfer by Conjugation of Type IV Secretion System Genes between Bartonella Species and Rhizobium radiobacter in Amoeba

A bacterial conjugation machinery recruited for pathogenesis.

A giant virus in amoebae.

Addiction modules and programmed cell death and antideath in bacterial cultures.

Amoebae/amoebal symbionts genetic transfers: lessons from giant viruses neighbours. Interovirol:

Automated discovery and phylogenetic analysis of new toxin-antitoxin systems.

Bacterial death by DNA gyrase poisoning.

Bacterial type IV secretion systems in human disease.

Bacterial type IV secretion: conjugation systems adapted to deliver effector molecules to host cells.

Bartonella rattaustraliani sp. nov., Bartonella queenslandensis sp. nov. and Bartonella coopersplainsensis sp. nov., identified in Australian rats.

Base calling of automated sequencer traces using Phred. I. Accuracy assessment.

Cloning, sequencing, and expression of three Bartonella henselae genes homologous to the Agrobacterium tumefaciens VirB region.

Complete genomic sequence of nitrogen-fixing symbiotic bacterium Bradyrhizobium japonicum USDA110.

Cutting edge: antibody-mediated cessation of hemotropic infection by the intraerythrocytic mouse pathogen Bartonella grahamii.

Detection by immunofluorescence assay of Bartonella henselae in lymph nodes from patients with cat scratch disease.

Direct visualization of horizontal gene transfer.

Diversifying selection and concerted evolution of a Type IV secretion system in Bartonella.

Egelman EH

Endosymbiosis in amoebae: Recently established endosymbionts have become required cytoplasmic components.

Functional divergence and horizontal transfer of type IV secretion systems.

Genetics and genetic manipulation in Francisella tularensis.

Genome analysis of microorganisms living in amoebae reveals a melting pot of evolution.

Genome sequence of Rickettsia bellii illuminates the role of amoebae in gene exchanges between intracellular pathogens.

Genomic analysis of Bartonella identifies type IV secretion systems as host adaptability factors.

Heterogeneity of susceptibility to fluoroquinolones in Bartonella isolates from Australia reveals a natural mutation in gyrA.

History of the ADP/ATP-translocase-encoding gene, a parasitism gene transferred from a Chlamydiales ancestor to plants 1 billion years ago.

Interaction between protein subunits of the type IV secretion system of Bartonella henselae.

Invasion and persistent intracellular colonization of erythrocytes. A unique parasitic strategy of the emerging pathogen Bartonella.

Lateral gene transfer between obligate intracellular bacteria: evidence from the Rickettsia massiliae genome.

Legionella dumoffii DjlA, a member of the DnaJ family, is required for intracellular growth.

Localization of TraC, a protein involved in assembly of the F conjugative pilus.

Massive comparative genomic analysis reveals convergent evolution of specialized bacteria.

Molecular characterization of resistance to macrolides in Bartonella henselae.

Network analysis structure genetic diversity in independent genetic worlds.

New connections in the prokaryotic toxinantitoxin network: relationship with the eukaryotic nonsense-mediated RNA decay system.

Programmed cell death in bacteria: proteic plasmid stabilization systems.

Programmed cell death in bacterial populations.

Run-off replication of host-adaptability genes is associated with gene transfer agents in the genome of mouse-infecting Bartonella grahamii.

The gene encoding the 17-kDa antigen of Bartonella henselae is located within a cluster of genes homologous to the virB virulence operon.

The genome sequence of Rickettsia felis identifies the first putative conjugative plasmid in an obligate intracellular parasite.

The genomic sequence of the accidental pathogen Legionella pneumophila.

The ins and outs of DNA transfer in bacteria.

The louse-borne human pathogen Bartonella quintana is a genomic derivative of the zoonotic agent Bartonella henselae.

The post-Darwinist rhizome of life.

The VirB type IV secretion system of Bartonella henselae mediates invasion, proinflammatory activation and antiapoptotic protection of endothelial cells.

The VirB/VirD4 type IV secretion system of Bartonella is essential for establishing intraerythrocytic infection.

Thirtyeight C-terminal amino acids of the coupling protein TraD of the F-like conjugative resistance plasmid R1 are required and sufficient to confer binding to the substrate selector protein TraM.

TraG-like proteins of type IV secretion systems: functional dissection of the multiple activities of TraG (RP4) and TrwB (R388).

Type IV secretion systems: tools of bacterial horizontal gene transfer and virulence.

Type IV secretion: intercellular transfer of macromolecules by systems ancestrally related to conjugation machines.

Type IV transporters of pathogenic bacteria.

VirE1 is a specific molecular chaperone for the exported single-stranded-DNA-binding protein VirE2 in Agrobacterium.

Evidence of Transfer by Conjugation of Type IV Secretion System Genes between Bartonella Species and Rhizobium radiobacter in Amoeba

Abstract

Similar works

Full text

Available Versions

Directory of Open Access Journals

Public Library of Science (PLOS)

Crossref