Rhodococcus equi

From Infogalactic: the planetary knowledge core
Jump to: navigation, search
Rhodococcus equi
Scientific classification
Kingdom:
Phylum:
Class:
Order:
Suborder:
Family:
Genus:
Species:
Rhodococcus equi

Magnusson 1923) Goodfellow & Alderson 1977

Lua error in Module:Taxonbar/candidate at line 22: attempt to index field 'wikibase' (a nil value).

Rhodococcus equi is a Gram-positive coccobacillus bacterium. The organism is commonly found in dry and dusty soil and can be important for diseases of domesticated animals (horses and goats). The frequency of infection can reach near 60%.[1] R. equi is an important pathogen causing pneumonia in foals. Since 2008, R. equi has been known to infect wild boar and domestic pigs.[2] In addition, R. equi can infect humans. At-risk groups are immunocompromised people, such as HIV-AIDS patients or transplant recipients. Rhodococcus infection in these patients resemble clinical and pathological signs of pulmonary tuberculosis. It is facultative intracellular.[3]

Taxonomically, R. equi has been categorized as Prescottia equi,Corynebacterium equi, Bacillus hoagii, Corynebacterium purulentus, Mycobacterium equi, Mycobacterium restrictum, Nocardia restricta, and Proactinomyces restrictus.

Hosts

Virulence

The most common route of infection in horses is likely via inhalation of contaminated dust particles. Inhaled virulent strains of R. equi are phagocytosed by alveolar macrophages. During normal phagocytosis, bacteria are enclosed by the phagosome, which fuses with the lysosome to become a phagolysosome. The internal environment of the phagolysosome contains nucleases and proteases, which are activated by the low pH of the compartment. The macrophage produces bacteriocidal compounds (e.g., oxygen radicals) following the respiratory burst. However, like its close relative Mycobacterium tuberculosis, R. equi prevents the fusion of the phagosome with the lysosome and acidification of the phagosome.[4][5][6] Additionally, the respiratory burst is inhibited. This allows R. equi to multiply within the phagosome where it is shielded from the immune system by the very cell that was supposed to kill it.[7] After about 48 hours, the macrophage is killed by necrosis, not apoptosis.[8] Necrosis is pro-inflammatory, attracting additional phagocytic cells to the site of infection, eventually resulting in massive tissue damage.

Virulence plasmid

All strains isolated from foals and the majority of human, cattle, and pig isolates contain a large plasmid. This plasmid has been shown to be essential for infection of foals, and presumably plays a similar role for infection of other hosts, although this has not been established yet. Strains that lack the virulence plasmid are unable to proliferate in macrophages. This virulence plasmid has been characterised in detail from equine and porcine strains, although only the former has been functionally characterised.[9][10] These circular plasmids consist of a conserved backbone responsible for replication and bacterial conjugation of the plasmid. This portion of the plasmid is highly conserved and found in nonpathogenic Rhodococci plasmids. In addition to the conserved region, the virulence plasmids contain a highly variable region that has undergone substantial genetic rearrangements, including inversion and deletions. This region has a different GC-content from the rest of the plasmid, and is flanked by genes associated with mobile genetic elements. It is therefore assumed to be derived from a different bacterial species than the backbone of the plasmid via lateral gene transfer.

Pathogenicity island

The variable region of the virulence plasmid contain genes that are highly expressed following phagocytosis of R. equi by macrophages.[11] This variable region is believed to be a pathogenicity island that contains genes essential for virulence.

A hallmark of the pathogenicity island (PAI) is that many genes within it do not have homologues in other species. The most notable of these are the virulence-associated protein (vap) genes. All foals infected with R. equi produce high levels of antibodies specific for vapA, the first vap gene to be characterised. Deletion of vapA renders the resulting strain avirulent.[12] In addition to vapA, the PAI encodes a further five full-length vap homologues, one truncated vap gene, and two vap pseudogenes. The porcine PAI contains five full-length vap genes, including the vapA homologue, vapB. In addition to these unique genes, the PAI contains genes that have a known function, in particular two regulatory genes encoding the LysR-type regulator VirR and the response regulator Orf8. These two proteins have been shown to control expression of a number of PAI genes including vapA.[13] Other genes have homology to transport proteins and enzymes. However, the functionality of these genes or how the proteins encoded within PAI subvert the macrophage has not yet been established.

References

  1. G. Muscatello, D. P. Leadon, M. Klay, A. Ocampo-Sosa, D. A. Lewis, U. Fogarty, T. Buckley, J. R. Gilkerson, W. G. Meijer, and J. A. Vázquez-Boland. (2007) Rhodococcus equi infection in foals: the science of 'rattles'. Equine Vet.J. 39:470-478. In: PMID 17910275
  2. Makrai, L. et al. (2008): Isolation and characterisation of Rhodococcus equi from submaxillary lymph nodes of wild boars (Sus scrofa). In: Vet Microbiol. PMID 18499361 doi:10.1016/j.vetmic.2008.04.009
  3. Lua error in package.lua at line 80: module 'strict' not found.
  4. K. von Bargen, K., M. Polidori, U. Becken, G. Huth, J.F. Prescott, A. Haas (2009) Rhodococcus equi virulence-associated protein A is required for diversion of phagosome biogenesis but not for cytotoxicity. Infect Immun 77: 5676-5681, PMID 19797071
  5. E. Fernandez-Mora, M. Polidori, A. Lührmann, U.E. Schaible, A. Haas (2005) Maturation of Rhodococcus equi-containing vacuoles is arrested after completion of the early endosome stage. Traffic 6: 635-653
  6. T. Sydor, K. von Bargen, F.F. Hsu, G. Huth, O. Holst, J. Wohlmann, U. Becken, T. Dykstra, K. Söhl, B. Lindner, J.F. Prescott, U.E. Schaible, O. Utermöhlen, A. Haas (2013) Diversion of phagosome trafficking by pathogenic Rhodococcus equi depends on mycolic acid chain length, Cell Microbiol. 15: 458-473
  7. M. K. Hondalus and D. M. Mosser. Survival and replication of Rhodococcus equi in macrophages. Infect.Immun. 62:4167-4175, 1994. In: PMID 7927672
  8. A. Lührmann, N. Mauder, T. Sydor, E. Fernandez-Mora, J. Schulze-Luehrmann, S. Takai, and A. Haas. Necrotic death of Rhodococcus equi-infected macrophages is regulated by virulence-associated plasmids. Infect.Immun. 72 (2):853-862, 2004. In: PMID 14742529
  9. M. Letek, A. A. Ocampo-Sosa, M. Sanders, U. Fogarty, T. Buckley, D. P. Leadon, P. Gonzalez, M. Scortti, W. G. Meijer, J. Parkhill, S. Bentley, and J. A. Vázquez-Boland. Evolution of the Rhodococcus equi vap pathogenicity island seen through comparison of host-associated vapA and vapB virulence plasmids. J.Bacteriol. 190 (17):5797-5805, 2008. In: PMID 18606735
  10. S. Takai, S. A. Hines, T. Sekizaki, V. M. Nicholson, D. A. Alperin, M. Osaki, D. Osaki, M. Nakamura, K. Suzuki, N. Ogino, T. Kakuka, H. Dan, and J. F. Prescott. DNA sequence and comparison of virulence plasmids from Rhodococcus equi ATCC 33701 and 103. Infect.Immun. 68:6840-6847, 2000. In: PMID 11083803
  11. J. Ren and J. F. Prescott. Analysis of virulence plasmid gene expression of intra-macrophage and in vitro grown Rhodococcus equi ATCC 33701. Vet.Microbiol. 94 (2):167-182, 2003. In: 12781484
  12. S. Jain, B. R. Bloom, and M. K. Hondalus. Deletion of vapA encoding Virulence Associated Protein A attenuates the intracellular actinomycete Rhodococcus equi. Mol.Microbiol 50 (1):115-128, 2003. In: PMID 14507368
  13. D. A. Russell, G. A. Byrne, E. P. O'Connell, C. A. Boland, and W. G. Meijer. The LysR-Type transcriptional regulator VirR is required for expression of the virulence gene vapA of Rhodococcus equi ATCC 33701. J.Bacteriol. 186:5576-5584, 2004. In: PMID 15317761

Further reading

  • Monika Venner und Erich Klug: Die Rhodococcus-equi-Pneumonie beim Fohlen: Diagnose, Therapie, Prophylaxe In: Pferde spiegel Nummer 4, 2005. Seiten 155-158 PDF
  • J. Ashour and M. K. Hondalus: Phenotypic mutants of the intracellular actinomycete Rhodococcus equi created by in vivo Himar1 transposon mutagenesis. In: Journal of Bacteriology. Volume 185, Nummer 8, April 2003. Seiten 2644-2652. doi:10.1128/JB.185.8.2644-2652.2003
  • A. Triskatis: Semiquantitative Bestimmung von Antikörpern gegen Rhodococcus equi in Serum und Klolostrum bei Stuten und Fohlen mittels ELISA und der Vergleich mit Befunden der Lungenuntersuchung PDF
  • Letek M et al.: Evolution of the Rhodococcus equi vap Pathogenicity Island Seen through Comparison of Host-Associated vapA and vapB Virulence Plasmids. In: Journal of Bacteriology. Volume 190, Number 17, September 2008. 5797–5805.
  • G. Muscatello, D. P. Leadon, M. Klay, A. Ocampo-Sosa, D. A. Lewis, U. Fogarty, T. Buckley, J. R. Gilkerson, W. G. Meijer, and J. A. Vázquez-Boland. (2007) Rhodococcus equi infection in foals: the science of 'rattles'. Equine Vet. J. 39:470-478.