Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-22T07:40:40.362Z Has data issue: false hasContentIssue false
  • English
  • Français

Bungowannah virus – a probable new species of pestivirus – what have we found in the last 10 years?

Published online by Cambridge University Press:  08 June 2015

P. D. Kirkland ,
A. J. Read ,
M. J. Frost  and
D. S. Finlaison
P. D. Kirkland*
Affiliation:
Virology Laboratory, Elizabeth Macarthur Agriculture Institute, PMB 4008 Narellan 2567 NSW, Australia
A. J. Read
Affiliation:
Virology Laboratory, Elizabeth Macarthur Agriculture Institute, PMB 4008 Narellan 2567 NSW, Australia
M. J. Frost
Affiliation:
Virology Laboratory, Elizabeth Macarthur Agriculture Institute, PMB 4008 Narellan 2567 NSW, Australia
D. S. Finlaison
Affiliation:
Virology Laboratory, Elizabeth Macarthur Agriculture Institute, PMB 4008 Narellan 2567 NSW, Australia
*
*Corresponding author. E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Bungowannah virus was discovered following an outbreak of stillbirths and sudden death in young pigs. Affected animals consistently showed a myocardopathy with signs of cardiac failure. After virus isolation and PCR investigations were unsuccessful, direct fetal inoculation was undertaken. Nucleic acid purified from serum from infected fetuses was subjected to sequence-independent single-primer amplification and nucleic acid sequencing. Sequences consistent with a pestivirus were obtained. The entire genome was identified but was genetically remote from the recognized pestivirus species. This virus was not recognized by pan-pestivirus reactive monoclonal antibodies but was subsequently detected in cell cultures by immunoperoxidase staining using convalescent sow serum. Experimental infections of sows at different stages of gestation reproduced the myocarditis syndrome. Pre-weaning losses of 70 and 29% were observed following infection at days 35 and 90, respectively. Piglets infected at day 35 were shown to be persistently infected, while chronic infections were observed after fetal infection at day 55. Chronically infected piglets showed growth retardation and were viremic for up to 7 months. Myocarditis was associated with infection in late gestation (day 90). Non-pregnant sheep and cattle have been experimentally infected but with no evidence of disease. Infection of pregnant cattle in early gestation resulted in both maternal and fetal infection, but all infected fetuses mounted an antibody response to the virus. Analysis of the nucleic acid sequence confirmed that Bungowannah has a number of changes not observed in other pestiviruses. Genes encoding some of the structural proteins remain fully functional when inserted into a bovine viral diarrhea virus (BVDV) backbone. Cell culture-based studies have shown that Bungowannah virus will grow in cells extending from humans to bats as well as farm animals.

Keywords

Bungowannah virusmyocarditispigsnovel pestivirus
Type
Review Article
Information
Animal Health Research Reviews , Volume 16 , Issue 1 , June 2015 , pp. 60 - 63
Copyright
Copyright © Cambridge University Press 2015 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Finlaison, DS (2010). Studies of the porcine myocarditis syndrome. PhD Thesis, University of Sydney, NSW, Australia.Google Scholar
Finlaison, DS, King, KR, Frost, MJ and Kirkland, PD (2009). Field and laboratory evidence that Bungowannah virus, a recently recognised pestivirus, is the causative agent of the porcine myocarditis syndrome (PMC). Veterinary Microbiology 136: 259265.CrossRefGoogle Scholar
Finlaison, DS, Cook, RW, Srivastava, M, Frost, MJ, King, KR and Kirkland, PD (2010). Experimental infections of the porcine foetus with Bungowannah virus, a novel pestivirus. Veterinary Microbiology 144: 3240.CrossRefGoogle Scholar
Finlaison, DS, King, KR, Gabor, M and Kirkland, PD (2012). An experimental study of Bungowannah virus infection in weaner aged pigs. Veterinary Microbiology 160: 245250.CrossRefGoogle ScholarPubMed
Kirkland, PD, Frost, MJ, Finlaison, DS, King, KR, Ridpath, JF and Gu, X (2007). Identification of a novel virus in pigs – Bungowannah virus: a possible new species of pestivirus. Virus Research 129: 2634.CrossRefGoogle Scholar
Kirkland, PD, Frost, MJ, King, KR, Finlaison, DS, Hornitzky, CL, Richter, M, Reimann, I, Dauber, M, Schirrmeier, H, Beer, M and Ridpath, JF (2014). Genetic and antigenic characterisation of Bungowannah virus, a novel pestivirus. Veterinary Microbiology (submitted)Google Scholar
McOrist, S, Thornton, E, Peake, A, Walker, R, Robson, S, Finlaison, D, Kirkland, P, Reece, R, Ross, A, Walker, K, Hyatt, A and Morrissy, C (2004). An infectious myocarditis syndrome affecting late-term and neonatal piglets. Australian Veterinary Journal 82: 509511.CrossRefGoogle ScholarPubMed
Read, AJ, Finlaison, DS, Frost, MJ, King, KR, Gu, X and Kirkland, PD (2011). Bungowannah virus – a novel pestivirus of pigs. Is it a threat to other species? In: 8th ESVV Pestivirus Symposium, 25–28 September 2011, Hannover, Germany.Google Scholar
Richter, M, Reimann, I, Wegelt, A, Kirkland, PD and Beer, M (2011). Trans-complementation studies with the novel “Bungowannah” virus support the classification into the genus pestivirus and provide new insights in the compatibility of pestivirus proteins. Virology 418: 113122.Google Scholar
Richter, M, Konig, P, Reimann, I and Beer, M (2014). Npro of Bungowannah virus exhibits the same antagonistic function in the IFN induction pathway than that of other classical pestiviruses. Veterinary Microbiology 168: 340347.CrossRefGoogle ScholarPubMed