Molecular characterization of native Australian trypanosomes in quokka (Setonix brachyurus) populations from Western Australia.

The quokka, Setonix brachyurus, is a vulnerable, small marsupial endemic to Western Australia. Blood samples were collected from quokkas from three different geographical locations; Two Peoples Bay, Bald Island and Rottnest Island. The overall prevalence of trypanosomes by nested PCR at the 18S ribosomal RNA gene was 57.3% (63/110) with prevalences of 91.4%, 85.3% and 4.9% respectively for Two Peoples Bay, Bald Island and Rottnest Island. Phylogenetic analysis conducted on 47 18S PCR positives identified two Trypanosoma copemani genotypes, with T. copemani genotype B, the most prevalent genotype infecting quokka populations from the three locations with an overall prevalence of 51.8% (24/47) compared to 34% for T. copemani genotype A (16/47). The overall prevalence of mixed T. copemani genotype A and B infections was 14.9% (7/47). Phylogenetic analysis of 26 quokka isolates at the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) locus, largely supported the 18S analysis but identified a mixed infection in one quokka isolate (Q4112-4117 from Two Peoples Bay). T. copemani genotype B has previously only been isolated from quokkas and the Gilbert's potoroo whereas T. copemani genotype A has a wide host range and may be pathogenic. Further work is required to determine the clinical impact of T. copemani on marsupial populations.

Investigation of the morphological diversity of the potentially zoonotic Trypanosoma copemani in quokkas and Gilbert's potoroos.

Trypanosomes are blood-borne parasites that can cause severe disease in both humans and animals, yet little is known of the pathogenicity and life-cycles of trypanosomes in native Australian mammals. Trypanosoma copemani is known to be infective to a variety of Australian marsupials and has recently been shown to be potentially zoonotic as it is resistant to normal human serum. In the present study, in vivo and in vitro examination of blood and cultures from Australian marsupials was conducted using light microscopy, immunofluorescence, scanning electron microscopy and fluorescence in situ hybridization. Promastigote, sphaeromastigote and amastigote life-cycle stages were detected in vivo and in vitro. Novel trypanosome-like stages were also detected both in vivo and in vitro representing an oval stage, an extremely thin stage, an adherent stage and a tiny round stage. The tiny round and adherent stages appeared to adhere to erythrocytes causing potential haematological damage with clinical effects similar to haemolytic anaemia. The present study shows for the first time that trypomastigotes are not the only life-cycle stages circulating within the blood stream of trypanosome infected Australian native marsupials and provides insights into possible pathogenic mechanisms of this potentially zoonotic trypanosome species.

Vaccination reduces the viral load and the risk of transmission of Jembrana disease virus in Bali cattle.

The efficacy of a tissue-derived vaccine, which is currently used in Indonesia to control the spread of Jembrana disease in Bali cattle, was determined by quantifying the viral load in plasma following experimental infection with Jembrana disease virus. Virus transmission is most likely to occur during the acute phase of infection when viral titers are greater than 10(6) genomes/ml. Vaccinated cattle were found to have a 96% reduction in viral load above this threshold compared to control cattle. This would reduce the chance of virus transmission as the number of days above the threshold in the vaccinated cattle was reduced by 33%. Viral loads at the onset and resolution of fever were significantly lower in the vaccinated cattle and immune function was maintained with the development of antibody responses to Env proteins within 10-24 days post challenge. There was, however, no significant reduction in the duration of the febrile period in vaccinated animals. The duration and severity of clinical parameters were found to be variable within each group of cattle but the quantification of viral load revealed the benefits of vaccinating to reduce the risk of virus transmission as well as to ameliorate disease.

Analysis of Jembrana disease virus replication dynamics in vivo reveals strain variation and atypical responses to infection.

Jembrana disease virus (JDV) is an acute lentiviral infection of Bali cattle in Indonesia. Data generated during a series of cattle infection experiments was examined and significant differences were identified in the mean plasma viral load on the first and second days of the febrile response in cattle infected with JDV(TAB/87) compared to those infected with JDV(PUL/01). The peak and total viral loads >or=10(6) genome copies/ml during the acute stage of the disease were significantly higher in JDV(TAB/87) infected cattle. JDV(PUL/01) infected cattle developed peak rectal temperatures earlier than the JDV(TAB/87) cattle but there were no differences in the duration of the febrile responses observed for the 2 groups of animals. The plasma viremia was above 10(6) genome copies/ml for almost 3 days longer in JDV(TAB/87) compared to JDV(PUL/01) infected cattle. Atypical responses to infection occurred in approximately 15% of experimentally infected animals, characterized by reduced viral loads, lower or absent febrile responses and absence of p26-specific antibody responses. Most of these cattle developed normal Tm-specific antibody responses between 4-12 weeks post-infection.

Recombinant Jembrana disease virus gag proteins identify several different antigenic domains but do not facilitate serological differentiation of JDV and nonpathogenic bovine lentiviruses.

In Indonesia, it is suspected that there are two bovine lentiviruses circulating in the cattle population: a pathogenic Jembrana disease virus (JDV), and a nonpathogenic bovine immunodeficiency-like virus (BIV). Both viruses cross-react antigenically and cannot be differentiated by current serological tests using JDV antigens. To identify possible type-specific epitopes, a series of recombinant protein constructs including the matrix, capsid and nucleocapsid proteins were produced from JDV gag and the expressed proteins were tested by Western blot using JDV and BIV hyperimmune sera. JDV matrix and truncated capsid proteins were recognised by both JDV and BIV hyperimmune sera indicating that there were multiple cross-reactive epitopes present in JDV gag. At least three epitopic regions were identified in these constructs, including the major homology region, by monoclonal antibody binding studies. JDV nucleocapsid recombinant protein was not recognised by either JDV or BIV hyperimmune sera and none of the recombinant gag proteins were able to differentiate between JDV positive sera from Jembrana disease endemic and Jembrana disease-free areas. Additionally, a 40 amino acid recombinant subunit protein encompassing the region recently found to contain an epitope unique to BIV [Zheng, L., Zhang, S., Wood, C., Kapil, S., Wilcox, G.E., Loughin, T.A., Minocha, H.C., 2001. Differentiation of two bovine lentiviruses by a monoclonal antibody on the basis of epitope specificity. Clin. Diagn. Lab. Immunol. 8, 283-287] was tested but was not recognised by either JDV positive sera from Jembrana disease-endemic or Jembrana disease-free areas.