Browsing by Author "York, Denis Francis."

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A biochemical and immunological comparison of the Jaagsiekte and two related retroviruses.
(1987) York, Denis Francis.; Verwoerd, D. W.; Dennison, Clive.
Jaagsiekte is a contagious cancer affecting the lungs of sheep. Although the etiological agent is Jaagsiekte retrovirus (JSRV), two other retroviruses viz South African maedi visna virus ( SA - OMVV) and a novel Bovine retrovirus (BRV) have been associated with or implicated in the jaagsiekte disease complex. JSRV was sufficiently purified from lung rinse material using a Freon extraction, Percoll density gradient centrifugation and chranatography on a Sephacryl column, its polypeptide composition was studied by gel electrophoresis and its morphology observed electron microscopically. Monoclonal antibodies were made against purified preparations of the virus. Two hybridomas were isolated that produced MAbs which appear to be tumour cell specific. A third hybridoma, called 4A1O, produces antibodies considered to be viral specific. These MAbs have been used in the development of JS specific immunoassays. A cross reaction between JSRV and a polyclonal serum against Mason Pfizer monkey virus (MPMV) was confirmed and used in a Western blot technique to identify, monitor and differentiate JSRV from other viruses. During the study of JSRV it became apparent that another retrovirus was often present in JS infected lungs. This virus, referred to as SA - OM1V I, is a novel South African isolate of maedi visna virus (MVV). As SA - OM1V I has physicochemical characteristics similar to JSRV, it was often found in purified JSRV preparations. Being a retrovirus it is also detected by the reverse transcriptase assay which was the only method used to assay and monitor for JSRV during the early stages of our work. Using a Westen blot technique and sera against MVV and MPMV it was possible to simultaneously detect and differentiate JSRV from SA - OMVV I. A method was also developed whereby the two viruses could be separated from each other during purification. The information gained and techniques developed whilst studyiing JSRV were also used to isolate and characterize BRV. This novel virus originated from bovine cells that had been co-cultivated with white blood cells from an ox suffering from malignant catarrhal fever. Three out of four sheep inoculated with BRV developed JS. It therefore had to be· ascertained whether this virus was related to JSRV or not. The comparative study revealed that BRV was biochemically and morphologically quite different fran JSRV. Interestingly, it was shown that serum against MPMV cross reacted with a 32 kd protein of BRV indicating a serological relationship between JSRV, MPMV and BRV. The possible role of BRV in the etiology of jaagsiekte remains to be elucidated.
GB Virus C / Hepatitis G Virus (GBV-C/HGV) infection in KwaZulu Natal, South Africa : its diagnosis, distribution and molecular epidemiology.
(2003) Sathar, Mahomed Aslam.; York, Denis Francis.
Recently a new Flavivirus, GB Virus C also referred to as Hepatitis G virus (GBV-C/HGV) was identified in humans with indeterminate hepatitis . Whilst in non-African countries this discovery led to an enormous enthusiasm to elucidate an association with liver disease, very little was known about the prevalence and pathogenicity of GBV-C/HGV infection in KwaZulu Natal, South Africa, where Hepatitis B Virus (HBV) infection is endemic and infection with the Human immunodeficiency virus (HIV) is a catastropic health problem. Sera from patients with liver disease (chronic liver disease [n = 98]; alcoholic liver disease [n = 50]); high risk groups (haemodialysis patients [n = 70]; HIV positive mothers and their babies [n = 75]) and control groups (alcoholics without liver disease [n = 35] and blood donors from the four racial groups [n = 232]) were screened for GBV-C/HGV RNA and Anti-E2 antibodies by reverse transcription polymerase chain reaction (RT-PCR) and an enzyme linked immunosorbent assay (ELISA), respectively. Overall 43.9% (43/98) of patients with chronic liver disease; 60 % (30/50) of patients with alcoholic liver disease; 47.1% (33/70) of haemodialysis patients; 60% (21/35) of alcoholics without liver disease and 31.9% (74/232) of blood donors (Africans] 44/76; 5.9%); Asians (5/52; 9.6%); Whites (15/49; 30.6%) and "Coloureds" [mixed origin] (9/54; 16.6%)]) were exposed to GBV-C/HGV infection as determined by the detection of Anti-E2 &/or RNA in serum. There was a significant difference in the prevalence of GBV-C/HGV infection (RNA &/or anti E2) between African blood donors and the other racial groups (p < 0.001), between blood donors and haemodialysis patients (p = 0.02) and or patients with chronic liver disease (p =0.04). There was no significant difference in the prevalence of GBV-C/HGV between African blood donors (45/76, 59.2%) and alcoholics with and without liver disease (30/50, 60% and 21/35, 60%, respectively). Anti-E2 antibodies and GBV-C/HGV RNA were almost mutually exclusive. GBV-C/HGV infected dialysis patients tended to have had more transfusions (p = 0.03) and had a longer duration of dialysis than non infected patients, indicating that the majority of patients on maintenance haemodialysis acquire their GBV-C/HGV infection through the transfusions they receive. There was no evidence for in utero and/or intrapartum transmission of GBV-C/HGY. However, there is some mother-to-infant transmission of GBV-C/HGV, though it is very probable that in KZN GBV-C/HGV is transmitted by as yet undefined non-parenteral routes. Sequence and phylogenetic analysis of the 5' non-coding region (5' NCR) and E2 gene segments of the GBV-C/HGV genome identified an additional "genotype" (Group 5) of GBV-C/HGV that is distinct from all other known GBV-C/HGV sequences (Groups 1-4). Although there is a high prevalence of Group 5 GBV-C/HGV isolates in KZN, there was no significant difference in liver biochemistry between GBV-C/HGV infected and noninfected patients with liver disease or between blood donors in each of the four racial groups. There was no significant differences in CD4 (461.12 ± 163.28 vs 478.42 ± 181.22) and CD8 (680.83 ± 320.36 vs 862.52 ± 354.48) absolute cell counts between HIV positive patients co-infected with GBV-C/HGV and those not infected with GBV-C/HGV, respectively. However, significantly higher relative CD3 [80.0 ± 4.17% vs 70.99 ± 19.79%] (p = 0.015), gamma delta T cells (yLT) [3.22± 1.30% vs 2.15 ± 29.12%] (p = 0.052) and lower CD 30 [35.45 ± 17.86% vs 50.59 ± 9.20%] (p = 0.041) status were observed in GBV-C/HGV positive compared to GBV-C/HGV negative HIV infected patients, respectively. Although there is a high prevalence of novel Group isolates of GBV-C/HGV in KZN, the lack of elevated liver enzymes and clinical hepatitis in blood donors and haemodialysis patients suggests that GBV-C/HGV is not associated with liver disease. HBV and not GBV-C/HGV modifies the course of alcoholic liver disease. The relatively higher number of CD3 cells and increased yLT expression, together with a decrease in CD 30 cells tends to suggest an association with protection and or delayed progression of HIV disease in GBV-C/HGV infected patients. Whilst GBV-C/HGV is not associated with liver disease, it may be an important commensal in HIV infected patients.
An investigation into the serological and molecular diagnosis of Jaagsiekte Sheep Retrovirus (JSRV)
(2005) Padayachi, Nagavelli.; York, Denis Francis.
The Jaagsiekte Sheep Retrovirus (JSRV), an exogenous type B/D-retrovirus with about 10-15 endogenous counterparts in all normal sheep genomes, causes Jaagsiekte (JS) or ovine pulmonary adenocarcinoma (OPA), a contagious lung cancer of sheep. This sheep lung cancer has been identified as the best natural out-bred model that can be used to study human epithelial tumours. The close similarity between the pathology of the sheep disease and Human Bronchiolo-alveolar carcinoma are highly suggestive that the human disease could have a similar aetiology and mechanism to the sheep disease. However, in the case of sheep at the time of the study there was a need for an assay that could be used to screen for infected sheep. The isolation, cloning and subsequent sequencing of the first full-length exogenous and endogenous forms of JSRV contributed greatly towards JSRV research. Until recently the diagnosis of OPA was based mostly on clinical presentation with confirmation by micro and macro examination of the affected lungs by expert pathologists. In the absence of a specific humoral response no serology-based tests were available to diagnose the disease early in live animals. Control and management of the disease was primarily by regular flock inspections and prompt culling of the suspected cases. The objective of this research project was therefore to assess and investigate the serological and molecular diagnosis of JSRV. In an attempt to develop a serology based assay three proteins were identified as candidate diagnostic antigens, the group specific antigen JSRV p26, the transmembrane and the orf-X proteins. Genes coding for all three proteins were isolated, cloned and expressed. The JSRV p26 was sufficiently purified and its potential as a diagnostic antigen was evaluated in both a Western blot and ELISA. Our studies confirmed that there were no circulating antibodies to the JSRV capsid protein. Evidence suggested that the immune response was localised to the lungs. Lung lavage samples were therefore collected from infected and normal sheep and analysed for the presence of JSRV p26 antibodies using an in-house JSp26 peroxidase conjugate in an antigen capture assay. This assay lacked sensitivity but the results indicated that there was a specific localised immune response to JSRV in the lungs of OPA affected sheep. This was confirmed with an in-house antigen capture assay that we developed. JS antigen was detected in the lung and nasal fluid of affected sheep, but not in equivalent samples from normal sheep. Three molecular assays were investigated for their sensitivity and specificity, the LTR-gag PCR, U3/LTR hemi-nested PCR and the PCR that covered the V1/V2 region. The U3/LTR hemi-nested assay was 2 logs more sensitive than the LTR-gag PCR. However, it detected the endogenous JSRV5.9A1 loci at higher concentrations. This was overcome by designing a more specific primer P3M for the first step of the U3/LTR hemi-nested PCR and the use of the AmpliTaq Gold DNA polymerase. This assay proved to be both sensitive and specific enough to screen for the infectious exogenous JSRV in peripheral blood samples from individual sheep. It is now possible to use this assay to selectively eradicate the disease from a flock through a selective culling programme. Furthermore, the assay could be made quantitative by the inclusion of concentration standards.
Maedi-Visna virus : the development of serum and whole blood immunodiagnostic assays.
(1997) Boshoff, Christoffel Hendrik.; York, Denis Francis.; Conradie, Jan D.
This thesis describes the development of serum and whole blood immunodiagnostic assays for Maedi-Visna virus (MVV). All previously described recombinant MVV ELISA assays utilised either the core p25 or transmembrane (TM) proteins alone, or combined, but as individual proteins. The p25 and TM genes of MVV were cloned individually into the pGEX-2T expression vector. Both proteins were expressed as a combined fusion protein in frame with glutathione S-transferase (GST). The purified recombinant antigens (GST-TM and GST-TM-p25) were used to develop a MVV ELISA. Sera from 46 positive and 46 negative sheep were tested using the GST-TM and GST-TM-p25 ELISAs and a commercial p25 EIA kit. A two-graph receiver operating characteristic (TG-ROC) analysis program was used to interpret the data. The GST-TM-p25 ELISA was more sensitive than the commercial assay which is based on the p25 antigen alone and more specific than the GST-TM ELISA. The GST-TM-p25 ELISA showed a sensitivity and specificity of 100%. The human AIDS lentivirus transmembrane (TM) glycoprotein portion of the envelope viral protein has been identified as the antigen most consistently recognised by antibodies. There is suggestive evidence that the same applies to MVV as the GST-TM fusion protein, expressed in E. coli, has comparable sensitivity to the GST-TM-p25 fusion protein, but lacks specificity. However, due to the hydrophobic nature of the MVV TM protein, purification of the expressed fusion protein required lengthy purification protocols. This was despite the fact that only a truncated version of the TM protein was expressed. This prompted investigating an alternative expression system that could possibly circumvent the above mentioned problems. The yeast Pichia pastoris is known to be suitable for the high-level expression of heterologous proteins which are secreted into the culture supernatant. These features made P. pastoris an attractive host for the expression of the hydrophobic TM protein of MVV. However, limited success was achieved as only low expression levels were obtained and detection and quantification was only accomplished by means of ELISA. Evaluation of the diagnostic performance of the P. pastoris expressed MVV TM-polypeptide was performed using a panel of 36 confirmed negative and positive sera, and evaluated using a TG-ROC analysis programme, which yielded an equal Se and Sp of 83%. The use of a novel rapid immunoassay system, which allows the detection of circulating antibodies in whole blood, has been investigated for use as a MVV diagnostic assay. The central feature of this immunoassay lies in a monoclonal antibody against a glycophorin epitope present on all sheep erythrocytes. A Fab'-peptide conjugate was constructed by coupling a synthetic peptide, corresponding to a sequence from MVV TM protein, to the hinge region of the Fab' fragment of the antisheep erythrocyte antibody. Within the limited number of 10 seronegative and 10 seropositive samples the autologous red blood cell agglutination assay had a sensitivity of 90% and a specificity of 80%. Despite the limitations and difficulties encountered, the use of such rapid whole blood immunodiagnostic assays for MVV holds promise.
Molecular characterisation of endogenous loci related to jaagsiekte sheep retrovirus.
(2007) Hallwirth, Claus Volker.; York, Denis Francis.; Fan, Hung Y.
The study of retroviruses has been of pivotal significance to the field of biomedical science, where it has provided fundamental insights into the processes underlying both viral and non-viral carcinogenesis. Ovine pulmonary adenocarcinoma (OP A), a contagious lung cancer of sheep and goats, has emerged over the past three decades as an invaluable model of human epithelial cancers. It is one of the very few animal models of retrovirus induced neoplasia of epithelial tissues, whereas most other such animal models of human cancers pertain to the haematopoietic system. OP A represents a unique, naturally occurring, inducible, outbred animal model of peripheral lung carcinomas, and is caused by a betaretrovirus - jaagsiekte sheep retrovirus (JSRV) - that is receiving increasing attention in the fields of retrovirology and lung cancer research. JSRV exists in two highly homologous, yet molecularly distinct forms. The first is an exogenous form of the virus that is transmitted horizontally from one animal to another. This form is infectious and the direct cause of OP A. The other is an endogenous form, 15 to 20 proviral copies of which reside benignly in the genome of sheep and are transmitted vertically from one generation to the next. At the time this study commenced, no knowledge existed regarding the underlying pathogenic mechanism by which JSRV causes OPA. Even though the nucleotide sequence of exogenous JSRV had been elucidated seven years earlier, only limited sequence information was available on endogenous JSRVs. With a view towards identifying genetic regions or elements within exogenous JSRV that could potentially be implicated in its pathogenic function, this study began with the cloning of the first three full-length endogenous JSRV loci ever isolated from sheep. The DNA sequences of these full-length endogenous JSRV loci were determined and comprehensively analysed. Comparison with exogenous JSRV isolates revealed that the two forms of the virus are highly homologous, yet can be consistently distinguished in three short regions within the coding genes. Two of these reside in the gag gene, and one at the end of the env gene. These regions were named the variable regions (VRs) of sheep betaretroviruses. The JSRV VR3 in env was linked by our collaborators to the virus's ability to transform cells in tissue culture. The effects and biological significance of VRI and VR2 in gag are subtler and more difficult to determine. After identifying these regions, it became the objective of this study to develop relevant molecular tools that could be used to discern the significance of these variable regions in vivo, and to characterise these tools in vitro to assess their suitability for in vivo studies. The development of these tools entailed the design of a novel strategy that was implemented to precisely substitute the endogenous VRI and VR2 (individually and in combination) into an infectious molecular clone of exogenous JSRV. These chimeric constructs were shown to support retroviral particle release into the supernatant of transiently transfected cells in tissue culture. These particles were confirmed by independent experiments to have arisen specifically from transfection with the chimeric clones. Finally, the particles were shown to be capable of infecting cultured cells and of productively integrating their genomes into those of their host cells, rendering these particles fully competent retroviruses that can be used in the context of in vivo studies to determine the biological significance of VRI and VR2. This study has made a significant contribution to the further development of the OP A / JSRV model system of human epithelial lung cancers. It has also led to the design of a molecular substitution strategy that can be adapted to introduce any genetic region into a cloned DNA construct, regardless of the degree - or lack of interrelation - of the two DNA sequences, thereby creating a highly versatile molecular biological tool.
Molecular diagnosis and typing of HTLV-I in KwaZulu-Natal.
(1998) Tarin, Michelle Lucille.; York, Denis Francis.; Bhigjee, Ahmed Iqbal.
Two areas of the HTLV-I genome were targeted for an in-house molecular diagnostic test, namely the pol and env regions. The pol primers proved the most sensitive (100%)and specific (100%). Amplification using the env primer pair was not reproducible, and was not pursued further. The AmpliSensor assay (Acugen Systems, Lowell, MA) was also tested. The assay was very specific, but not as sensitive as our in-house PCR. To investigate the predominant HTLV-I subtype in the region, a 1535 by env gene was isolated from peripheral blood obtained from five local HTLV-I seropositive patients. Four of the patients presented with HAM/TSP, and the fifth presented with a skin disease. Nucleotide sequencing of the amplified products revealed the local strains to be very conserved, differing by 0.1% to 0.9% among themselves. No apparent difference was noted for the two clinical manifestations. Phylogenetic analysis was performed using repesentative strains from around the world. The local strains clearly fell within the cosmopolitan subtype. The local strains were most closely related to the North American strains suggesting an unexpected link between the two countries.