Caprine Arthritis-encephalitis Viruses Research Articles

Expression analysis of lung miRNAs responding to ovine VM virus infection by RNA-seq

BackgroundMicroRNAs (miRNAs) are short endogenous, single-stranded, noncoding small RNA molecules of approximately 22 nucleotides in length. They regulate gene expression posttranscriptionally by silencing mRNA expression, thus orchestrating many physiological processes. The Small Ruminant Lentiviruses (SRLV) group includes the Visna Maedi Virus (VMV) and Caprine Arthritis Encephalitis (CAEV) viruses, which cause a disease in sheep and goats characterized by pneumonia, mastitis, arthritis and encephalitis. Their main target cells are from the monocyte/macrophage lineage. To date, there are no studies on the role of miRNAs in this viral disease.ResultsUsing RNA-seq technology and bioinformatics analysis, the expression levels of miRNAs during different clinical stages of infection were studied. A total of 212 miRNAs were identified, of which 46 were conserved sequences in other species but found for the first time in sheep, and 12 were completely novel. Differential expression analysis comparing the uninfected and seropositive groups showed changes in several miRNAs; however, no significant differences were detected between seropositive asymptomatic and diseased sheep. The robust increase in the expression level of oar-miR-21 is consistent with its increased expression in other viral diseases. Furthermore, the target prediction of the dysregulated miRNAs revealed that they control genes involved in proliferation-related signalling pathways, such as the PI3K-Akt, AMPK and ErbB pathways.ConclusionsTo the best of our knowledge, this is the first study reporting miRNA profiling in sheep in response to SRLV infection. The known functions of oar-miR-21 as a regulator of inflammation and proliferation appear to be a possible cause of the lesions caused in the sheep’s lungs. This miRNA could be an indicator for the severity of the lung lesions, or a putative target for therapeutic intervention.

Serosurvey of bluetongue, caprine arthritis-encephalitis (CAE) and Maedi-Visna in Barbary sheep (Ammotragus lervia) of a southern Brazilian zoo

ABSTRACT: Bluetongue (BT) is an infectious and non-contagious disease of compulsory notification which may affect domestic and wild ruminants, transmitted by Culicoides spp. midges. Despite the high morbidity and mortality in sheep, role of wild animals in the BT cycle remains unclear. Caprine arthritis-encephalitis (CAE) and Maedi-Visna virus (MVV) have been reportedly found in goats and sheep, but not described in wildlife species. Accordingly, serum samples from 17 captive Barbary sheep (Ammotragus lervia) from Curitiba zoo, southern Brazil, were tested for bluetongue, caprine arthritis-encephalitis (CAE) and Maedi-Visna viruses by agar gel immunodiffusion (AGID) and enzyme linked immunosorbent assay (ELISA). Antibodies for bluetongue were observed in 6/17 (35.3%) Barbary sheep by AGID test and in 7/17 (41.2%) by ELISA. All samples were negative for the presence of antibodies against caprine arthritis-encephalitis (CAE) and Maedi-Visna viruses. These findings indicate that Barbary sheep may be infected by bluetongue virus and act as wildlife reservoir in both captive and free-range environments.

Although Macrophage-Tropic Simian/Human Immunodeficiency Viruses Can Exhibit a Range of Pathogenic Phenotypes, a Majority of Isolates Induce No Clinical Disease in Immunocompetent Macaques

Unlike prototypical lentiviruses like visna and caprine arthritis-encephalitis viruses, which are mainly macrophage tropic (M-tropic), primate lentiviruses primarily target CD4+ T lymphocytes. We previously reported that during the late phase of highly pathogenic chimeric simian/human immunodeficiency virus (SHIV) infections of rhesus macaques, when CD4+ T cells have been systemically eliminated, high levels of viremia are maintained from productively infected macrophages. The availability of several different M-tropic SHIVs from such late-stage immunocompromised animals provided the opportunity to assess whether they might contribute to the immune deficiency induced by their T-cell-tropic parental viruses or possibly cause a distinct disease based on their capacity to infect macrophages. Pairs of rhesus monkeys were therefore inoculated intravenously with six different M-tropic SHIV preparations, and their plasma viral RNA loads, circulating lymphocyte subset numbers, and eventual disease outcomes were monitored. Only one of these six M-tropic SHIVs induced any disease; the disease phenotype observed was the typical rapid, complete, and irreversible depletion of CD4+ T cells induced by pathogenic SHIVs. An analysis of two asymptomatic monkeys, previously inoculated with an M-tropic SHIV recovered directly from alveolar macrophages, revealed that this inoculum targeted alveolar macrophages in vivo, compared to a T-cell-tropic virus, yet no clinical disease occurred. Although one isolate did, in fact, induce the prototypical rapid, irreversible, and complete loss of CD4+ T cells, indicating that M-tropism and pathogenicity may not be inversely related, the majority of M-tropic SHIVs induced no clinical disease in immunocompetent macaques.

Mutations increasing exposure of a receptor binding site epitope in the soluble and oligomeric forms of the caprine arthritis-encephalitis lentivirus envelope glycoprotein

The caprine arthritis-encephalitis (CAEV) and ovine maedi-visna (MVV) viruses are resistant to antibody neutralization, a feature shared with all other lentiviruses. Whether the CAEV gp135 receptor binding site(s) (RBS) in the functional surface envelope glycoprotein (Env) is protected from antibody binding, allowing the virus to resist neutralization, is not known. Two CAEV gp135 regions were identified by extrapolating a gp135 structural model that could affect binding of antibodies to the RBS: the V1 region and a short sequence analogous in position to the human immunodeficiency virus type 1 gp120 loop B postulated to be located between two major domains of CAEV gp135. Mutation of isoleucine-166 to alanine in the putative loop B of gp135 increased the affinity of soluble gp135 for the CAEV receptor(s) and goat monoclonal antibody (Mab) F7-299 which recognizes an epitope overlapping the gp135 RBS. The I166A mutation also stabilized or exposed the F7-299 epitope in anionic detergent buffers, indicating that the I166A mutation induces conformational changes and stabilizes the RBS of soluble gp135 and enhances Mab F7-299 binding. In contrast, the affinity of a V1 deletion mutant of gp135 for the receptor and Mab F7-299 and its structural stability did not differ from that of the wild-type gp135. However, both the I166A mutation and the V1 deletion of gp135 increased cell-to-cell fusion activity and binding of Mab F7-299 to the oligomeric Env. Therefore, the CAEV gp135 RBS is protected from antibody binding by mechanisms both dependent and independent of Env oligomerization which are disrupted by the V1 deletion and the I166A mutation, respectively. In addition, we found a correlation between side-chain β-branching at amino acid position 166 and binding of Mab F7-299 to oligomeric Env and cell-to-cell fusion, suggesting local secondary structure constraints in the region around isoleucine-166 as one determinant of gp135 RBS exposure and antibody binding.

The detection of proviral DNA by semi-nested polymerase chain reaction and phylogenetic analysis of Czech Maedi-Visna isolates based on gag gene sequences.

A semi-nested polymerase chain reaction (snPCR) for detecting proviral DNA of ovine lentivirus (OvLV) in peripheral blood mononuclear cells was developed. Primers for snPCR were situated within the gag gene of the Maedi-Visna virus (MVV) genome. A comparison between the snPCR and serological tests (agar gel immunodiffusion test, immunoblot) were performed using 98 ovine blood samples. Thirty (30.6%) of the 98 sheep examined had antibodies specific for the MVV. PCR showed 21 of them to be positive and nine seropositive animals to be PCR negative. Six of the 68 serologically negative sheep were found to be PCR positive, probably due to delayed seroconversion. The PCR amplification products of these six sheep were sequenced and subjected to phylogenetic analysis. The resulting phylogenetic tree of partial gag gene sequences confirmed that the ovine lentivirus genotype in the Czech Republic is more closely related to the prototype MVV isolates than to the caprine arthritis encephalitis viruses.

North American and French Caprine Arthritis-Encephalitis Viruses Emerge from Ovine Maedi-Visna Viruses

The full extent of genetic diversity among small ruminant lentiviruses (SRLVs), i.e., caprine arthritis encephalitis viruses (CAEVs) and maedi-visna viruses (MVVs), remains unknown. This is due in part to the fact that few sequences of CAEV are available. To contribute to this knowledge, gag, pol, and env nucleotide sequences from an SRLV named CA680 originating from a goat from western France were determined. This analysis revealed that this virus is closely related to the Cork and 63 CAEV American isolates. Mismatched amino acids between the CA680 virus and prototype CAEVs ranged from 6.7, 0.7, and 17.5% for gag, pol, and SU sequences, respectively. The differences between the CA680 virus and MVV prototypes ranged from 16.5, 12.5, and 32.3% for the protein sequences, respectively. A screening using a heteroduplex mobility assay (HMA) adapted to SRLVs revealed that 6 of 10 caprine virus field isolates were closely related to CA680, indicating that this latter isolate was a prototype of CAEVs common in the west of France. Phylogenetic trees drawn using CA, RT, or SU sequences of numerous SRLVs and rooted with EIAV sequences revealed that CA680 and CAEV prototypes, all infectious for goat, clustered in one group. From these HMA and phylogenetic analyses, it appears that U.S. and French caprine SRLVs form a clade that had emerged from a much more diverse group containing all SRLVs infectious for sheep. These ovine SRLVs form a more ancient group in which the EIAV is rooted.

Mononuclear phagocytes as targets, tissue reservoirs, and immunoregulatory cells in human immunodeficiency virus disease.

We have presented evidence in this review for the following: 1. Macrophages are likely the first cell infected by HIV. Studies document recovery of HIV into macrophages in the early stages of infection in which virus isolation in T cells is unsuccessful and detectable levels of antibodies against HIV are absent. 2. Macrophages are major tissue reservoirs for HIV during all stages of infection. Unlike the lytic infection of T cells, many HIV-infected macrophages show little or no virus-induced cytopathic effects. HIV-infected macrophages persist in tissue for extended periods of time (months) with large numbers of infectious particles contained within intracytoplasmic vacuoles. 3. Macrophages are a vector for the spread of infection to different tissues within the patient and between individuals. Several studies suggest a "Trojan horse" role for HIV-infected macrophages in dissemination of infectious particles. The predominant cell in most bodily fluids (alveolar fluid, colostrum, semen, vaginal secretions) is the macrophage. In semen, for example, the numbers of macrophages exceed those of lymphocytes by more than 20-fold (Wolf and Anderson 1988). 4. Macrophages are major regulatory cells that control the pace and intensity of disease progression in HIV infection. Macrophage secretory products are implicated in the pathogenesis of CNS disease and in control of viral latency in HIV-infected T cells. This litany of events in which macrophages participate in HIV infection in man parallels similar observations in such animal lentivirus infections as visna-maedi or caprine arthritis-encephalitis viruses. HIV interacts with monocytes differently than with T cells. Understanding this interaction may more clearly define both the pathogenesis of HIV disease and strategies for therapeutic intervention.

Caprine arthritis-encephalitis (CAE) and Maedi-Visna viruses detected by the polymerase chain reaction (PCR)

It may take several months before goats and sheep infected with lentiviruses develop measurable antiviral antibodies. During this period, virus may be isolated from infected animals but current cell culture techniques for the isolation and identification of goat and sheep lentiviruses are tedious and take several weeks to complete. Using the polymerase chain reaction, we show here that virus can be detected in infected cell cultures with high specificity and sensitivity. To demonstrate both CAE- and Maedi-Visna virus-specific DNA we utilized primers 20 base pairs long and framing 215 nucleotides of the gag gene (p28/p11 region) of Visna virus. DNA of Maedi-Visna and CAE viruses could be detected at 1 day post-infection in cultured sheep plexus and lamb carpal cells, respectively. This was 4 days before CAE viral proteins could be demonstrated by immunoblotting. The PCR was highly sensitive, allowing the detection of approximately one infected cell in a culture containing 10 6 cells. Our experiments indicate that the PCR exceeds the sensitivity of conventional detection methods for Maedi-Visna and CAE viruses. Experiments to adapt the PCR to material obtained from infectes animals are under way.

Evidence for interference, coinfections, and intertypic virus enhancement of infection by ovine-caprine lentiviruses

The ovine-caprine lentiviruses share nucleotide homology and serological properties in their gag-pol genes and gene products but constitute two distinct biological groups represented by ovine visna virus of Icelandic origin and by caprine arthritis-encephalitis and ovine progressive pneumonia viruses of U.S. origin. Two members of each group, visna 1514 and its antigenic variant LV1-1 in the first group and CAEV/CO and S93, a field isolate virus from a local arthritic sheep, in the second group, were examined in the present study in competitive-binding studies in fibroblast and macrophage cell cultures. The cultures were preinoculated with each of the four viruses and then reinoculated with either 1514 virus or CAEV/CO, labeled with [35S]methionine. Both 1514 and CAEV/CO caused homologous interference. LV1-1 and S93 viruses shared the interference patterns of 1514 and CAEV/CO, respectively. 1514 and LV1-1 did not interfere with binding of CAEV/CO. Similarly, CAEV/CO and S93 did not interfere with binding of 1514. Remarkably, certain combinations, such as S93 plus 1514, resulted in enhanced binding of the second virus. Other experiments showed that the enhancement in binding extended to enhancement in replication of the second virus. These latter data suggested that individual cells supported replication of both viruses. Further testing of this phenomenon showed that goats could be doubly infected with two noninterfering viruses, 1514 and CAEV/CO. The ability of noninterfering related lentiviruses to infect the same cell and also the same host animal may be important in the natural history of these viruses in providing ideal conditions for the development of new recombinant viruses.

Comparative Pathogenesis of Animal and Human Retrovirus Infections

ABSTRACT The human immunodeficiency virus (HIV) shares some structural and biological features with other lentiviruses such as maedi, visna, and equine infectious anemia viruses. Both the budding p...

Lentivirus-host interactions: lessons from visna and caprine arthritis-encephalitis viruses.

The biological properties of the ruminant animal lentiviruses, visna and caprine arthritis-encephalitis viruses, closely resemble those of their human counterparts, the human immunodeficiency viruses (HIV). All of these viruses are morphologically identical and are disseminated from host to host in nature during exchange of body fluids. Artificial conditions that favor excess exchange of such fluids precipitate epidemics by these viruses. The strategy of replication of the animal viruses in tissue culture and in vivo are very similar to that of the human virus. Virus replication is highly productive in tissue culture and leads to cytopathic effects characterized by fusion. In vivo, the rate of virus replication is restricted and lesions, suggestive of an immunopathological origin, develop after prolonged periods of subclinical infection. Similar to the animal viruses, the human viruses have a tropism for macrophages in vivo, and this leads somehow to a loss of T helper lymphocytes and proliferation of cytotoxic lymphocytes. In addition, the viruses are highly neurotropic and this results in acute fulminating disease in neonatal hosts and chronic encephalopathy in adults. Both animal and human viruses cause persistent infections and have similar strategies for eluding host immune responses. These include sequestration of neutralizing epitopes, induction of low titers of neutralizing antibodies, and antigenic drift during persistent infection. Despite close homology between genetic sequences of HIV-I and -II, these two viruses seem to have as much biological disparity from each other as does visna virus from caprine arthritis-encephalitis virus. The latter two viruses induce neutralizing antibodies that are highly strain specific and show no cross protection.(ABSTRACT TRUNCATED AT 250 WORDS)

Human T-cell lymphotropic virus type III shares sequence homology with a family of pathogenic lentiviruses.

The etiologic agent of the acquired immune deficiency syndrome, human T-cell lymphotropic virus type III (HTLV-III), has recently been shown to morphologically resemble and share sequence homology with visna virus, a pathogenic lentivirus. Molecular hybridization, heteroduplex mapping, and DNA sequence analyses were used to compare HTLV-III to other lentiviruses of domestic animals, including visna, caprine arthritis encephalitis, and equine infectious anemia viruses. Hybridization results showed that a substantial amount of sequence homology exists between each of these viruses and HTLV-III. In addition, a closer relationship was found between visna and caprine arthritis encephalitis viruses than for any of the other lentiviruses studied. These results, along with nucleotide and amino acid sequence comparisons, have been used in a comprehensive effort to derive a systematic relationship for lentiviruses and to provide further evidence for classifying HTLV-III with the Lentivirinae subfamily of retroviruses. This relationship predicts that similarities in biology and disease process can be expected between HTLV-III and other Lentivirinae members.

Antigenic Cross-reactivity between Caprine Arthritis-Encephalitis, Visna and Progressive Pneumonia Viruses Involves All Virion-associated Proteins and Glycoproteins

Antigenic relatedness between the virion-associated proteins of caprine arthritis-encephalitis, visna and progressive pneumonia viruses was examined. Antigenic cross-reactivity was assessed by immunoprecipitation of disrupted, radiolabelled virus with goat, sheep and rabbit antisera, followed by resolution of the immunoprecipitation products by SDS-polyacrylamide gel electrophoresis. The results indicate that antigenic cross-reactivity between the caprine and ovine virus isolates involves all of the major virion-associated proteins and glycoproteins. The common antigenic determinants exhibited by virion structural proteins are immunogenic in goats, sheep and rabbits.

Lack of neutralizing antibodies to caprine arthritis-encephalitis lentivirus in persistently infected goats can be overcome by immunization with inactivated Mycobacterium tuberculosis.

The pathogenesis of the persistent progressive diseases of sheep (visna-maedi) and goats (arthritis-encephalitis) is dependent on continuous replication of the causative lentiviruses. One subgroup of these viruses, Icelandic visna virus, accomplishes this form of replication by undergoing antigenic mutation. Mutant viruses arising late in the infection escape neutralization by antibodies directed to the parental virus. In contrast, we show here that viruses obtained from persistently infected sheep and goats with natural disease in this country do not induce virus-neutralizing antibodies, although antibodies to virus core proteins were produced. The lack of neutralizing antibodies was not overcome by hyperimmunization of animals with concentrated preparations of live or inactivated virus. Thus, failure to produce these specific antibodies was not due to lack of sufficient antigen or interference with the immune response because of the ability of these viruses to infect macrophages. The hyporesponsive state, however, was overcome by immunization of animals with virus and large amounts of inactivated Mycobacterium tuberculosis. Induction of agglutinating and neutralizing antibodies by this method was probably due to a unique form of antigen processing by macrophages activated by M. tuberculosis. Neutralizing antibodies were produced for the first time against the caprine arthritis-encephalitis virus by this method. These antibodies have similar biological properties to those induced by Icelandic visna virus. They belong to the immunoglobulin G1 subclass, they are effective against a narrow range of caprine arthritis-encephalitis viruses, and they identify (for the first time) antigenic variants among these caprine agents.