Detection of false-positive sera in contagious agalactia with a multiantigen ELISA and their elimination with a protein G conjugate.

In serology, lack of specificity can generally be attributed to cross-reactions between different pathogens with antigens bearing similar epitopes. During seroepidemiologic surveys of contagious agalactia of sheep caused by Mycoplasma agalactiae infection, numerous sera were analyzed by enzyme-linked immunosorbent assay (ELISA). A few sera reacted with various antigens coated on plates, including the well with no antigen. This reactivity was not due to cross-reactions as initially suspected, and these multipositive sera were designated false-positive sera. Elimination of this false positivity was not possible by using covalent ELISA plates or different rabbit anti-sheep IgG conjugates. Only conjugates using monoclonal antibodies or protein G were efficient in elimination of false positivities without reducing the true specific positive titers. No false-positive sera have been observed since the implementation of protein G conjugates in the serologic diagnosis of contagious agalactia by ELISA for the past 2 years.

Maedi-visna virus infection in sheep: a review.

The maedi-visna virus (MVV) is classified as a lentivirus of the retroviridae family. The genome of MVV includes three genes: gag, which encodes for group-specific antigens; pol, which encodes for reverse transcriptase, integrase, RNAse H, protease and dUTPase and env, the gene encoding for the surface glycoprotein responsible for receptor binding and entry of the virus into its host cell. In addition, analogous to other lentiviruses, the genome contains genes for regulatory proteins, i.e. vif, rev and tat. The coding regions of the genome are flanked by long terminal repeats (LTR) which play a crucial role in the replication of the viral genome and provide binding sites for cellular transcription factors. The organs targeted by MVV are, in descending order of importance, the lungs, mammary glands, joints and the brain. In these organs, the virus replicates in mature macrophages and induces slowly progressing inflammatory lesions containing B and T lymphocytes. The clinical signs of MVV infection, i.e. dyspnea, loss of weight, mastitis and arthritis, are related to the location of these lesions. Infection with MVV induces the formation of antibodies which can be detected by agar gel immunodiffusion, ELISA and the serum neutralization assay. As neither antiviral treatment nor vaccination is available, diagnostic tests are the backbone of most of the schemes implemented to prevent the spread of MVV. However, since current serological assays are still lacking in sensitivity and specificity, molecular biological methods are being developed permitting the detection of virus in peripheral blood, milk and tissue samples. Future research will have to focus on both the development of new diagnostic tests and a better understanding of the pathogenesis of MVV infection.

Priming with tat-deleted caprine arthritis encephalitis virus (CAEV) proviral DNA or live virus protects goats from challenge with pathogenic CAEV.

We previously reported that infection of goats with caprine arthritis encephalitis virus (CAEV) tat- proviral DNA or virus results in persistent infection, since the animals seroconverted and direct virus isolation from cultures of blood-derived macrophages was positive. In this study we wanted to determine whether goats injected with CAEV tat- proviral DNA or virus were protected against challenge with the pathogenic homologous virus and to investigate whether CAEV tat- was still pathogenic. All animals injected with CAEV tat- became infected as indicated by seroconversion and virus isolation. Challenge at 8 or 9 months postinfection demonstrated protection in four of four animals injected with CAEV tat- but did not in three of three mock-inoculated challenged goats. Challenge virus was undetectable in the blood macrophages of protected animals during a period of 6 or 10 months postchallenge. In two of four protected animals, however, we were able to detect the challenge wild-type virus by reverse transcriptase PCR on RNA directly extracted from synovial membrane cells surrounding the inoculation site. This result suggests that protection was achieved without complete sterilizing immunity. Animals injected with CAEV tat- and mock challenged developed inflammatory lesions in the joints, although these lesions were not as severe as those in CAEV wild-type-injected goats. These results confirm the dispensable role of Tat in CAEV replication in vivo for the establishment of infection and pathogenesis and demonstrate in another lentivirus infection model the efficacy of live attenuated viruses to induce resistance to superinfection.

Requirement of caprine arthritis encephalitis virus vif gene for in vivo replication.

Replication of vif-caprine arthritis encephalitis virus (CAEV) is highly attenuated in primary goat synovial membrane cells and blood-derived macrophages compared to the wild-type (wt) virus. We investigated the requirement for CAEV Vif for in vivo replication and pathogenicity in goats by intra-articular injection of either infectious proviral DNA or viral supernatants. Wild-type CAEV DNA or virus inoculation induced persistent infection resulting in severe inflammatory arthritic lesions in the joints. We were unable to detect any sign of virus replication in vif- CAEV DNA inoculated goats, while vif- CAEV virus inoculation resulted in the seroconversion of the goats. However, virus isolation and RT-PCR analyses on blood-derived macrophage cultures remained negative throughout the experiment as well as in joint or lymphoid tissues taken at necropsy. No pathologic lesions could be observed in joint tissue sections examined at necropsy. Goats inoculated with the vif- virus demonstrated no protection against a pathogenic virus challenge. These results demonstrate that CAEV Vif is absolutely required for efficient in vivo virus replication and pathogenicity and provide additional evidence that live attenuated lentiviruses have to establish a persistent infection to induce efficient protective immunity.

The caprine arthritis encephalitis virus tat gene is dispensable for efficient viral replication in vitro and in vivo.

Caprine arthritis encephalitis virus (CAEV) is a lentivirus closely related to visna virus and more distantly to other lentiviruses, such as human immunodeficiency virus. The genomes of visna virus and CAEV contain a tat gene encoding a protein able to weakly transactivate its own long terminal repeat, suggesting that transactivation may be a dispensable function for viral replication. Three different tat gene mutants of an infectious molecular clone of CAEV were used to study their replication after transfection or infection of primary goat synovial membrane cells and of blood-derived mononuclear cells or macrophages. Our results showed no difference between replication of the wild type and either the complete tat deletion mutant or the tat stop point mutant, whereas slower growth kinetics and lower levels of expression of the partial tat deletion mutant that of the wild type were obtained in these cells. Quantitative PCR and reverse transcription-PCR analyses of the different steps of a single replicative cycle revealed an identical pattern of retrotranscription, transcription, and viral production, whereas time course analysis demonstrated that the intracellular level of viral genomic RNA was affected by the partial tat deletion at later time points. We then compared the infectious properties of the wild-type and tat mutant viruses in vivo by direct inoculation of proviral DNAs into the joints of goats. All the animals seroconverted between 27 and 70 days postinoculation. Moreover, we were able to isolate tat mutant CAEV from blood-derived macrophages that was still able to infect synovial membrane cells in vitro. This study clearly demonstrates that the tat gene of CAEV is dispensable for viral replication in vitro and in vivo.

[Caprine arthritis-encephalitis: trial of an adjuvant vaccine preparation. I. Clinical and virological study]. / Arthrite-encéphalite caprine: essai d'une preparation vaccinale adjuvée--I. Etude clinique et virologique.

In purpose to protect goats against caprine arthritis encephalitis virus (CAEV), the first group of kids (I) was inoculated with purified, inactivated and adjuvant-treated virions, the second group (II) with adjuvant and the third one (III) with culture medium. 2-4 months later, the three groups were challenged with virulent CAEV by intraarticular route. On the clinical level, vaccinated and challenged kids show more early and severe arthritis than other groups. On the virological level, isolation of lentivirus from white blood cells and different organs is more important in group I than groups II and III. Therefore, vaccinations with inactivated and adjuvant-treated virions do not protect against a virulent challenge; there is an enhancement of lesions. We note that the adjuvant elicits a mild non-specific protection against virulent challenge.

[Caprine arthritis-encephalitis: trial of an adjuvant vaccine preparation. II. Study of the antibody response]. / Arthrite-encéphalite caprine: essai d'une preparation vaccinale adjuvée--II. Etude de la reponse anticorps.

In an experiment of vaccination against caprine arthritis encephalitis virus (CAEV), the antibody response in three groups of young goats was followed by AGIDT, ELISA, seroneutralization, western blot. Goats of group I, inoculated with inactivated virus mixed with adjuvant, showed a few weeks after vaccination a high antibody response, clearly enhanced after infectious intraarticular challenge. These antibodies did not protect against arthritis, which appeared more severe in this group. In the other groups (group II, control adjuvant, with the weakest clinical expression, group III, control tissue culture medium), the levels of circulating antibodies appeared much lower. No neutralizing antibodies could be detected during the whole experiment. A western blot analysis revealed mainly in group I a high antibody response against gp 135 antigen. The important immune reaction might be involved in enhancement of viral infectivity in this group.

Identification and subcellular localization of the Q gene product of visna virus.

The genome of the sheep visna lentivirus contains an open reading frame, Q, which has a coding potential of 230 amino acid residues. This paper reports the identification and the subcellular localization of the Q ORF-encoded protein detected in lysates of visna virus-infected sheep choroid plexus cells. Sera from sheep either experimentally or naturally infected with visna virus reacted with the bacterially synthesized Q protein indicating that the in vivo expressed Q product is immunogenic. Antibodies raised against a synthetic N-terminal peptide, reacted with either the bacterial Q or the in vitro translated Q protein as well as with the Q protein expressed during cellular infection. This 29 kDa protein is detectable late in the lytic viral cycle, i.e., 72 hr postinfection, and this expression correlates with the late transcription of its 4.8-kb mRNA. These results provide evidence for the first time that the Q ORF is a late gene of visna virus and that the Q protein is located in the cytosol compartment, without evidence of accumulation at the cell membrane, or in cell-free virion particles.

Subcellular localization of rev-gene product in visna virus-infected cells.

The 1.4-kb mRNA of visna lentivirus is expressed early during the lytic infection of sheep choroid plexus cell cultures. It encodes for visna early gene 1 (VEG1) product, since renamed rev gene product (or Rev), based on significant amino acid sequence homologies between this protein and the proteins of simian immunodeficiency virus of macaque and human immunodeficiency virus type 2. In this report, we examined the subcellular localization and time course appearance of the Rev protein in visna virus-infected cells. Immunoprecipitation assays of [35S]methionine-labeled cell lysates with antisera raised against the Rev protein revealed a polypeptide of 19 kDa (p19rev). This protein was predominant early in the viral replication cycle and accumulated preferentially in the cytoplasmic/membrane fraction of infected cells. Indirect immunofluorescence staining of infected cells confirmed the cytoplasmic location of visna Rev protein and could reveal in some stained cells a higher concentration of Rev at the cellular plasma membrane. The regulating protein, still present late in the viral lytic cycle, is packaged into mature viral particles along with the structural gag and env gene products.

[Caprine enzootic arthritis-encephalitis in France: epidemiological and experimental studies]. / L'arthrite-encéphalite enzootique caprine en France: recherches épidémiologiques et expérimentales.

In an epidemiological study on CAEV-induced caprine arthritis, the ELISA carried out on mixed sera appeared to be an efficient pointer to viral articular pathology in flocks; the breed and origin of goats, the selection of flocks with high milk production proved to be factors which favour viral arthritis, the serological diagnosis of which remains a flock diagnosis. In addition, in an experimental infection, only one type II caprine strain induced significant cases of arthritis; the disease could be reproduced more effectively by the intra-articular route than intravenously. Lastly, in a vaccination test followed by infectious CAEV challenge, two vaccinated goats showed more severe arthritis than did non vaccinated control goats. These observations emphasise the importance of the different viral strains, of the penetration route of the virus, of the repetition of infections and of the immune response in the induction of CAEV arthritis.

[Experimental studies on maedi-visna]. / Recherches expérimentales sur le maedi-visna.

In order to study pathogenicity of sheep lentiviruses, to obtain monospecific sera and to perfect ELISA, 3 experiments with different strains were carried out for 4 yr. In expt 1, one clone only of a French maedi-visna strain (564-79) elicits a clear seroconversion in inoculated sheep. In expt 2, K1514 is more immunogenic than K796 and PPV: intratracheal route seems more efficient than intracerebral route. Sheep infected by ts mutants (expt 3) are early positive as wild strain K796. Nevertheless, the level of positivity is less important than for the parental strain, suggesting that the defect of the ts mutants is not limiting their replication in vivo. An important result is the lack of clinical signs and anatomical and histopathological lesions, in spite of frequent isolations of virus from buffy coat cells. These results suggest that: different enhancing factors have to be taken in account in the apparition of clinical signs; all the clones are not infectious; viral infection might be effective with several types of virions.

Highly lytic and persistent lentiviruses naturally present in sheep with progressive pneumonia are genetically distinct.

Ovine and caprine lentiviruses share the capacity to induce slowly progressive and inflammatory diseases of the central nervous system (leukoencephalitis or visna), lungs (progressive pneumonia or maedi), and joints (arthritis) in their natural hosts. Studies on their replication indicated that ovine lentiviruses and caprine arthritis-encephalitis virus (CAEV) recently isolated in the United States establish persistent infection in ovine and caprine fibroblasts, whereas older prototype ovine lentiviruses such as Icelandic visna virus or American progressive pneumonia virus irreversibly lyse fibroblast cultures. Since all of the recent isolates were found to be persistent, Narayan et al. (J. Gen. Virol. 59:345-356, 1982) concluded that the highly lytic viruses were only tissue-culture-adapted strains. In the present report, we isolated new ovine lentiviruses from French sheep with naturally occurring progressive pneumonia which are either highly lytic (five isolates), as are the Icelandic strains of visna virus, or persistent (one isolate), as are CAEV or American persistent ovine lentiviruses. Protein and nucleic acid content analyses of these new highly lytic (type I) and persistent (type II) isolates indicated that type I and type II ovine lentiviruses were genetically distinct, type I and type II viruses being closely related to the Icelandic strains of visna virus and to CAEV, respectively. We conclude that (i) highly lytic ovine lentiviruses, such as the Icelandic prototype strains of visna virus and persistent lentiviruses more related to CAEV, are naturally present in the ovine species, and (ii) irreversible cell lysis induced by highly lytic viruses does not result from a tissue culture adaptation of field isolates that were originally persistent but is instead the consequence of a genetic content distinct from that of persistent viruses.

Lentiviruses are naturally resident in a latent form in long-term ovine fibroblast cultures.

Long-term ovine fibroblast cultures contain replicative-competent lentiviruses in a latent form. This in vitro phenomenon, never described previously for lentiviruses, was clearly demonstrated by activating the expression of latent viruses with various inducing cell treatments, some of which were efficient in inducing endogenous retroviruses or latent herpesviruses. Activated lentiviruses were highly lytic in ovine fibroblasts (type I), or they established persistent infections (type II) as described previously for field isolates from sheep with progressive pneumonia (Quérat et al., J. Virol. 52:671-678, 1984).

Precursor polypeptides to structural proteins of visna virus.

Visna virus is a retrovirus which replicates in fibroblast-like cells of the sheep choroid plexus through a lytic cycle. Visna virions contain three major low-molecular-weight proteins (p30, p16, and p14) which, together with the genomic RNA and several molecules of reverse transcriptase, constitute the core structure of the virions. The core is surrounded by an envelope containing a major glycoprotein (gp135). By analogy with the oncoviruses, these three groups of structural proteins (i.e., the internal proteins, the envelope glycoprotein, and the reverse transcriptase) are probably encoded by the gag, env, and pol genes, respectively. To elucidate the genetic organization of the visna virus genome and its expression, we studied the synthesis of viral proteins in infected sheep choroid plexus cells. Intracellular viral proteins were detected by immunoprecipitation of pulse-labeled cell extracts with monospecific sera raised against p30, p16, and gp135 and resolution of the proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Immunoprecipitation with anti-p30 and anti-p16 sera allowed the characterization of the 55,000-dalton polypeptide precursor to internal virion proteins p30, p16, and p14 (Pr55(gag)). Tryptic peptide mapping confirmed the precursor-product relationship between Pr55(gag) and the three internal proteins. In addition, a gag-related polypeptide of 150,000 daltons was also detected. This polypeptide, which was less abundant than Pr55(gag), is a likely precursor to the viral reverse transcriptase (Pr150(gag-pol)). Pr55(gag) and Pr150(gag-pol) are not glycosylated. The precursor related to major envelope protein gp135 is a glycosylated polypeptide with an average molecular weight of 150,000 (gPr150(env)). Pulse-chase experiments indicated that gPr150(env) matures into glycoprotein gp135 intracellularly; however, gp135 was never preponderant in cell extracts. The non-glycosylated from of gPr150(env), which accumulated in the presence of 2-deoxy-d-glucose, appeared as a polypeptide of about 100,000 daltons. These results indicated that visna virus codes for the largest non-glycosylated env-related precursor among all of the retroviruses and therefore probably contains the largest env gene.

[An ELISA test for detection of maedi-visna antibodies. Comparative study with gel immunodiffusion and complement-fixation test]. / Une technique ELISA pour la détection des anticorps anti-virus maedi-visna. Etude comparative avec l'immunodiffusion en gelose et la fixation du complement.

An indirect microELISA test was performed for detection of maedi-visna antibodies in ovine and caprine species. The antigen consisted in viral particles, highly purified by successive ultracentrifugations. By comparative testing of 934 sera in ELISA and gel immunodiffusion, we found a good correlation between these two tests, and moreover, ELISA revealed another 11.3% of positive samples. The precocity of this ELISA was shown by experimental infection of sheep with different strains of maedi-visna: positive sera were detected 7 weeks post-infection, instead 4-5 months with gel immunodiffusion. The complement fixation test was compared with gel immunodiffusion and was found the less sensitive. This ELISA test appeared to be satisfactory, and may be used for early diagnosis of maedi-visna infection.