Biochemical and immunological characterization of the major structural proteins of feline immunodeficiency virus.

Feline immunodeficiency virus (FIV) structural proteins were identified using sera obtained from experimentally inoculated cats. Proteins analysed by both radioimmunoprecipitation and Western blotting were specific for FIV infection and failed to cross-react with either antisera to feline leukaemia virus of feline syncytium-forming virus. Western blot analysis of purified virus revealed immunoreactive proteins with apparent Mr of 65K, 50K, 40K, 32K, 24K, 15K and 10K. The major core structural proteins of the virus were isolated by reverse phase HPLC and the aminoterminal sequences of p10 and p24 were determined. Monoclonal antibodies specific for p24 suggested the presence of a precursor protein that could be detected in 35[S]methionine/cysteine-labelled, virus-infected cell extracts. This putative precursor protein possessed an apparent Mr of 50K (Pr50gag). Further analysis revealed the presence of two additional proteins of 130K and 40K. Experiments utilizing tunicamycin, endoglycosidase H and glycopeptidase F revealed that p130 and p40 exhibited properties characteristic of glycoproteins. Our studies also indicated that FIV is immunologically related to other lentiviruses.

Intracellular proteins of feline immunodeficiency virus and their antigenic relationship with equine infectious anaemia virus proteins.

Feline immunodeficiency virus (FIV) grown in cat lymphocyte and thymocyte cultures was labelled with L-[35S]methionine or [3H]glucosamine and virus-coded proteins were identified using immunoprecipitation. Polypeptides with apparent Mr values of 15K, 24K, 43K, 50K, 120K and 160K were detected. An additional polypeptide of 10K was detected by Western blot analysis. The two highest Mr species sometimes appeared as one band, of which only the 120K polypeptide was glycosylated. In the presence of tunicamycin gp120 was no longer detectable and a non-glycosylated precursor of 75K was found instead. Pulse-chase experiments suggested that the smaller polypeptides p24 and p15 are cleavage products of both p160 and p50. Western blot analysis using a rabbit serum directed against p26 of equine infectious anaemia virus (EIAV) and an anti-EIAV horse serum from a field case of infection revealed a cross-reactivity with p24 of FIV. Cat sera collected late after experimental FIV infection recognized p26 of EIAV, indicating a reciprocal cross-reactivity.

[Neurotoxicity in mice due to cysteine-rich parts of visna virus and HIV-1 Tat proteins]. / Neurotoxicité chez la souris de portions riches en cystéines des protéines Tat du virus visna et de VIH-1.

The trans-activating visna virus and HIV-1 Tat proteins share, at their amino-acid sequence level, a significant 60% analogy on 17 consecutive residues. These homologous sequences are also found in a part of the short neurotoxin sequence from snake venom. Synthetic peptides representative of the two analogous viral sequences are, after intracerebroventricular injection at doses of 200 micrograms per 20 g mouse, responsible for the death of the injected animal in few hours. The HIV-1 recombinant Tat protein has the same effect. Such observation suggests a direct role of the Tat lentiviral protein in the origin of the neurologic effects associated with visna and HIV-1 infections.

A double labeling technique for performing immunocytochemistry and in situ hybridization in virus infected cell cultures and tissues.

This report describes a combined immunocytochemical and in situ hybridization procedure which allows visualization of cellular or viral antigens and viral RNA in the same cell. Cultures infected with visna or measles virus were fixed in periodate-lysine-paraformaldehyde-glutaraldehyde, stained by the avidin-biotin-peroxidase technique using antibodies to viral or cellular proteins and then incubated with radiolabeled specific DNA probes (in situ hybridization). The immunoperoxidase stain was preserved through the hybridization procedure. Nonspecific 'sticking' of probes over peroxidase stained cells was prevented by incorporation of 0.1% Triton X-100 into the hybridization solution and the post-hybridization washes. The in situ hybridization signal (silver grains/cell) on peroxidase-stained cells was reduced relative to hybridization with unstained cells. The double labeling technique was also applied to sections of paraffin-embedded tissues from a sheep infected with visna virus and mice infected with the HNT strain of measles virus. Visna virus RNA was detected in immunocytochemically identified macrophages in the synovium. A greater number of these cells had viral RNA than had viral protein. In measles virus-infected brains viral RNA was detected only in cells with viral protein. This technique provides a new approach to the study of viral pathogenesis by: identifying the types of cells which are infected in the host and identifying points of blockade in the virus life cycle during persistent infections.

Intracellular ribonucleoprotein complexes of visna virus are infectious.

Sheep choroid plexus cells infected with visna virus produce intracytoplasmic viral ribonucleoprotein complexes with sedimentation values of 120S to 200S and buoyant densities of 1.29 to 1.32 g/cm3. These ribonucleoprotein complexes display an endogenous RNA-directed DNA polymerase activity and contain all of the species of RNA associated with polysomes. An analysis of the polypeptides present in the ribonucleoproteins allowed us to identify the mature internal virion core proteins and their precursor, Pr55gag, as well as the glycosylated envelope precursor gPr150env and small amounts of mature glycoprotein gp135. Ultracentrifugation-purified ribonucleoproteins could infect sheep choroid plexus cells and led to a normal lytic cycle with virus production. Our results suggest that visna virus can propagate by means of intracellular infectious particles.

Morphological and immunological comparison of caprine arthritis encephalitis and ovine progressive pneumonia viruses.

Caprine arthritis encephalitis virus (CAEV) causes a variety of pathological conditions ranging from mild to very severe and from acute to chronic, depending upon the age of initial infection and other variables. Although the virus has been reported to have properties of characteristic of retroviruses and to be related to maedi-visna virus (also called progressive pneumonia virus [PPV]), relatively little information about its morphological and immunological characteristics has been reported. We describe the morphological features of CAEV replicating in cultured caprine cells. Although the virus replicates slowly and very little virus is released from productively infected cells, it is apparent that the morphogenesis of CAEV is strikingly similar to that of maedi-visna. After the transmission of CAEV to a more permissive permanent cell line derived from Himalayan tahr ovary, it was possible to grow and purify enough virus to initiate biochemical characterization. The structural proteins of CAEV are generally very similar to those of PPV, suggesting that the two viruses are closely related but not identical. This was substantiated by showing that serum from a CAEV-infected goat immunoprecipitated both CAEV and PPV virion structural antigens from extracts of radiolabeled virus and also precipitated putative nonstructural viral antigens from extracts of both CAEV- and PPV-infected cells.

Characterization of visna virus mRNA.

Visna virus is a retrovirus responsible for a classical slow infection of the central nervous system of sheep. In the present work we focused our attention on the viral mRNA's. We found that, during the acute infection in vitro, (i) viral mRNA's amount to only 0.1% of the total cytoplasmic RNA, (ii) 20% of the total cytoplasmic viral RNA is found in polyribosomes, and (iii) three viral mRNA's can be identified by sucrose gradient sedimentation or polyacrylamide gel electrophoresis. Their sedimentation coefficients are 36S, 27S, and 21S.

Precipitation of visna viral proteins by immune sera of rabbits and sheep.

Eighteen polypeptides equivalent to 1.2 x 10(6) daltons of visna virus were specifically precipitated by immune sera from rabbits and sheep. The hyperimmunized rabbit antisera contained high concentrations of antibodies against p25 and p14, whereas the sera from sheep actively infected with visna virus showed a large quantity of anti-gp115 antibody. The results indicate that almost all the polypeptides reported previously (F. H. Lin, J. Virol. 25:207--214, 1978) are virus-specific components of visna. The presence of anti-gp115 antibody in sera of infected sheep may offer a simple and sensitive diagnostic procedure for visna.

Detection of viral sequences of low reiteration frequency by in situ hybridization.

The sensitivity of in situ hybridization has been increased at least 10-fold by hybridizing in cDNA excess, by increasing the diffusion of the cDNA through the cells, by hybridizing at optimum temperature, and by stabilizing hybrids during autoradiography. Saturation of intracellular RNA with [3H]cDNA has been achieved. The assay is quantitative. In situ hybridization has been used to detect and quantitate visna virus RNA in infected cells. By using [3H]cDNA with specific activity of 2 X 10(8) dpm/micrograms and conditions that reduce background to negligible levels, 10--20 copies of viral RNA per cell can be detected and quantitated after 2 days of autoradiographic exposure.

Absence of circularly permuted and largely redundant sequences in the genome of visna virus.

A previous study of the infectivity of visna virus proviral DNA suggested that the genetic information of the virus is distributed over at least two of the RNA subunits. Because the genetic complexity of visna virus corresponds to the size of one subunit, this result may imply that sequence redundancies exist within each subunit. In the present article we have examined this question by constructing a map of the large RNase T1-resistant oligonucleotides of the viral genome. Our principal results are as follows: (i) all 36S RNA subunits have the same genetic content regardless of their polyadenylic acid [poly(A)] content; (ii) the poly(A) tract is present at the 3' end of the molecule; and (iii) the recoveries of 19 large RNase T1-resistant oligonucleotides from poly(A)-tagged RNA fragments of various sizes demonstrate that the oligonucleotides are organized in the same linear order within all subunits. Our results, therefore, exclude the existence of large sequence redundancies in the genome of visna virus.

Polyacrylamide gel electrophoresis of visna virus polypeptides isolated by agarose gel chromatography.

The proteins of visna are separated into nine major peaks by agarose gel chromatography in 6 M guanidine hydrochloride (GuHCl). The polypeptides in eack peak were isolated by acid precipitation and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). The patterns of SDS-PAGE show that the excluded material from the GuHCl column contains an aggregate of 10 non-glycosylated polypeptides. It is shown that this aggregate represents virus substructures that are not completely solubilized by GuHCl. Two glycoproteins, gp175 and gp115, were isolated from the column eluate. The major glycoprotein gp115 was coeluted with P90, P68, and P61 in GuHCl 4. Each of the four major peaks (GuHCl 5 to 8) contains more than one nonglycosylated polypeptide. However, a small polypeptide, P12, can be isolated in a homogeneous form in the last peak, GuHCl 9. Analysis of the virus proteins (100 microgram) by SDS-PAGE shows that 20 radioactive bands can be recognized. During fractionation of the protein on agarose gel columns followed by analysis with SDS-PAGE, a number of minor polypeptides that were not detected before became clearly recognizable. Thus, the combined use of column chromatography and SDS-PAGE shows that visna virus is composed of 25 proteins.

Visna virus RNA synthesis.

Visna is a classical slow infection in which virus characteristically persists in the face of the host immune response. The agent of this disease belongs to the retravirus group. The persistence of infection and the slow spread of virus are at least in part a consequence of restriction of the expression of virus genetic information in tissues of an infected animal (A. T. Haase et al., Science 195:175-177, 1977), but the point at which the virus life cycle is interrupted in vivo and the mechanism of restriction are unknown. We have embarked on a molecular analysis of restriction, focusing first on transcription. In this paper we have established the levels of viral RNA synthesis under permissive conditions, as a base line for subsequent studies in vivo. We show that (i) uninfected cells do not contain RNA sequences related to the visna virus genome, (ii) parental RNA is rapidly transported to the nucleus of the infected cell, (iii) virus RNA is synthesized in the nucleus and then transported to the cytoplasm (iv) synthesis of RNA proceeds mostly exponentially to reach levels of about 4,000 copies per cell at the end of the growth cycle, (v) nuclear and cytoplasmic RNA sediment in two size classes, 35S and 10-20S, (vi) viral mRNA has the same polarity as genome RNA and also sediments in two size classes of 35S and 10-20S.

Characterization of visna virus envelope neuraminic acid.

Visna virus particles inhibit influenza virus hemagglutination in an assay for neuraminic acid-containing viruses. Pretreatment of visna virus with neuraminidase abolished hemagglutination inhibition activity but did not significantly affect attachment, infectivity, or virus-induced cell fusion in sheep choroid plexus cell monolayers.

Slow persistent infection caused by visna virus: role of host restriction.

Proviral DNA has been demonstrated by in situ hybridization in foci of cells of a lamb infected with the RNA slow virus visna. A few of these cells also contain the major virion structural antigen p30. This restriction in virus gene expression in the infected animal provides a mechanism for persistence of virus in this chronic infection.

Complexity and polyadenylic acid content of visna virus 60-70S RNA.

The genomic complexity of visna virus was measured by quantitative analysis of 18 RNase T1-resistant oligonucleotides from 60-70S RNA. T1-resistant oligonucleotides were separated by two-dimensional polyacrylamide gel electrophoresis. Visna virus had a genomic complexity of 3.6 X 10(6) daltons, very close to the size of a single 30-40S RNA subunit. It was therefore concluded that the visna virus genome is largely polyploid. Visna virus 60-70S RNA polyadenylic acid segment was purified by T1 RNase digestion followed by oligodeoxythymidylic acid-cellulose column chromatography. It contained over 99% AMP and had a size of about 200 nucleotides. The binding capacities on oligodeoxythymidylic acid-cellulose of native 60-70S RNA and purified 30-40S RNA subunits were examined. It was concluded that two out of three intact subunits contain a polyadenylic acid segment.