Primate retroviruses: envelope glycoproteins of endogenous type C and type D viruses possess common interspecies antigenic determinants.

The major 70,000- to 80,000-molecular-weight envelope glycoproteins of the squirrel monkey retrovirus, Mason-Pfizer monkey virus, and M7 baboon virus and the related endogenous feline virus, RD114, were isolated and immunologically characterized. Immunoprecipitation and competition immunoassay analysis revealed these viral envelope glycoproteins to possess several distinct classes of immunological determinants. These include species-specific determinants, group-specific antigenic determinants unique to endogenous primate type C viruses, and group-specific determinants for type D viruses such as Mason-Pfizer monkey virus and squirrel monkey retrovirus. In addition, a class of broadly reactive antigenic determinants shared by envelope glycoproteins of both type C viruses of the baboon/RD114 group and type D viruses of the Mason-Pfizer monkey virus/squirrel monkey virus group are described. Other mammalian oncornaviruses tested, including isolates of nonprimate origin and representative type B viruses, lacked these determinants. The demonstration of antigenic determinants specific to envelope glycoproteins of type C and type D primate viruses indicates either that these viruses are evolutionarily related or that genetic recombination occurred between their progenitors. Alternatively, endogenous type D oncornaviruses may be replication defective, and acquisition of endogenous type C viral genetic sequences coding for envelope glycoprotein determinants may be necessary for their isolation as infectious virus.     

Type-C RNA Virus Gene Expression in Human Tissue

Partially purified fractions of human tissues have been analyzed by competition radioimmunoassay for the presence of two of the principle structural components of type-C RNA viruses, the major core protein (p27 to p30) and the major envelope glycopeptides (gp69/71). Screening of tissues was carried out by use of a heterologous assay system of (125)I-labeled Rauscher murine virus p30 antigen and anti-RD 114 virus serum which was found to detect a class of interspecies determinants common to murine, feline, and primate viruses. A competitor with the same apparent affinity for antibody binding as that of purified viral core proteins was found in relatively high concentration in tissues from patients with systemic lupus erythematosus, in some neoplastic tissues, and also in normal human tissues. This competitor from a lupus spleen chromatographed on phosphocellulose and showed size fractionation during gel filtration similar to known p27 to p30 viral proteins. An immunologically reactive protein was also demonstrated by immunodiffusion and by immunoprecipitation of (125)I-labeled human protein with anti-RD 114 p28 serum. Analysis of these human competitor proteins with homologous assay systems of viral core proteins and corresponding antisera showed that all, including the normal tissue extracts, appear similar to core proteins of known viruses, especially the RD 114 and woolly monkey species. A hypothesis suggested by these data is that many, if not all, humans harbor at least part of the genome of one or more type-C viruses, the properties of which are similar to those of viruses from other mammalian species, particularly primates.     

Structural proteins of mammalian RNA tumor viruses: relatedness of the interspecies antigenic determinants of the major internal protein.

The relatedness of antigenic determinants of purified major core proteins of the murine, feline, RD 114/baboon, and woolly monkey/gibbon ape groups of RNA tumor viruses was examined by competition radioimmunoassay. In assay systems of a homologous antigen and antiserum, high affinity competition for binding to all of the antibodies was observed only with the homologous unlabeled protein; the core proteins of other groups of viruses showed only low affinity binding of a small fraction of antibodies, presumably those reactive with the interspecies determinants, at concentrations of competing protein 10- to 100-fold greater than that of the labeled antigen. The cross-reactive (interspecies) antigens of every two viruses were selectively examined by precipitating the purified 125-I-labeled protein with antiserum against each of the other proteins. The extent to which these shared determinants were common to the other viruses was then tested by the effectiveness of the proteins of each virus to compete for antibody binding. Several classes of interspecies determinants were distinguished: those common to two of the groups of viruses, others to three, and some to all four. Moreover, an even greater variety of interspecies determinants was indicated by differences in the affinity of the individual proteins for antibody binding, supporting the hypothesis that there are at least several, if not many, different interspecies determinants with a broad spectrum of antigenic cross-reactivity. These studies suggest that the murine and feline viruses are closely related as they contain cross-reactive antigenic determinants not shared with the other viruses, that the feline virus is more closely related to the woolly monkey virus than to RD 114, and that the RD 114 and woolly monkey viruses retain interspecies determinants shared relatively equally with each of the other viruses.     

Purification, Characterization, and Comparison of the DNA Polymerases from Two Primate RNA Tumor Viruses

The DNA polymerase from the Mason-Pfizer monkey virus (M-PMV), an RNA tumor virus not typical type-C or type-B, has been purified a thousand-fold over the original crude viral suspension. This purified enzyme is compared to a similarly purified DNA polymerase from the primate woolly monkey virus, a type-C virus. The two enzymes have similar template specificities but differ in their requirements for optimum activity. Both DNA polymerases have a pH optimum of 7.3 in Tris buffer. M-PMV enzyme has maximum activity with 5 mM Mg(2+) and 40 mM potassium chloride, whereas the woolly monkey virus optima are 100 mM potassium chloride with 0.8 mM Mn(2+). The apparent molecular weight of the M-PMV enzyme is approximately 110,000, whereas the woolly monkey virus polymerase is approximately 70,000. The biochemical properties of these two enzymes were also compared to a similarly purified enzyme from a type-C virus from a lower mammal (Rauscher murine leukemia virus). The results show that more similarity exists between the DNA polymerases from viruses of the same type (type-C), than between the polymerases from viruses of different types but from closely related species.     

Antigenic characterization of type C RNA virus isolates of gibbon apes.

Type C RNA viruses initially isolated from a lymphosarcoma of a gibbon ape and from a fibrosarcoma of a woolly monkey are very closely related immunologically. However, recent studies have shown that these viruses are distinguishable in a radioimmunoassay for the 12,000-molecular-weight polypeptide (p12) of the woolly monkey virus. In the present report, an immunoassay has been developed for the p12 polypeptide of the gibbon ape type C virus. This assay is shown to further distinguish the woolly monkey and gibbon ape viruses. In type-specific assays for the p12 polypeptides of these viruses, two new type C viruses isolated from gibbons in a second colony, characterized by high incidence of hemopoietic neoplasia, are immunologically distinguishable from the original gibbon ape virus. The p12 type-specific immunoassays described in the present report may be of importance in studying the natural history of these viruses and their relationship to tumors of primates.     

Structural polypeptides of mammalian type C RNA viruses. Isolation and immunologic characterization of a low molecular weight polypeptide, p10.

Low molecular weight polypeptides of several mammalian type C RNA tumor viruses were purified by sequential ion exchange chromatography and molecular sizing techniques. These included a polypeptide with a molecular weight of 10,000 to 11,000, p 10, from two type C viruses of mouse origin. Rauscher- and Moloney-murine leukemia virus (MuL virus), and from an infectious type C virus isolate of the woolly monkey. The p12 structural polypeptides of these viruses as well as Rauscher-MuL virus p15 were also purified. By using radioimmunoassays developed for each polypeptide, it was possible to demonstrate that all three low molecular weight polypeptides, p15, p12, and p10, were immunologically unique. Among type C viral structural polypeptides, p10 has been least well characterized immunologically. The results of the present study indicate that p10 is virus-coded and possesses strong group-specific antigenic determinants. By use of appropriate immunoassays, broadly reactive interspecies determinants shared by mammalian type C virus isolates of murine, feline, and primate origin, were also demonstrated. The interspecies antigenic determinants of p10 were shown to be as broadly cross-reactive as those exhibited by the major type C virus structural polypeptide, p30.     

Radiommunoassays for the 70,000-molecular-weight glycoproteins of endogenous mouse type C viruses: viral antigen expression in normal mouse tissues and sera.

Genetic information coding for type C RNA viruses is transmitted within the DNA of mouse cells. At least three endogenous viruses have so far been immunologically distinguished by radioimmunoassays for their 12,000-molecular-weight polypeptides (p12). In the present study, the 70,000-molecular-weight glycoproteins (gp70) of three prototype viruses were purified, and competition radioimmunoassays were developed for each. By use of these immunoassays, the antigenic determinants of gp70's of different classes of endogenous virus, isolated from the same and from a variety of other mouse strains, were readily discriminated. In contrast, viruses of the same class were indistinguishable. These findings further document the existence of three distinct endogenous viruses of mouse cell. The levels of type C viral gp70 were quantitated in tissues and sera of several inbred strains. The pattern of immunological reactivity of the gp70 detected in serum was indistinguishable from that of the viral gp70 partially purified from tissues of the same strain. Moreover, in each case it was indistinguishable from that of a specific class of endogenous virus. In virus-negative tissues of BALB/c and NIH Swiss mice, the viral gp70 detected was shown to be representative of a class III endogenous virus whose p12 polypeptide was also expressed by the same cells.     

Biological, Chemical, and Immunological Studies of Rauscher Ecotropic and Mink Cell Focus-Forming Viruses from JLS-V9 Cells

Two murine leukemia viruses were isolated from JLS-V9 cells which had been infected with Rauscher plasma virus. One virus was XC positive and failed to grow on mink or cat cells and thus was an ecotropic virus. The other virus formed cytopathic foci on mink cells, was XC negative, and fell into the mink cell focus-forming (MCF) viral interference group and was thus an MCF virus. The glycoproteins of the two viruses could be distinguished immunologically, by peptide mapping, and by size in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The MCF virus produced gp69, and the ecotropic virus produced gp71, explaining the origin of the heterogeneous glycoprotein (gp69 and gp71) of Rauscher leukemia virus. Amino-terminal sequences of gp69 and gp71 were determined. The MCF sequence was distinct from the ecotropic sequence, but retained partial homology to it. The data show that the glycoproteins are encoded by related yet distinct genes. The protein structural data support the proposal that MCF virus gp70 molecules have nonecotropic sequences at the amino terminus, with ecotropic sequences occurring at the 3' end of the gene. The Rauscher MCF virus glycoprotein lacks a glycosylation site found at position 12 of the ecotropic sequence.     

Search for mammalian type-C retrovirus polypeptides on infected animal cells and human tumor cell lines using interspecies-reacting antibodies

Cells producing endogenous and exogenous type-C retroviruses of murine, feline and primate origin were evaluated for expression of those virus-specific cell-surface antigens which cross-react with antibodies to interspecies determinants of mammalian type-C viral polypeptides. Surface polypeptides of cells replicating endogenous and exogenous type-C retroviruses were iodinated by the lactoperoxidase method. Labelled antigens were immunoprecipitated and analyzed in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. This method detected gp71 and less frequently p15E/p12E on the surface of virus-producing cells; in addition, p27 was found on F422 cells replicating feline leukemia virus. Antibodies to the membrane protein p15E displayed the broadest cross-reactivity but only antibodies to gp71 mediated complement-dependent interspecies cell lysis. The pattern of cross-reactivity reflected known genetic relationships among these mammalian viruses. Although antiserum to the simian sarcoma virus complex (SSV) was strongly cytotoxic to some human tumor cell lines, this reactivity could not be attributed to antibodies cross-reacting with SSV gp71.     

Purification and characterization of baboon endogenous virus DNA polymerase.

An RNA-directed DNA polymerase was purified from baboon endogenous type-C virus by successive column chromatography on DEAE cellulose, phosphocellulose and hydroxyapatite. The purified DNA polymerase has a molecular weight of 68 000, a pH optimum of 8.0, a Mn2+ optimum of 1 mM, and a KCl optimum of 40 mM. The purified enzyme transcribes heteropolymeric regions of viral 60--70 S RNA isolated from different type-C viruses. The purified enzyme is immunologically related to a similarly purified polymerase from the cat endogenous type-C virus RD114.     

Characterization and significance of delayed processing of the feline leukemia virus FeLV-FAIDS envelope glycoprotein.

FeLV-FAIDS, an immunodeficiency-inducing isolate of feline leukemia virus, is composed of a pathogenic but replication-defective genome (molecular clone 61C) and a replication-competent but non-immunodeficiency-inducing variant genome (molecular clone 61E). The chimeric virus EECC, composed of the 5' gag-pol of 61E fused to the env-3' LTR of 61C, also induces immunodeficiency. The 61C (or EECC) gp80 can be distinguished from that of 61E on the basis of antigenic recognition, size, and rate of posttranslational processing. We found that the nascent precursor polypeptides of the two viruses were the same size; however, the 61E gp80 rapidly shifted to a smaller size and was subsequently cleaved to gp70, whereas EECC gp80 maintained its nascent size and was cleaved to gp70 only after a prolonged time. Endo-beta-N-acetyl glucosaminidase H and N-glycanase digestions of newly formed glycoproteins resulted in a similar banding pattern for both viruses, indicating that both contained the same number of oligosaccharide side chains and that all of these were high mannose sugars. The metabolic inhibitors of glycosylation, castanospermine or N-methyldeoxynojirimycin, prevented both the rapid trimming of 61E gp80 and its cleavage to gp70. Treatment with mannosidase inhibitors, however, did not affect 61E gp80 processing or size, suggesting that retention of glucose residues on EECC was responsible for these distinguishing properties of the glycoprotein. The pathological consequence of aberrant viral glycoprotein processing was evaluated in feline 3201 T lymphocytes, which are infectable by both 61E and EECC but are killed only by EECC. As in fibroblasts, the EECC glycoprotein produced in lymphocytes was larger, antigenically distinct, and processed more slowly than was the glycoprotein of 61E. Castanospermine treatment of 61E-infected 3201 T cells, however, not only abrogated the antigenic differences between the 61E and EECC glycoproteins but also resulted in a cytopathic effect. Our results suggest that (i) intracellular accumulation of EECC envelope glycoprotein may occur consequent to retention of glucose residues on carbohydrate side chains and (ii) a strong correlation exists between delayed glycoprotein processing and cytopathicity in FeLV-FAIDS-infected T lymphocytes.     

Reactivity of antisera to endogenous primate retrovirus with a human T cell membrane protein: recognition of a nonviral glycoprotein by antibodies directed only against carbohydrate components

A glycosylated protein of approximately 70,000 daltons (gp70) from the surface of human peripheral blood T cells was immunoprecipitated by antisera to the baboon endogenous retrovirus (BEV-M7) and the serologically related feline endogenous retrovirus (RD114) but not by antisera to other retroviruses. Whereas preliminary absorption experiments were consistent with a possible viral specificity for this reaction, detailed biochemical and serologic characterization of the purified cellular protein suggested that it was not related to the gp70 of either M7 or RD114 viruses. The specificity of the reaction was further analyzed by assays of cellular gp70 antigenicity after exposure to exo- and endoglycosidases or trypsin and carbohydrate hapten inhibition studies. The results of these experiments were consistent with the interpretation that the glycoprotein was being recognized by antibody binding to the carbohydrate moiety of the molecule. These results provide an example of an antibody activity that could lead to inappropriate conclusions when sensitive radioimmunoprecipitation techniques are used for the biochemical analysis of antigenic systems. They emphasize the necessity of purifying cellular antigens as a prerequisite to determining the exact basis for a serologic reaction.     

RD-114, baboon, and woolly monkey viral RNA's compared in size and structure.

The molecular weights, subunit compositions, and secondary structure patterns of the RNAs from an endogenous baboon virus and from a woolly monkey sarcoma virus were examined and compared to the properties of the RNA of RD-114, an endogenous feline virus. The high molecular weight RNA extracted from each of these three viruses has a sedimentation coefficient of 52S, and a molecular length, measured by electron microscopy, of 16-20 kb (kb=kilobase, 1000 nucleotides). Each such RNA is a dimer, containing two monomer subunits of 8-10 kb in length (molecular weight 3 X 10(6) daltons). The two monomer subunits are joined at their non-poly(A) ends in a structure called the dimer linkage structure. The appearance of this structure is somewhat different for the different viruses. The dimer linkage dissociates at temperature estimated to be 87 degrees C in aqueous 0.1M Na+ for RD-114 and baboon viral RNAs, but at the lower temperature of 66 degrees C for woolly monkey RNA. All three viral RNAs have two large loops of similar size and position symmetrically placed on either side of the dimer linkage structure. Since the baboon virus is partially related to RD-114, and the woolly monkey virus is unrelated to either of the other two, the dimer linkage and symmetrical loops are surprisingly similar and may well be common features of type C virus RNAs.     

Differential expression of helper viral structural polypeptides in cells transformed by clonal isolates of woolly monkey sarcoma virus.

Cell lines transformed by woolly monkey sarcoma virus (WSV) in the absence of infectious virus production were analyzed for the expression of woolly monkey helper viral p30, p12, and gp70 antigens. Several lines produced high levels of both p30 and p12, whereas gp70 was not detectable. One transformed clone expressed only p12, and in another cell line, none of the helper viral antigens were detected. The properties of each sarcoma virus bred true upon transmission, indicating that each variant represents a distinct genotype. The different cell lines were examined with respect to properties characteristic of the transformed state. The in vitro growth properties and oncogenicity of each WSV-transformed clone were indistinguishable, indicating that transformation by WSV occurs independently of the expression of at least three helper viral polypeptides.     

Identification of a putative receptor for subgroup A feline leukemia virus on feline T cells.

Retrovirus infection is initiated by the binding of virus envelope glycoprotein to a receptor molecule present on cell membranes. To characterize a receptor for feline leukemia virus (FeLV), we extensively purified the viral envelope glycoprotein, gp70, from culture supernatants of FeLV-61E (subgroup A)-infected cells by immunoaffinity chromatography. Binding of purified 125I-labeled gp70 to the feline T-cell line 3201 was specific and saturable, and Scatchard analysis revealed a single class of receptor binding sites with an average number of 1.6 x 10(5) receptors per cell and an apparent affinity constant (Ka) of 1.15 x 10(9) M-1. Cross-linking experiments identified a putative gp70-receptor complex of 135 to 140 kDa. Similarly, coprecipitation of 125I-labeled cell surface proteins with purified gp70 and a neutralizing but noninterfering anti-gp70 monoclonal antibody revealed a single cell surface protein of approximately 70 kDa. These results indicate that FeLV-A binds to feline T cells via a 70-kDa cell surface protein, its presumptive receptor.     

Relationship of retroviruses isolated from human leukemia tissues to the woolly monkey-gibbon ape leukemia viruses.

Retroviruses have been isolated from the tissues of human leukemia patients. Previous studies have shown that these isolates share some antigenic determinants with the family of viruses isolated from the woolly monkey and gibbon ape and that they exhibit partial nuclei acid homology with this same group of viruses. We have compared the RNAs of the viruses by two-dimensional polyacrylamide gel electrophoresis of the large RNase T1-resistant oligonucleotides. The degree of sequence identity between the RNAs was determined by the similarity of their RNase T1-resistant oligonucleotide pattern on gels, fingerprints, and in some cases by partial sequence analysis of individual oligonucleotides. This technique permits us to determine the degree of sequence identity among related RNA species. From our studies we conclude that viruses isolated from the tissues of two human leukemia patients, A1476 and SKA 21-3, as well as some subcultures of a virus isolated from the leukemic tissues of a third patient, HL23V, are closely related to the wooly monkey virus. However, the fingerprints of other HL23 viral isolates are very similar to that of GaLVSF, a gibbon ape leukemia virus isolated from a lymphosarcoma.