RNA-binding properties of the matrix protein (p19gag) of avian sarcoma and leukemia viruses

We have reinvestigated the ability of the matrix protein (MA) (p19gag) of avian sarcoma and leukemia viruses to interact with RNA. Previous reports claimed on the one hand that MA can bind tightly and with a high degree of specificity to avian sarcoma and leukemia virus RNA in vitro and on the other that it cannot bind to RNA at all. We found that MA purified by any of several methods does bind to RNA, as measured by its ability to cause retention of radioactive RNA on nitrocellulose membranes in a filtration assay. However, this interaction is weak and lacks specificity. The interaction of MA with RNA was barely detectable by classical sedimentation analysis, and from this observation we estimate that the intrinsic MA-RNA association constant is ca. 10(3) M-1, at least 3 orders of magnitude smaller than the constant describing the interaction of the viral nucleocapsid protein (NC) (p12gag) with RNA, ca. 10(6) M-1. Separately purified phosphorylated and nonphosphorylated MA species bound RNA equally. We also found that MA can bind to DNA with an affinity similar to that for RNA. The large quantitative discrepancy between our results and earlier published reports can be traced in part to methods of data analysis.     

Primary structure of p19 species of avian sarcoma and leukemia viruses.

The internal structural proteins of avian sarcoma and leukemia viruses are derived from a precursor polypeptide that is the product of the viral gag gene. The N-terminal domain of the precursor gives rise to p19, a protein that interacts with the lipid envelope of the virus and that may also interact with viral RNA. The C terminus of p19 from the Prague C strain of Rous sarcoma virus was previously assigned to a tyrosine residue 175 amino acids from the N terminus. We have used metabolic labeling and carboxypeptidase digestion to show that the C terminus of p19 is actually tyrosine 155. This implies the existence of a sixth gag protein 22 amino acids in length and located between p19 and p10 on the gag precursor. The p19 species of some recombinant avian sarcoma viruses and of the defective endogenous virus derived from the ev-1 locus migrate on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as if they were about 4,000 daltons smaller than p19. We have elucidated the structure of these forms, called p19 beta, by analysis of the proteins and determination of the DNA sequence of the p19 region of the gag gene from ev-1 and ev-2. Esterification of carboxyl groups completely suppressed the differences in migration of p19 and p19 beta. Peptide mapping showed the altered mobility to be determined by sequences in the C-terminal cyanogen bromide fragment of the proteins. We conclude from the DNA sequence that a single glutamate-lysine alteration is responsible for the altered electrophoretic mobility.     

Purification and properties of a fifth major viral gag protein from avian sarcoma and leukemia viruses.

We have developed procedures for the purification of a 6,000-dalton protein from avian myeloblastosis virus. This protein is a major component of avian myeloblastosis virus, accounting for over 7% of total protein, and thus is equimolar with the other internal structural proteins in virions. As described in the accompanying paper (Hunter et al., J. Virol. 45:885-888, 1983), the results of N-terminal amino acid sequence analysis identify the protein as a product of the gag gene. We suggest denoting this protein as p10, according to nomenclature that is already in use for a previously identified but poorly defined low-molecular-weight protein or proteins of avian sarcoma and leukemia viruses. In virions p10 appears to be located between the core and the membrane. Several of its properties may explain why p10 has not been characterized previously. Among these are its abnormal amino acid composition, its solubility under conditions where most proteins are fixed into sodium dodecyl sulfate-polyacrylamide gels, and the variability in its electrophoretic migration in different avian sarcoma viruses.     

Amino-terminal amino acid sequence of p10, the fifth major gag polypeptide of avian sarcoma and leukemia viruses.

We have identified p10 as a fifth gag protein of avian sarcoma and leukemia viruses. Amino-terminal protein sequencing of this polypeptide purified from the Prague C strain of Rous sarcoma virus and from avian myeloblastosis virus implies that it is encoded within a stretch of 64 amino acid residues between p19 and p27 on the gag precursor polypeptide. For p10 from the Prague C strain of Rous sarcoma virus the first 30 residues were found to be identical with the predicted amino acid sequence from the Prague C strain of Rous sarcoma virus DNA sequence, whereas for p10 from avian myeloblastosis virus the protein sequence for the same region showed two amino acid substitutions. Amino acid composition data indicate that there are no gross composition changes beyond the region sequenced. The amino terminus of p10 is located two amino acid residues past the carboxy terminus of p19, whereas its carboxy terminus probably is located immediately adjacent to the first amino acid residue of p27.     

Localization of lipid-protein and protein-protein interactions within the murine retrovirus gag precursor by a novel peptide-mapping technique

In HTG2 hamster cells infected with the replication-defective Gazdar murine sarcoma virus only immature virus particles are formed, with the uncleaved gag precursor Pr65 as the only major protein in the virion. We have investigated the structure of these particles by using in situ cross-linking followed by chemical and enzymatic cleavages of Pr65 to localize sites of lipid-protein and protein-protein interactions. Lipid-protein cross-links were localized within a 10-kDa fragment in the p15 region of Pr65. Homotypic protein-protein cross-links between Pr65 units were localized within the p15 regions and also within the p10 regions of Pr65. Similar data for processed gag proteins in Rauscher murine leukemia virus, a prototype of a mature C-type virus, suggest that these interactions of the gag precursor are not altered during maturation. To identify the sites of cross-linking within Pr65, we have developed a two-dimensional peptide mapping technique that is based on nearest neighbor analysis of fragments released by cyanogen bromide treatment of partial cleavage products in gel slices. In conjunction with cross-linking, the peptide mapping technique is a powerful means for localizing specific interactions on a polypeptide backbone.     

Phosphorylation of the nonstructural proteins encoded by three avian acute leukemia viruses and by avian fujinami sarcoma virus.

The gag gene-related, nonstructural proteins of three avian acute leukemia viruses (namely, myelocytomatosis viruses MC29 and CMII and avian erythroblastosis virus) and of avian Fujinami sarcoma virus (FSV) isolated by immunoprecipitation from cellular lysates with anti-gag serum were shown to be phosphoproteins in vivo. The specific 32P radioactivity of the nonstructural proteins of MC29, CMII, and FSV was significantly higher than that of helper viral, intracellular gag proteins. Two of these proteins, i.e., the 140,000-dalton FSV and the 110,000-dalton MC29 proteins, were also phosphorylated in vitro by a kinase activity associated with immunocomplexes. This kinase activity is either separated from these proteins or inactivated by incubation of cellular lysates with normal serum followed by adsorption to staphylococcal protein A or sedimentation at 100,000 x g or both. It remains to be resolved whether the 110,000-dalton MC29 and 140,000-dalton FV proteins, in addition to being substrates for phosphorylation, also have intrinsic kinase activity.     

Differential proteolytic processing leads to multiple forms of the CA protein in avian sarcoma and leukemia viruses.

The CA (capsid) protein of avian sarcoma and leukemia viruses occurs in multiple species. Only one form has been previously characterized biochemically. We have now determined that the mature CA protein of avian sarcoma and leukemia viruses exists as three species with different C termini, ending in amino acid residues A-476, A-478, and M-479 of the Gag precursor, respectively. These structures were deduced from a combination of cyanogen bromide peptide mapping, sequence analysis of tryptic peptides, and electrospray mass spectrometry. The three forms of CA were detected in the same ratios in Rous sarcoma virus and avian myeloblastosis virus and therefore are likely to represent a common feature of members of this genus of avian retroviruses. The only previously reported CA species, CAM-479, accounts for only about 36% of the total CA protein, while CAA-476 and CAA-478 account for 55 and 9%, respectively. From the analysis of peptides cleaved in vitro by PR, the viral protease, we infer that the cleavage site between A-476 and A-477 not only is recognized by PR but is the preferred site. We were unable to determine if A-478/A-479 is a cleavage site for PR or alternatively if CAA-478 results from further processing of CAM-479 by a carboxypeptidase. To study the biological significance of residues A-477 to M-479, we constructed genetically altered viruses in which deletions removed either residues 477 to 479 or 477 to 488. The resulting virus particles appeared to assembly with normal efficiencies, but the latter mutant showed slowed proteolytic processing. Neither of the mutants was infectious.     

Biochemical characterization of transformation-specific proteins of acute avian leukemia and sarcoma viruses

The biological and biochemical properties of the transformation-specific proteins of three avian oncornaviruses with different oncogenic potentials were compared, namely the gag-myc protein of the avian myelocytomatosis virus MC29, the gag-erb A protein of the avian erythroblastosis virus AEV, and the gag-fps protein of Fujinami sarcoma virus FSV. These oncogenes were analyzed in transformed fibroblasts that expressed only the transforming proteins but showed no virus replication. Monoclonal antibodies against the viral structural protein p19, which is the N-terminus of the proteins, were used for indirect immunofluorescence, for immunoprecipitation of the proteins from subcellular fractions, and for immunoaffinity column chromatography. With this last method a 3000-fold purification of the proteins was obtained. By indirect immunofluorescence it was shown that the gag-myc protein was located in the nucleus, and bound to DNA after purification. The gag-erb A protein was not nuclear but probably located in the cytoplasm and did not bind to DNA after purification. Neither of the two proteins exhibited protein kinase activity. In contrast, the gag-fps protein did not bind to DNA but showed protein kinase activity after purification. It was not located in the nucleus either.     

Protection against Friend retrovirus-induced leukemia by recombinant vaccinia viruses expressing the gag gene.

High sequence variability in the envelope gene of human immunodeficiency virus has provoked interest in nonenvelope antigens as potential immunogens against retrovirus infection. However, the role of core protein antigens encoded by the gag gene in protective immunity against retroviruses is unclear. By using recombinant vaccinia viruses expressing the Friend murine leukemia helper virus (F-MuLV) gag gene, we could prime CD4+ T-helper cells and protectively immunize susceptible strains of mice against Friend retrovirus infection. Recovery from leukemic splenomegaly developed more slowly after immunization with vaccinia virus-F-MuLV gag than with vaccinia virus-F-MuLV env; however, genetic nonresponders to the envelope protein could be partially protected with Gag vaccines. Class switching of F-MuLV-neutralizing antibodies from immunoglobulin M to immunoglobulin G after challenge with Friend virus complex was facilitated in mice immunized with the Gag antigen. Sequential deletion of the gag gene revealed that the major protective epitope was located on the N-terminal hydrophobic protein p15.     

Optimization of the method of cyanogen bromide mapping of polypeptides separated by polyacrylamide gel electrophoresis

Two highly efficient methods of CNBr-peptide mapping of polypeptides divided by polyacrylamide gel electrophoresis are described. The first is elaborated on the basis of peptide mapping of collagen proposed by G. Barsh et al. The following three modifications diminish wasting the material essential for the method. 1. CNBr treatment takes place in the absence of CNBr solution outside the gel, excluding the peptides elution from the gel fragments in the process of mapping. 2. After CNBr treatment the solution of CNBr is substituted by the samples buffer before electrophoresis by means of drying and subsequent addition of minimal volumes of the buffer. The latter procedures substitute the gel washing out by the buffer solution. 3. The step of washing the gel fragments by the 70% strong solution of formic acid before CNBr treatment is excluded. The second method of CNBr-peptide mapping is notable for extracting peptides from the gel fragments in the process of CNBr-treatment and permits obtaining of the high quality peptide electrophoregrams.     

Identification of the viral sequence required for the generation of recovered avian sarcoma viruses and characterization of a series of replication-defective recovered avian sarcoma viruses.

The ability of transformation-defective deletion mutants of Schmidt-Ruppin Rous sarcoma virus to induce tumors and generate recovered sarcoma viruses (rASVs) was correlated with the partial src sequences retained in the transformation-defective viral genomes. Since all the transformation-defective viruses that were capable of generating rASVs retained a portion of the 3' src sequence, regardless of the extent of the 5' src deletion, and those lacking the 3' src were unable to generate rASVs, it appears that the 3', but most likely not the 5', src sequence retained in the transformation-defective viral genome is essential for rASV formation. However, rASVs derived from a particular mutant, td109, which retained a portion of the 3' src sequence, but lacked most (if not all) of the 5' src sequence, were all found to be defective in replication. Analyses of the genomic sequences of 13 isolates of td109-derived rASVs revealed that they contained various deletions in viral envelope (env), polymerase (pol), and structural protein (gag) genes. Ten isolates of rASVs contained env deletions. One isolate (rASV3812) contained a deletion of env and the 3' half of pol, and one isolate (rASV398) contained a deletion of env and pol. The one with the most extensive deletion (rASV374) had a deletion from the p12-coding sequence through pol and env. In addition, the 5' src region of td109-derived rASVs were heterogeneous. Among the 7 isolates analyzed in detail, one isolate of rASV had a small deletion of the 5' src sequence, whereas three other isolates contained extra new sequences upstream from src. Both env- and env- pol- rASVs were capable of directing the synthesis of precursor and mature gag proteins in the infected nonproducer cells. We attribute the deletions in the replication-defective rASVs to the possibility that the 5' recombination site between the td109 and c-src sequence, involved regions of only partial homology due to lack of sufficient 5' src sequence in the td109 genome for homologous recombination. A model of recombination between the viral genome and the c-src sequence is proposed to account for the requirement of the 3' src sequence and the basis for the generation of deletions in td109-derived rASVs.     

The same normal cell protein is phosphorylated after transformation by avian sarcoma viruses with unrelated transforming genes.

The phosphorylation of a normal cellular protein of molecular weight 34,000 (34K) is enhanced in Rous sarcoma virus-transformed chicken embryo fibroblasts apparently as a direct consequence of the phosphotransferase activity of the Rous sarcoma virus-transforming protein pp60src. We have prepared anti-34K serum by using 34K purified from normal fibroblasts to confirm that the transformation-specific phosphorylation described previously occurs on a normal cellular protein and to further characterize the nature of the protein. In this communication, we also show that the phosphorylation of 34K is also increased in cells transformed by either Fujinami or PRCII sarcoma virus, two recently characterized avian sarcoma viruses whose transforming proteins, although distinct from pp60src, are also associated with phosphotransferase activity. Moreover, comparative fingerprinting of tryptic phosphopeptides shows that the major site of phosphorylation of 34K is the same in all three cases.     

Specificity of plasma membrane targeting by the rous sarcoma virus gag protein

Budding of C-type retroviruses begins when the viral Gag polyprotein is directed to the plasma membrane by an N-terminal membrane-binding (M) domain. While dispersed basic amino acids within the M domain are critical for stable membrane association and consequent particle assembly, additional residues or motifs may be required for specific plasma membrane targeting and binding. We have identified an assembly-defective Rous sarcoma virus (RSV) Gag mutant that retains significant membrane affinity despite having a deletion of the fourth alpha-helix of the M domain. Examination of the mutant protein's subcellular distribution revealed that it was not localized to the plasma membrane but instead was mistargeted to intracytoplasmic membranes. Specific plasma membrane targeting was restored by the addition of myristate plus a single basic residue, by multiple basic residues, or by the heterologous hydrophobic membrane-binding domain from the cellular Fyn protein. These results suggest that the fourth alpha-helix of the RSV M domain promotes specific targeting of Gag to the plasma membrane, either through a direct interaction with plasma membrane phospholipids or a membrane-associated cellular factor or by maintaining the conformation of Gag to expose specific plasma membrane targeting sequences.     

Nucleotide sequences in the RNA of mammalian leukemia and sarcoma viruses.

The nucleotide sequences in viral RNA from purified murine sarcoma and hamster leukemia viruses (S+H+) from HTG-1 cells and Rauscher leukemia virus (RLV) from JLS-V 9 cells have been examined by polynucleotide agarose affinity chromatography. There is at least one copy of poly(A) sequences per genomic viral RNA molecule. After heat denaturation of genomic viral RNA (S+H+), there are two types of viral subunits for 34S and 28S species: one that contains poly(A) sequences and one that does not. There are no detectable poly(U) tracts in the viral RNA. However, poly(C) sequences and poly(G) tracts were detected in viral RNA, although less poly(G) than poly(C) tracts were observed. In addition, heat-denatured genomic viral RNA has a greater affinity for poly(G) agarose column than native genomic viral RNA.     

Role of gag sequence in the biochemical properties and transforming activity of the avian sarcoma virus UR2-encoded gag-ros fusion protein.

The transforming protein P68gag-ros of avian sarcoma virus UR2 is a transmembrane tyrosine protein kinase molecule with the gag portion protruding extracellularly. To investigate the role of the gag moiety in the biochemical properties and biological functions of the P68gag-ros fusion protein, retroviruses containing the ros coding sequence of UR2 were constructed and analyzed. The gag-free ros protein was expressed from one of the mutant retroviruses at a level 10 to 50% of that of the wild-type UR2. However, the gag-free ros-containing viruses were not able to either transform chicken embryo fibroblasts or induce tumors in chickens. The specific tyrosine protein kinase activity of gag-free ros protein is about 10- to 20-fold reduced as judged by in vitro autophosphorylation. The gag-free ros protein is still capable of associating with membrane fractions including the plasma membrane, indicating that sequences essential for recognition and binding membranes must be located within ros. Upon passages of the gag-free mutants, transforming and tumorigenic variants occasionally emerged. The variants were found to have regained the gag sequence fused to the 5' end of the ros, apparently via recombination with the helper virus or through intramolecular recombination between ros and upstream gag sequences in the same virus construct. All three variants analyzed code for gag-ros fusion protein larger than 68 kDa. The gag-ros recombination junction of one of the transforming variants was sequenced and found to consist of a p19-p10-p27-ros fusion sequence. We conclude that the gag sequence is essential for the transforming activity of P68gag-ros but is not important for its membrane association.