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.     

Determination of the proteolytic processing sites in the polyprotein encoded by the bottom-component RNA of cowpea mosaic virus

We have purified two low-molecular-weight polypeptides from the Prague C strain of Rous sarcoma virus and have identified these as products of the gag precursor Pr76 by protein sequencing and by amino acid analysis. Both polypeptides are derived from a stretch of 22 amino acids within Pr76 that separates p19 and p10. We refer to this region as p2. Together the two cleavage products form the entire p2 region. The junctions of p19 with the amino-terminal fragment of p2 and of p10 with the carboxy-terminal fragment of p2 define two new processing sites within the gag precursor, Tyr-155-His-156 and Gly-177-Ser-178. Both polypeptides are major cleavage products of Pr76 that occur in Prague C Rous sarcoma virus at an estimated 1,000 copies per virion. They also are prominent components of avian myeloblastosis virus. The combination of gel filtration and reverse-phase high-pressure liquid chromatography, which was used for the isolation of the two fragments of p2, resolved over a dozen other low-molecular-weight polypeptides from avian sarcoma and leukemia viruses that previously were undetected. This technique thus should serve as a useful procedure for further characterization of viral components.     

Correlation of RNA binding affinity of avian oncornavirus p19 proteins with the extent of processing of virus genome RNA in cells.

We purified the p19 proteins from the Prague C strain of Rous sarcoma virus, avian myeloblastosis virus, B77 sarcoma virus, myeloblastosis-associated virus-2(0), and PR-E 95-C virus and measured their binding affinities for 60S viral RNA by the nitrocellulose filter binding technique. The apparent association constants of the p19 proteins from Rous sarcoma virus Prague C, avian myeloblastosis virus, and B77 sarcoma virus for homologous and heterologous 60S RNAs were similar (1.5 x 10(11) to 2.6 x 10(11) liters/mol), whereas those of myeloblastosis-associated virus-2(0) and PR-E 95-C virus were 10-fold lower. The sizes and relative amounts of the virus-specific polyadenylic acid-containing RNAs in the cytoplasms of cells infected with Rous sarcoma virus Prague C, myeloblastosis-associated virus-2(0), and PR-E 95-C virus were determined by fractionating the RNAs on agarose gels containing methylmercury hydroxide, transferring them to diazobenzyloxymethyl paper and hybridizing them to a 70-nucleotide complementary DNA probe. In cells infected with Rous sarcoma virus Prague C we detected 3.4 x 10(6)-, 1.9 x 10(6)-, and 1.1 x 10(6)-dalton RNAs, in PR-E 95-C virus-infected cells we detected 3.4 x 10(6)-, 1.9 x 10(6)- and 0.7 x 10(6)-dalton RNAs, and in cells infected with myeloblastosis-associated virus-2(0) we detected 3 x 10(6)- and 1.3 x 10(6)-dalton RNAs. Each of these RNA species contained RNA sequences derived from the 5' terminus of genome-length RNA, as evidenced by hybridization with the 5' 70-nucleotide complementary DNA. The ratios of subgenomic mRNA's to genome-length RNAs in cells infected with myeloblastosis-associated virus-2(0) and PR-E 95-C virus were three- to five-fold higher than the ratio in cells infected with Rous sarcoma virus Prague C. These results suggest that more processing of viral RNA in infected cells is correlated with lower binding affinities of the p19 protein for viral RNA, and they are consistent with the hypothesis that the p19 protein controls processing of viral RNA in cells.     

Structural characterization of the avian retrovirus reverse transcriptase and endonuclease domains

The enzymatic domains of the avian retrovirus polymerase (pol) gene have been mapped by the use of peptide antibodies and COOH-terminal amino acid analysis. The processed pol beta polypeptide is cleaved in vivo to yield alpha and pp32. Rabbit antibodies were directed against synthetic peptides whose sequence was deduced from the known pol sequence of Rous sarcoma virus, Prague C (Schwartz, D.E., Tizard, R., and Gilbert, W. (1983) Cell 32, 853-869). The RNase H active site of pol was located in the NH2-terminal region of the alpha DNA polymerase subunit. The COOH terminus of the alpha subunit was found to be immediately adjacent to the NH2 terminus of the pp32 pol protein. COOH-terminal amino acid analysis of pp32 revealed that this protein is also processed. From the deduced amino acid sequence of pol, it appears likely that pol encodes an additional 4100-dalton polypeptide located at its extreme COOH terminus. The enzymatic domains on beta appear to map in the following order: RNase H-DNA polymerase-DNA endonuclease. Hydrophilicity analysis and secondary structure predictions of wild type Rous sarcoma virus pol products and mutated pp32 possessing single amino acid changes permit further structural evaluation of the multifunctional pol protein.     

Fine-structure analyses of lipid-protein and protein-protein interactions of gag protein p19 of the avian sarcoma and leukemia viruses by cyanogen bromide mapping.

In avian sarcoma and leukemia viruses, the gag protein p19 functions structurally as a matrix protein, connecting internal components with the viral envelope. We have used a combination of in situ cross-linking and peptide mapping to localize within p19 the regions responsible for two major interactions in this complex, p19 with lipid and p19 with p19. Lipid-protein cross-links were localized near the amino terminus within the first 35 amino acids of the polypeptide. Homotypic protein-protein disulfide bridges were found to originate from near the carboxy terminus of p19, from cysteine residues at amino acids 111 and 153. These results suggest that p19 is divided into domains with distinct functions. The peptide maps constructed for p19, and for the related proteins p23 in avian sarcoma and leukemia viruses and p19 beta in recombinant avian sarcoma viruses, should serve as useful tools for other types of studies involving these proteins.     

Phosphorylation of avian retrovirus matrix protein by Ca2+/phospholipid-dependent protein kinase

The matrix protein from avian myeloblastosis virus and the Rous sarcoma virus, Prague C strain, is a phosphoprotein. A comparison of the amino acid sequences shows these phosphoproteins are very similar. The sites of phosphorylation of the matrix protein purified from virions are identified as serine residues 68 and 106. Treatment with purified rabbit skeletal-muscle protein phosphatase 1 or 2A, selectively releases phosphate from serine 68, while alkali treatment releases phosphate from both sites. When analyzed as a substrate for six different protein kinases, only the Ca2+/phospholipid-dependent protein kinase modifies the matrix protein. The serine residues phosphorylated in vivo are identical to those phosphorylated in vitro by this protein kinase. The role of these phosphorylation events in viral production is discussed.     

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.     

Primary structure of the low molecular weight nucleic acid-binding proteins of murine leukemia viruses

Murine leukemia viruses contain a low molecular weight basic protein, designated p10, which binds to single-stranded nucleic acids. The complete amino acid sequence of p10 from the Rauscher strain of virus has been determined. The partial amino acid sequences of p10s from Moloney, Friend, AKR, Gross, radiation leukemia, and BALB/2 viral strains have also been determined using microsequencing techniques. Rauscher p10 is composed of 56 amino acid residues; the other p10s are similar in size but differ from Rauscher by a few conservative amino acid substitutions. The structure of Rauscher p10 was compared to the structure of a functionally homologous protein from Rous avian sarcoma virus. The comparison revealed regions of amino acid sequence homologies which indicate a phylogenetic relationship between the murine and avian viral strains. The analyses revealed a periodic placement of three Cys residues and a Gly-His sequence. A structure involving these residues is found once in the murine protein and twice in the avian protein. A similar structure is seen in the single stranded nucleic acid binding protein of bacteriophage T4. However, in the latter case, the order of amino acid residues is inverted.     

Antiserum specific for the carboxy terminus of the transforming protein of Rous sarcoma virus

An antiserum specific for the carboxy terminus of p60src, the transforming protein of Rous sarcoma virus, was produced by immunization of rabbits with a conjugate of bovine serum albumin and the synthetic peptide NH2-Tyr-Val-Leu-Glu-Val-Ala-Glu-COOH. The carboxy-terminal six amino acids of this peptide correspond in sequence to that deduced for the carboxy terminus of the p60src of the Schmidt-Ruppin strain of Rous sarcoma virus of subgroup A. The p60src proteins of the several strains of Rous sarcoma virus and the cellular homolog of the viral transforming protein, p60c-src, comprise a polymorphic family of polypeptides. The anticarboxy-terminal serum reacted readily with the p60src proteins of three different strains of Rous sarcoma virus. In contrast, no precipitation of cellular p60c-src could be detected with this serum. This suggests that the viral p60src proteins have identical carboxy termini and that the carboxy terminus of cellular p60c-src may be different from that of viral p60src. The anticarboxy-terminal serum reacted poorly with the subpopulation of viral p60src which is present in a complex with two cellular phosphoproteins. Apparently, the presence of the two cellular proteins interferes with the recognition of p60src by the anticarboxy-terminal serum. It seems likely, therefore, that these two cellular proteins bind to the carboxy-terminal domain of p60src.     

Effect of p15-associated protease from an avian RNA tumor virus on avian virus-specific polyprotein precursors.

A proteolytic activity is associated with structural protein p15 in avian RNA tumor viruses. Its effect on the known intracellular viral polyprotein precursors obtained by immunoprecipitation was investigated. Cleavage of Pr76gag resulted in the sequential appearance of p15, p27, and p19. The intracellular precursor Pr180gag-pol was also cleaved by p15, whereas the intracellular glycoprotein precursors of avian RNA tumor viruses, Pr92env, remained unaffected by p15 under all conditions tested. The specificities of the antibodies used to precipitate the precursors influenced the pattern of intermediates and cleavage products obtained by p15 treatment. If virus harvested from the the Prague strain of Rous sarcoma virus, subgroup C-transformed cells at 15-min intervals was incubated at 37 degrees C for further maturation, RNA-dependent DNA polymerase activity showed an optimum of DNA synthesis with 70S viral RNA or synthetic template-primers after short incubation periods. The presence of additional p15 during incubation resulted in a shift of the enzyme activity peak toward earlier time points. Virus harvested at 3-h intervals contained significant amounts of Pr180gag-pol and Pr76gag. The addition of p15 resulted in the cleavage of Pr180gag-pol and Pr76gag, but only a few distinct low-molecular-weight polypeptides appeared. Treatment of purified RNA-dependent DNA polymerase with p15 in vitro resulted in a disappearance of the beta subunit and an enrichment of the alpha subunit. In addition, a polypeptide of 32 x 10(3) molecular weight was generated. The cleavage pattern observed differed from the one obtained by trypsin treatment.     

Sequence of the Long Terminal Repeat and Adjacent Segments of the Endogenous Avian Virus Rous-Associated Virus 0

Rous-associated virus 0 (RAV-0), an endogenous chicken virus, does not cause disease when inoculated into susceptible domestic chickens. An infectious unintegrated circular RAV-0 DNA was molecularly cloned, and the sequence of the long terminal repeat (LTR) and adjacent segments was determined. The sequence of the LTR was found to be very similar to that of replication-defective endogenous virus EV-1. Like the EV-1 LTR, the RAV-0 LTR is smaller (278 base pairs instead of 330) than the LTRs of the oncogenic members of the avian sarcoma virus-avian leukosis virus group. There is, however, significant homology. The most striking differences are in the U(3) region of the LTR, and in this region there are a series of small segments present in the oncogenic viruses which are absent in RAV-0. These differences in the U(3) region of the LTR could account for the differences in the oncogenic potential of RAV-0 and the avian leukosis viruses. I also compared the regions adjacent to the RAV-0 LTR with the available avian sarcoma virus sequences. A segment of approximately 200 bases to the right of the LTR (toward gag) is almost identical in RAV-0 and the Prague C strain of Rous sarcoma virus. The segment of RAV-0 which lies between the end of the env gene and U(3) is approximately 190 bases in length. Essentially this entire segment is present between env and src in the Schmidt-Ruppin A strain of Rous sarcoma virus. Most of this segment is also present between env and src in Prague C; however, in Prague C there is an apparent deletion of 40 bases in the region adjacent to env. In Schmidt-Ruppin A, but not in Prague C, about half of this segment is also present between src and the LTR. This arrangement has implications for the mechanism by which src was acquired. The region which encoded the gp37 portion of env appears to be very similar in RAV-0 and the Rous sarcoma viruses. However, differences at the very end of env imply that the carboxy termini of RAV-0, Schmidt-Ruppin A, and Prague C gp37s are significantly different. The implications of these observations are considered.     

The second oncogene mil of avian retrovirus MH2 is related to the src gene family.

The nucleotide sequence of a PstI fragment prepared from a cloned MH2 virus genome, pMH2-Hd, has been deduced using chemical and enzymatic methods. This fragment, 1862 nucleotides in length, starts with the gag gene, encodes the v-mil sequence and stops within the v-myc gene. This sequence shows that the v-mil gene is fused to the gag gene giving rise to a fused polyprotein of 98 000 daltons: 515 amino acids at the amino terminus would correspond to p10, p19, p27 and part of p12 determinants, 347 amino acids at the carboxy terminus correspond to the v-mil specific sequence. The mil protein shares homology with a number of onc proteins such as src, fes, fms, mos, yes, fps and erbB, as well as with the catalytic chain of the cAMP-dependent protein kinase. This PstI fragment also encodes the beginning of the myc gene which was integrated in MH2 along with the 3' end of the preceding intron placing an acceptor splice site in front of the used open reading frame. As deduced from the sequence, the MH2 myc protein is not identical to the MC29 myc protein. It differs at its amino terminus, which contains little or no gag determinants, depending on the ATG used to initiate translation.     

Positionally independent and exchangeable late budding functions of the Rous sarcoma virus and human immunodeficiency virus Gag proteins.

The Gag proteins of Rous sarcoma virus and human immunodeficiency virus (HIV) each contain a function involved in a late step in budding, defects in which result in the accumulation of these molecules at the plasma membrane. In the Rous sarcoma virus Gag protein (Pr76gag), this assembly domain is associated with a PPPY motif, which is located at an internal position between the MA and CA sequences. This motif is not contained anywhere within the HIV Gag protein (Pr55gag), and the MA sequence is linked directly to CA. Instead, a late assembly function of HIV has been associated with the p6 sequence situated at the C terminus of Gag. Here we demonstrate the remarkable finding that the late assembly domains from these two unrelated Gag proteins are exchangeable between retroviruses and can function in a positionally independent manner.     

Characterization of Rous sarcoma virus-related sequences in the Japanese quail.

We detected sequences related to the avian retrovirus Rous sarcoma virus within the genome of the Japanese quail, a species previously considered to be free of endogenous avian leukosis virus elements. Using low-stringency conditions of hybridization, we screened a quail genomic library for clones containing retrovirus-related information. Of five clones so selected, one, lambda Q48, contained sequence information related to the gag, pol, and env genes of Rous sarcoma virus arranged in a contiguous fashion and spanning a distance of approximately 5.8 kilobases. This organization is consistent with the presence of an endogenous retroviral element within the Japanese quail genome. Use of this element as a high-stringency probe on Southern blots of genomic digests of several quail DNA demonstrated hybridization to a series of high-molecular-weight bands. By slot hybridization to quail DNA with a cloned probe, it was deduced that there were approximately 300 copies per diploid cell. In addition, the quail element also hybridized at low stringency to the DNA of the White Leghorn chicken and at high stringency to the DNAs of several species of jungle fowl and both true and ruffed pheasants. Limited nucleotide sequencing analysis of lambda Q48 revealed homologies of 65, 52, and 46% compared with the sequence of Rous sarcoma virus strain Prague C for the endonuclease domain of pol, the pol-env junction, and the 3'-terminal region of env, respectively. Comparisons at the amino acid level were also significant, thus confirming the retrovirus relatedness of the cloned quail element.     

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein.

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.     

The avian retrovirus env gene family: molecular analysis of host range and antigenic variants.

The nucleotide sequence of the env gp85-coding domain from two avian sarcoma and leukosis retrovirus isolates was determined to identify host range and antigenic determinants. The predicted amino acid sequence of gp85 from a subgroup D virus isolate of the Schmidt-Ruppin strain of Rous sarcoma virus was compared with the previously reported sequences of subgroup A, B, C, and E avian sarcoma and leukosis retroviruses. Subgroup D viruses are closely related to the subgroup B viruses but have an extended host range that includes the ability to penetrate certain mammalian cells. There are 27 amino acid differences shared between the subgroup D sequence and three subgroup B sequences. At 16 of these sites, the subgroup D sequence is identical to the sequence of one or more of the other subgroup viruses (A, C, and E). The remaining 11 sites are specific to subgroup D and show some clustering in the two large variable regions that are thought to be major determinants of host range. Biological analysis of recombinant viruses containing a dominant selectable marker confirmed the role of the gp85-coding domain in determining the host range of the subgroup D virus in the infection of mammalian cells. We also compared the sequence of the gp85-coding domain from two subgroup A viruses, Rous-associated virus type 1 and a subgroup A virus of the Schmidt-Ruppin strain of Rous sarcoma virus. The comparison revealed 24 nonconservative amino acid changes, of which 6 result in changes in potential glycosylation sites. The positions of 10 amino acid differences are coincident with the positions of 10 differences found between two subgroup B virus env gene sequences. These 10 sites identify seven domains in the sequence which may constitute determinants of type-specific antigenicity. Using a molecular recombinant, we demonstrated that type-specific neutralization of two subgroup A viruses was associated with the gp85-coding domain of the virus.     

Phosphorylation of the avian retrovirus integration protein and proteolytic processing of its carboxyl terminus.

The integration protein (IN) of the Prague A strain of Rous sarcoma virus (RSV) was analyzed by high-resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three polypeptides of similar proportions and molecular mass (32 kDa) were immunoprecipitated by an antiserum directed against the first 10 amino acids of the amino terminus of IN. However, the faster-migrating nonphosphorylated polypeptide was not immunoprecipitated by two different polyclonal antisera directed against the last 11 amino acids of the carboxyl terminus of IN. These results suggest that the faster-migrating species was proteolytically processed at its carboxyl terminus. RSV IN is phosphorylated on an S residue located five amino acids from its carboxyl terminus. Two different missense mutations at this S residue resulted in the isolation of slow-growing viable mutants whose phenotypes were stable. Each mutation at residue 282 eliminated both major phosphorylated-Ser-containing tryptic peptides observed with wild-type IN. An S----F mutation resulted in the conversion of all IN polypeptides to one species that was not precipitable by carboxyl-terminal antisera, suggesting that this amino acid transition promoted proteolysis at the carboxyl terminus. An S----D mutation resulted in the recovery of one major (greater than 95%) slower-migrating polypeptide that was immunoprecipitated by carboxyl-terminal antisera, suggesting that this negatively charged D residue (similar to phosphorylated Ser) inhibited proteolysis. Modification of the S residue at amino acid 262 to R had no apparent effect on the proteolytic processing or phosphorylation of IN.     

Feline sarcoma virus-coded polyprotein: enzymatic cleavage by a type C virus-coded structural protein.

A purified 15,000-molecular-weight (Mr) Prague strain Rous sarcoma virus gag gene-coded structural protein, p15, was shown to enzymatically cleave the previously described 130,000 Mr feline sarcoma virus-coded polyprotein, Pr130. Cleavage products included proteins ranging in molecular weight from 12,000 to 110,000. The specificity of this cleavage reactivity was indicated by the fact that, under similar conditions, neither purified type C viral structural proteins nor nonviral proteins such as bovine serum albumin were cleaved to significant extents. Moreover, feline leukemia virus Pr65gag was efficiently cleaved, resulting in the generations of proteins of 30,000 (p30), 15,000 (p15), 12,000 (p12), and 10,000 (p10) Mr. Using enzymatically (p15) treated feline sarcoma virus Pr130 as starting material, we were able to purify a major 72,000 Mr cleavage product and to show it to contain the previously described feline sarcoma virus-coded nonstructural component.