Mutations in Rous sarcoma virus nucleocapsid protein p12 (NC): deletions of Cys-His boxes.

Rous sarcoma virus nucleocapsid protein p12 (NC) contains two conserved amino acid motifs, the Cys-His boxes, which constitute potential metal-binding domains. To try to understand the function of NC and of each of its Cys-His boxes during the viral life cycle, particularly in viral RNA packaging, we have used synthetic oligonucleotides to delete precisely either the proximal or the distal box, or both Cys-His boxes. The mutant DNAs were transfected into chicken embryo fibroblasts, and the virions produced in a transient assay were characterized biochemically for production of viral proteins and particles, RNA packaging, and infectivity. The results indicated the following. (i) The deletion of either the proximal or the distal box decreases the amount of viral RNA packaged in the particles and results in incomplete 70S dimer formation. (ii) The deletion of both boxes inhibits viral RNA packaging. (iii) The deletion of the proximal, but not the distal, box suppresses any detectable infectivity, while the deletion of the distal, but not the proximal, box lowers infectivity 100 to 200 times.     

Effect of rearrangements and duplications of the Cys-His motifs of Rous sarcoma virus nucleocapsid protein.

It has been widely documented that the nucleocapsid protein p12 (NC) of Rous sarcoma virus (RSV) has a role in the encapsidation and maturation of the virus genomic RNA during particle formation, and particularly important appear to be the Cys-His motifs of this protein. Since some retroviruses only have one such motif, we have investigated the significance of the two distinct Cys-His motifs of RSV NC. The analysis of the phenotype of virus NC mutants with precise rearrangements or duplications of the motifs highlights the following features. (i) The two motifs are not functionally equivalent. (ii) The order and number of Cys-His motifs are less important for RSV NC than the presence of two distinct motifs for both the encapsidation of virus genomic RNA and maintenance of the integrity of the RNA after particle formation. (iii) The proximal motif has a distinct function in the virus replication cycle other than RNA encapsidation and dimerization. (iv) The presence of three Cys-His motifs reduces virus infectivity and leads to high-frequency deletion events (of one of the motifs) after infection: the resulting RNA species encode a wild type-like NC protein restoring full infectivity to the progeny virus particles. Additionally, the data suggest that this occurs only after infection. The deletion probably arises by intramolecular displacement of the replication complex between repeat sequences.     

Characterization of unstable poly (A)-RNA in Caulobacter crescentus

Antabuse (disulfiram) is widely used in the treatment of chronic alcoholism. We have examined the effect of this drug on malignant transformation by Rous sarcoma virus, on eukaryotic cell synthesis, and on nucleic acid binding. It was found that: (1) Disulfiram inhibits the activity of the RNA dependent DNA polymerase of Rous sarcoma virus and inactivates the ability of the virus to malignantly transform chick embryo cells. The monomer of disulfiram, diethyldithiocarbamate does not affect the virus. (2) Disulfiram induced the synthesis of four proteins in normal chick embryo and human foreskin cells. The monomer diethyldithiocarbamate, induced these proteins also. Cellular DNA synthesis is more sensitive to disulfiram than are RNA and protein synthesis. (3) Disulfiram binds to neither DNA or RNA in the presence or absence of copper. However, diethyldithiocarbamate in the presence of, but not in the absence of, copper binds to HeLa cell DNA and to Rous sarcoma virus 70 S genome RNA. These results indicate that this compound, which causes no symptoms in people who do not consume alcohol, may have significant effects on a cellular level.     

The genome-associated,specific RNA binding proteins of avian and mammalian type C viruses

A structural protein purified from the Rous sarcoma virus (RSV) can specifically bind in vitro to purified avian, but not mammalian, type C viral RNA. Following ultraviolet irradiation of viral particles under conditions which stabilize the polyploid 70S viral RNA, the same polypeptide can be directly purified from the RSV genome. Based on its electrophoretic mobility in polyacrylamide gels containing sodium dodecylsulfate, the RNA binding protein has been identified as the major phosphoprotein (p19) of avian type C viruses. Similar experiments show that the major phosphoproteins of mammalian type C viruses (p12 for murine viruses and p16 for endogenous primate viruses) are also the specific RNA binding proteins and, similarly, are found closely associated with the 70S RNA genomes in the intact viral particles.     

Effect of isonicotinic acid hydrazide-copper complex on Rous sarcoma virus and its genome RNA.

The copper complex of the antituberculous drug, insonicotinic acid hydrazide (INH), inhibits the RNA-dependent DNA polymerase of Rous sarcoma virus and inactivates its ability to malignantly transform chick embryo cells. The INH-copper complex binds to the 70S genome RNA of Rous sarcoma virus (RSV), which may account for its ability to inhibit the RNA-dependent DNA polymerase. The complex binds RNA more effectively than DNA in contrast to M-IBT-copper complexes, which bind both types of nucleic acids equally. The homopolymers, poly rA and poly rU, are bound by the INH-copper complex to a greater extent than poly rC. Isonicotinic acid hydrazide alone and CuSO4 alone bind neither DNA, RNA, poly (rA), poly (rU), nor poly (rC). However, CuSO4 alone binds poly (rI); INH alone does not. In addition to viral DNA synthesis, chick-embryo cell DNA synthesis is inhibited by the INH-copper complex. The extent of inhibition of cellular DNA synthesis is greater than that of cellular RNA and protein synthesis. No selective inhibition of transformation in cells previously infected with Rous sarcoma virus is observed.     

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.     

Appearance of virus-specific DNA in mammalian cells following transformation by Rous sarcoma virus

To detect Rous sarcoma virus-specific DNA in mammalian cells, we have measured the capacity of unlabeled cell DNA to accelerate the reassociation of labeled double-stranded DNA synthesized by the Rous sarcoma virus RNA directed DNA polymerase. Two populations of double-stranded polymerase products are identified by their reassociation kinetics and represent approximately 5% and 30% of the viral 70 S RNA genome. Using two strains of Rous sarcoma virus and four lines of transformed mammalian cells, we found two copies of DNA homologous to both DNA populations in Rous sarcoma virustransformed rat and mouse cells, but not in normal cells. The Rous sarcoma viruslike DNA can be demonstrated in the non-repeated fraction of transformed cell DNA and in nuclear DNA. The results are supported by evidence that the techniques employed detect the formation of extensive well-matched duplexes of cell DNA and viral polymerase products.     

Characterization of ribosome binding on Rous sarcoma virus RNA in vitro.

We determined the sites at which ribosomes form initiation complexes on Rous sarcoma virus RNA in order to determine how initiation of Pr76gag synthesis at the fourth AUG codon from the 5' end of Rous sarcoma virus strain SR-A RNA occurs. Ribosomes bind almost exclusively at the 5'-proximal AUG codon when chloride is present as the major anion added to the translational system. However, when chloride is replaced with acetate, ribosomes bind at the two 5'-proximal AUG codons, as well as at the initiation site for Pr76gag. We confirmed that the 5'-proximal AUG codon is part of a functional initiation site by identifying the seven-amino acid peptide encoded there. Our results suggest that (i) translation in vitro of Rous sarcoma virus virion RNA results in the synthesis of at least two polypeptides; (ii) the pattern of ribosome binding observed for Rous sarcoma virus RNA can be accounted for by the modified scanning hypothesis; and (iii) the interaction between 40S ribosomal subunits or 80S ribosomal complexes is stronger at the 5'-proximal AUG codon than at sites farther downstream, including the initiation site for the major viral proteins.     

Importance of basic residues in binding of rous sarcoma virus nucleocapsid to the RNA packaging signal

In the context of the Rous sarcoma virus Gag polyprotein, only the nucleocapsid (NC) domain is required to mediate the specificity of genomic RNA packaging. We have previously showed that the Saccharomyces cerevisiae three-hybrid system provides a rapid genetic assay to analyze the RNA and protein components of the avian retroviral RNA-Gag interactions necessary for specific encapsidation. In this study, using both site-directed mutagenesis and in vivo random screening in the yeast three-hybrid binding assay, we have examined the amino acids in NC required for genomic RNA binding. We found that we could delete either of the two Cys-His boxes without greatly abrogating either RNA binding or packaging, although the two Cys-His boxes are likely to be required for efficient viral assembly and release. In contrast, substitutions for the Zn-coordinating residues within the boxes did prevent RNA binding, suggesting changes in the overall conformation of the protein. In the basic region between the two Cys-His boxes, three positively charged residues, as well as basic residues flanking the two boxes, were necessary for both binding and packaging. Our results suggest that the stretches of positively charged residues within NC that need to be in a proper conformation appear to be responsible for selective recognition and binding to the packaging signal (Psi)-containing RNAs.     

RNA-directed DNA polymerase of Rous sarcoma virus: initiation of synthesis with 70 S viral RNA as template

DNA synthesis by the RNA-directed DNA polymerase of Rous sarcoma virus with 70 S viral RNA as template initiates by the covalent attachment of dAMP to the 3′ terminal adenosine of an RNA molecule. Initiation continues throughout the course of a 90-minute enzymatic reaction, and chain propagation occurs on most if not all of the dAMP residues attached to primer RNA. The nature of the primer molecules was established in two ways. First, the RNA was tagged by attachment of radioactive mono- and oligodeoxynucleotides. Second, primers were isolated directly from their covalent complexes with nascent DNA. The results of both procedures indicate that DNA synthesis initiates on the 3′ termini of 4 S RNA molecules hydrogen-bonded to 70 S RNA. Purified primer RNA has a nucleotide composition (G + C = 64%) different from that (G + C = 60%) of other 4 S RNAs found hydrogen-bonded to the 70 S RNA of Rous sarcoma virus.     

Comparison of the expression of the src gene of Rous sarcoma virus in vitro and in vivo.

We have compared the polypeptide products of the src gene of several strains of Rous sarcoma virus produced by in vitro translation of heat-denatured 70S virion RNA in the nuclease-treated reticulocyte lysate with those present in chick cells transformed by these viruses. We have done this by immunoprecipitation, using sera from rabbits injected at birth with Schmidt-Ruppin Rous sarcoma virus. In vitro translation results in the synthesis of at least nine polypeptides which appear to be encoded by the src gene. These range in size from 17,000 to 60,000 daltons. The sera from tumor-bearing rabbits precipitated these polypeptides arising from the in vitro translation of RNA from Schmidt-Ruppin Rous sarcoma virus of both subgroup A and subgroup D and from one stock of Prague Rous sarcoma virus of subgroup C. In each case, all of this family of related polypeptides could be precipitated except the smallest, the 17,000-dalton polypeptide. No precipitation of analogous polypeptides resulting from the translation of RNA from other strains of Rous sarcoma virus was observed. Cells transformed by these three strains of Rous sarcoma virus contain easily detectable amounts of a polypeptide, p60src, essentially identical to the 60,000-dalton in vitro product. With one exception, they do not contain significant amounts of polypeptides analogous to the smaller in vitro products which can be precipitated by these sera. Cells transformed by one stock of Schmidt-Ruppin Rous sarcoma virus of subgroup A did contain a 39,000-dalton polypeptide, which was related, by peptide mapping, to the 60,000-dalton polypeptide and was similar in size to a precipitable in vitro product. The 60,000-dalton polypeptide present in transformed cells appeared to be phosphorylated 10 to 25 min after its synthesis, metabolically very stable, and not derived from a precursor polypeptide. All immunoprecipitates from transformed cells which contained p60src also contained an 80,000-dalton phosphoprotein. This polypeptide is unrelated to p60src, as determined by peptide mapping, and may well be a host cell polypeptide which is specifically associated with p60src.     

Precise localization of m6A in Rous sarcoma virus RNA reveals clustering of methylation sites: implications for RNA processing.

N6-methyladenosine (m6A) residues are present as internal base modifications in most higher eucaryotic mRNAs; however, the biological function of this modification is not known. We describe a method for localizing and quantitating m6A within a large RNA molecule, the genomic RNA of Rous sarcoma virus. Specific fragments of 32P-labeled Rous sarcoma virus RNA were isolated by hybridization with complementary DNA restriction fragments spanning nucleotides 6185 to 8050. RNA was digested with RNase and finger-printed, and individual oligonucleotides were analyzed for the presence of m6A by paper electrophoresis and thin-layer chromatography. With this technique, seven sites of methylation in this region of the Rous sarcoma virus genome were localized at nucleotides 6394, 6447, 6507, 6718, 7414, 7424, and 8014. Further, m6A was observed at two additional sites whose nucleotide assignments remain ambiguous. A clustering of two or more m6A residues was seen at three positions within the RNA analyzed. Modification at certain sites was found to be heterogeneous, in that different molecules of RNA appeared to be methylated differently. Previous studies have determined that methylation occurs only in the sequences Gm6AC and Am6AC. We observed a high frequency of methylation at PuGm6ACU sequences. The possible involvement of m6A in RNA splicing events is discussed.     

Site-directed mutagenesis of the avian retrovirus nucleocapsid protein, pp 12, at Serine 40, the primary site of phosphorylation in vivo

The major nucleocapsid protein of avian retroviruses, pp 12, binds to single-stranded viral RNA with high affinity. Phosphorylation at Ser-40 is necessary for this binding. In order to examine the role of phosphorylation of serine 40 in the biological function of pp 12, we have introduced a series of amino acid substitutions at this position in the Rous sarcoma virus (Pr-C) protein. Substitution of threonine, alanine, or three other amino acids for Ser-40 had very little or no detectable effect on viral replication, nor did the control substitution of glycine for Ser-43, a nonphosphorylated residue. In vivo and in vitro, the Ala-40 and probably the Thr-40 substituted p 12 proteins are phosphorylated at alternative sites which are phosphorylated to a minor extent in vivo in the wild type protein. A study of the RNA binding properties of Ala-40 substituted p 12 has indicated that the protein has been stabilized in a high affinity RNA binding state which is independent of phosphorylation. The viability of the Ala-40 mutant virus indicates that this high binding affinity may be required for biological activity.     

Product of in vitro translation of the Rous sarcoma virus src gene has protein kinase activity.

In vitro translation of Rous sarcoma virus virion RNA resulted in the synthesis of a protein kinase which, when immunoprecipitated with antitumor serum, phosphorylated the immunoglobulin heavy chain. Even though in vitro translation of virion RNA resulted in the synthesis of a number of polypeptides which were recognized by antitumor serum, control experiments demonstrated that an immunoprecipitable protein kinase activity was found only when an immunoprecipitable p60src, the polypeptide product of the src gene, was synthesized. A protein kinase with similar properties was therefore intimately associated with p60src which was synthesized in vitro in the reticulocyte lysate, just as it is with p60src which is obtained from transformed chick and mammalian cells. It is therefore highly unlikely that this association is artifactual. ts NY68 is a mutant of Rous sarcoma virus which is able to transform cells at 36 but not at 41 degrees C. In vitro translation of ts NY68 virion RNA at 30 degrees C resulted in efficient synthesis of immunoprecipitable p60src, but very inefficient synthesis of an immunoprecipitable protein kinase. The p60src obtained by in vitro translation of wild-type virion RNA was more than 20-fold more active as a protein kinase than was that obtained from ts NY68 RNA. The correlation in the case of ts NY68 of a deficiency in protein kinase activity with an inability to transform cells at high temperature suggests that the protein kinase activity associated with p60src is indeed critical to cellular transformation.     

Phosphorylation of the transforming protein of Rous sarcoma virus: direct demonstration of phosphorylation of serine 17 and identification of an additional site of tyrosine phosphorylation in p60v-src of Prague Rous sarcoma virus.

We provide direct evidence that serine 17 is the major site of serine phosphorylation in p60v-src, the transforming protein of Rous sarcoma virus, and in its cellular homolog, p60c-src. The amino acid composition of the tryptic peptide containing the major site of serine phosphorylation in p60v-src was deduced by peptide map analysis of the protein labeled biosynthetically with a variety of radioactive amino acids. Manual Edman degradation revealed that the phosphorylated serine in this peptide was the amino terminal residue. These data are consistent only with the phosphorylation of serine 17. The major site of serine phosphorylation in chicken p60c-src, the cellular homolog of p60v-src, is contained in a tryptic peptide identical to that containing serine 17 in p60v-src of Schmidt Ruppin Rous sarcoma virus of subgroup A. Serine 17 is therefore also phosphorylated in p60c-src. The p60v-src protein encoded by Prague Rous sarcoma virus was found to contain two sites of tyrosine phosphorylation. The previously unrecognized site of tyrosine phosphorylation may be tyrosine 205 or possibly tyrosine 208. Treatment of Prague Rous sarcoma virus-infected cells with vanadyl ions stimulated the protein kinase activity of p60v-src and increased the phosphorylation of tyrosine 416 but not the phosphorylation of the additional site of tyrosine phosphorylation.