Evidence of methylation of B77 avian sarcoma virus genome RNA subunits.

B77 avian sarcoma virus RNA was labeled with (methyl-3H) methionine under conditions that prevent non-methyl incorporation of 3H radioactivity into purine rings. From the determined values for the extent of methylation of 4S RNA isolated from infected chicken embryo cells, it was estimated that 30 to 40S RNA subunits that results from heat denaturation of the 60 to 70S RNA contain approximately 21 methyl groups, of which 14 to 16 are present at internal positions as N6 -methyladenosine residues. In addition, each of the virion RNA subunits appears to contain about two methyl groups in the "capped" 5' -terminal structure m7G(5')ppp(5') gm. These properties are consistent with the hypothesis that the 30 to 40S genome RNA os oncornaviruses also serves an mRNA function in infected cells.     

Sequence specificity of internal methylation in B77 avian sarcoma virus RNA subunits.

Following ribonuclease digestion of methyl-3H-labeled B77 avian sarcoma virus RNA subunits, methylated oligonucleotides were isolated by diethylaminoethylcellulose chromotogrpahy. Partial nucleotide sequences were deduced from the known enzymatic specificities of the ribonucleases. In addition to methylated nucleosides in the 5'-terminal cap structure, m7G(5')GmpCp, N6-methyladenosine(m6A) was found to be present in only two internal sequences of the RNA molecule, Gpm6ApC and Apm6ApC. The average numbers of methylated nucleosides per RNA subunit are about 12-13 in Gpm6ApC, 1-2 in Apm6ApC, and 2 in m7GpppGmpCp. The sequences containing m6A in B77 sarcoma virus RNA are identical to m6A-containing sequences previously reported for the bulk mRNA from HeLa cells (Wei, C.M., Gershowitz, A., and Moss, B. (1976), Biochemistry 15, 397-401). Analysis of the oligonucleotides produced by RNase A digestion indicated that the sequence of bases on the 5' side of these trinucleotides is not specific. The oligonucleotide profile, however, was highly reproducible in different virus preparations. This suggests that the methylations occur at specific positions on the RNA molecule. Some of the methylated oligonucleotides produced by RNase A digestion appear to be present in less than molar amounts. Several hypotheses are proposed to explain this result.     

Expression of the PRC II avian sarcoma virus genome.

We found that the genomic RNA of the replication-defective avian sarcoma virus PRC II was 4.0 kilobases long. A Northern blot analysis of the viral RNAs present in PRC II-transformed cells showed that the PRC II genome was expressed as a single 4.0 kilobase mRNA species. In vitro translation of polyadenylic acid-containing 70S virion RNA yielded two highly related proteins of 110,000 and 105,000 daltons (P110 and P105), which were synthesized from messenger activity that sedimented as expected for the 4.0 kilobase PRC II genome (at 25 to 27S). P110 and P105 were identified as in vitro translation products of the PRC II genome by immunoprecipitation and tryptic peptide mapping and were the only PRC II-specific polypeptides detected by in vitro synthesis. In addition, we found that immune complexes prepared from PRC II 70S virion RNA in vitro translation products contained a tyrosine-specific protein kinase activity. A comparison of the in vitro- and in vivo-synthesized proteins revealed that PRC II-transformed cells also contained 110,000- and 105,000-dalton proteins, which were indistinguishable from in vitro-synthesized P110 and P105 by electrophoretic mobility and tryptic peptide analysis. Both P110 and P105 were present in producer cells and in seven individual nonproducer clones. A pulse-chase analysis showed that P105 was the primary translation product of the PRC II genome and that P110 was derived from P105 by post-translational modification. Under conditions of long-term labeling with [35S]methionine, P110 and P105 were present in a molar ratio of approximately 1:1. These results indicated that the transformation-specific product of the PRC II genome, previously referred to as a single component (P105), actually consists of two polypeptides related by post-translational modification.     

Translation of avian sarcoma virus RNA in Xenopus laevis oocytes.

Evidence for the synthesis and processing of Pr76 (precursor to group-specific antigens p27, p19, and $\text{p12}\text{15}$, upon injection of avian sarcoma virus 70S or 35S RNA into $\text{Xenopus}$ oocytes has been presented. Further, we show that tRNA^trp primer, bound to 35S RNA, does not block translation of virion RNA under these conditions.     

5'-terminal phosphorylation and secondary structure of double-stranded RNA from a fungal virus.

Different double-stranded RNA species from Penicillium stoloniferum virus have been phosphorylated at the 5′ termini with the aid of polynucleotide kinase. A very low phosphate uptake has been observed which, especially in the case of a relatively small molecular component, was increased several times by pretreatment with RNAase t₁. Adenosine and uridine have been detected at the 5′-termini of this RNA component. Digestion with RNAase T₁, an enzyme which does not cut across the two strands of a double-stranded RNA molecule, produced a new uridine terminus and increased the efficiency of phosphorylation. It is concluded that this double-stranded RNA molecule contains single-stranded stretches at or near the 5′-termini. The possibility of a circular structure being formed by the annealing of single-stranded tails is discussed.     

The 5'-terminal region of the Aichi virus genome encodes cis-acting replication elements required for positive- and negative-strand RNA synthesis

Aichi virus is a member of the family Picornaviridae. It has already been shown that three stem-loop structures (SL-A, SL-B, and SL-C, from the 5' end) formed at the 5' end of the genome are critical elements for viral RNA replication. In this study, we further characterized the 5'-terminal cis-acting replication elements. We found that an additional structural element, a pseudoknot structure, is formed through base-pairing interaction between the loop segment of SL-B (nucleotides [nt] 57 to 60) and a sequence downstream of SL-C (nt 112 to 115) and showed that the formation of this pseudoknot is critical for viral RNA replication. Mapping of the 5'-terminal sequence of the Aichi virus genome required for RNA replication using a series of Aichi virus-encephalomyocarditis virus chimera replicons indicated that the 5'-end 115 nucleotides including the pseudoknot structure are the minimum requirement for RNA replication. Using the cell-free translation-replication system, we examined the abilities of viral RNAs with a lethal mutation in the 5'-terminal structural elements to synthesize negative- and positive-strand RNAs. The results showed that the formation of three stem-loops and the pseudoknot structure at the 5' end of the genome is required for negative-strand RNA synthesis. In addition, specific nucleotide sequences in the stem of SL-A or its complementary sequences at the 3' end of the negative-strand were shown to be critical for the initiation of positive-strand RNA synthesis but not for that of negative-strand synthesis. Thus, the 5' end of the Aichi virus genome encodes elements important for not only negative-strand synthesis but also positive-strand synthesis.     

Structure and membrane interaction of the internal fusion peptide of avian sarcoma leukosis virus.

The structure and membrane interaction of the internal fusion peptide (IFP) fragment of the avian sarcoma and leucosis virus (ASLV) envelope glycoprotein was studied by an array of biophysical methods. The peptide was found to induce lipid mixing of vesicles more strongly than the fusion peptide derived from the N-terminal fusion peptide of influenza virus (HA2-FP). It was observed that the helical structure was enhanced in association with the model membranes, particularly in the N-terminal portion of the peptide. According to the infrared study, the peptide inserted into the membrane in an oblique orientation, but less deeply than the influenza HA2-FP. Analysis of NMR data in sodium dodecyl sulfate micelle suspension revealed that Pro13 of the peptide was located near the micelle-water interface. A type II beta-turn was deduced from NMR data for the peptide in aqueous medium, demonstrating a conformational flexibility of the IFP in analogy to the N-terminal FP such as that of gp41. A loose and multimodal self-assembly was deduced from the rhodamine fluorescence self-quenching experiments for the peptide bound to the membrane bilayer. Oligomerization of the peptide and its variants can also be observed in the electrophoretic experiments, suggesting a property in common with other N-terminal FP of class I fusion proteins.     

Transfer of defective avian tumor virus genomes by a Rous sarcoma virus RNA packaging mutant.

SE21Q1b, a Rous sarcoma virus mutant which packages cellular rather than viral RNA, is competent for infection of quail cells and can transmit defective transforming retrovirus genes. Stably transformed recipient clones have been obtained by using this mutant.     

A base-paired structure in the avian sarcoma virus 5' leader is required for efficient encapsidation of RNA.

Selective encapsidation of avian sarcoma-leukosis virus genomic RNA within virions requires recognition of a cis-acting signal (termed psi) located in the 5' leader of the RNA between the primer binding site and the splice donor site. Computer analyses indicate the potential for numerous secondary structure interactions within this region, including alternative conformations with similar free energy levels. We have constructed mutations designed to disrupt and restore potential secondary structure interactions within psi to investigate the role of these structures in RNA packaging. To test for the ability of psi mutants to package a heterologous reporter gene into virions, chimeric constructs bearing avian sarcoma virus 5' sequences fused to lacZ were transiently cotransfected with a nonpackageable helper construct into chicken embryo fibroblasts. lacZ virions produced from cotransfected cells were used to infect new cultures of chicken embryo fibroblasts, and then an in situ assay for individual cells expressing lacZ was done. Results obtained with this assay were confirmed in direct analyses of isolated virion RNA by RNase protection assays. Two mutations, predicted to disrupt a potential stem structure forming between elements located at nucleotides 160 to 167 and 227 to 234, severely inhibited packaging when either element was mutated. A construct in which these mutations were combined to restore potential base pairing between the two elements displayed a partially restored packaging phenotype. These results strongly suggest that the structure, referred to as the O3 stem, is required for efficient encapsidation of avian sarcoma virus RNA. Site-directed mutagenesis of additional sequence elements located in the O3 loop reduced packaging as measured by the indirect assay, suggesting that these sequences may also be components of the encapsidation signal. The possible implications of the O3 stem structure with regard to translation of avian sarcoma-leukosis virus short upstream open reading frames are discussed.     

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.