Nature of Rous sarcoma virus-specific RNA in transformed and revertant field vole cells.

Cytoplasmic and polyribosomal RNAs from Rous sarcoma virus-transformed and phenotypically reverted field vole cells were fractionated by rate-zonal sedimentation and hybridized with a (3)H-labeled complementary DNA viral probe to determine the size classes of virus-specific RNA present in these cell types. In contrast to Rous sarcoma virus-infected permissive avian cells, only two of three discrete species of virus-specific RNA were detected in the cytoplasm of these vole cells. These included genome-length 35S RNA and a 21S RNA. However, viral 28S RNA, routinely detected in the cytoplasm of productively infected avian cells, could not be found in cytoplasmic RNA from vole cells. In addition, a low-molecular-weight viral RNA sedimenting less than 16S was detected in both infected avian and vole cells. Because of its heterogeneity this latter species is most likely generated from the intracellular degradation of the larger viral RNAs. Both the viral 35S and 21S RNA were also found to be associated with total polyribosomes from these vole cells. Studies were also performed to determine the distribution of both total viral genomic and sarcoma-specific RNA sequences among the size classes of fractionated total polyribosomes. In both vole cell types the majority of cytoplasmic viral RNA sequences were also associated with polyribosomes and were similarly distributed among the size classes of total polyribosomes. Sarcoma-specific sequences were present on both the 35S and 21S RNA species. These data suggest that the expression of the viral transforming gene in revertant field vole cells may be controlled at some stage subsequent to translation of the viral RNA.     

The genome of respiratory syncytial virus is a negative-stranded RNA that codes for at least seven mRNA species.

The RNA from purified respiratory syncytial (RS) virions and the RNAs from RS virus-infected cells were isolated and characterized. The RNA from RS virions was found to be a unique species of single-stranded RNA of approximately 5 x 10(6) daltons. Specific annealing experiments demonstrated that at least 93% of the virion RNA was of negative (nonmessage) polarity. Eight major and three minor species of virus-specific RNA were detected in the cytoplasm of RS virus-infected HEp-2 cells. The largest intracellular RNA species comigrated with RNA from purified virions, was not polyadenylated, and was synthesized only in the presence of concomitant protein synthesis. The seven major smaller species of RNA were synthesized in the presence of an inhibitor of protein synthesis. These RNAs were all polyadenylated and were shown to be RS virus specific by their ability to anneal specifically to purified virion RNA. The sum of the sizes of the major RS virus-specific polyadenylated RNAs was sufficient to account for the coding capacity of the RS virus genome (within the limits of reliability of the methods we have used to determine size).     

RNA metabolism of murine leukemia virus: detection of virus-specific RNA sequences in infected and uninfected cells and identification of virus-specific messenger RNA

Virus-specific RNA sequences were detected in mouse cells infected with murine leukemia virus by hybridization with radioactively labeled DNA complementary to Moloney murine leukemia virus RNA. The DNA was synthesized in vitro using the endogenous virion RNA-dependent DNA polymerase and the DNA product was characterized by size and its ability to protect radioactive viral RNA. Virus-specific RNA sequences were found in two lines of leukemia virus-infected cells (JLS-V11 and SCRF 60A) and also in an uninfected line (JLS-V9). Approximately 0.3% of the cytoplasmic RNA in JLS-VII cells was virus-specific and 0.9% of SCRF 60A cell RNA was virus-specific. JLS-V9 cells contained approximately tenfold less virus-specific RNA than infected JLS-VII cells. Moloney leukemia virus DNA completely annealed to JLS-VII or SCRF 60A RNA but only partial annealing was observed with JLS-V9 RNA. This difference is ascribed to non-homologies between the RNA sequences of Moloney virus and the endogenous virus of JLS-V9 cells.Virus-specific RNA was found to exist in infected cells in three major size classes: 60–70 S RNA, 35 S RNA and 20–30 S RNA. The 60–70 S RNA was apparently primarily at the cell surface, since agents which remove material from the cell surface were effective in removing a majority of the 60–70 S RNA. The 35 S and 20–30 S RNA is relatively unaffected by these procedures. Sub-fractionation of the cytoplasm indicated that approximately 35% of the cytoplasmic virus-specific RNA in infected cells is contained in the membrane-bound material. The membrane-bound virus-specific RNA consists of some residual 60–70 S RNA and 35 S RNA, but very little 20–30 S RNA. Virus-specific messenger RNA was identified in polyribosome gradients of infected cell cytoplasm. Messenger RNA was differentiated from other virus-specific RNAs by the criterion that virus-specific messenger RNA must change in sedimentation rate following polyribosome disaggregation. Two procedures for polyribosome disaggregation were used: treatment with EDTA and in vitro incubation of polyribosomes with puromycin in conditions of high ionic strength. As identified by this criterion, the virus-specific messenger RNA appeared to be mostly 35 S RNA. No function for the 20–30 S was determined.     

Size of virus-specific RNA in B-34, a hamster tumor cell producing nucleic acids of type C viruses from three species.

B-34 is the designation of a hamster tumor-derived cell line induced by the Harvey sarcoma virus. This cell line produces virions which contain structural proteins common to edogenous hamster viruses and nucleic acid sequences of hamster, mouse, and rat origin. The sedimentation characteristics of the intracellular virus-specific RNA was determined in sucrose gradients after treatment with dimethylsulfoxide by molecular hybridization using complementary DNA of strict virus specificity. Hamster virus-specific RNA sedimented at 35S (major peak) as is characteristic of productive infection by type C leukemia viruses of other species. Rat virus-specific RNA sedimented at 30S which is characteristic of the sarcoma virus-related genome found in nonproducer cells transformed by Kirsten sarcoma virus. Both Harvey and Kirsten sarcoma viruses contain a related but not necessarily identical 30S rat-specific component which is also found in normal cultured rat cells. Mouse cells producing Harvey sarcoma virus also contain a rat-specific 30S RNA. Mouse virus-derived sequences also sedimented at 30S in B-34 cells and in a similar size range in Harvey virus-infected mouse cells. The possibility that the mouse and rat-derived sequences are present on a single 30S RNA species which would then be related to sarcomagenic potential is one attractive hypothesis suggested by these data.     

Three different cellular proteins bind to complementary sites on the 5'-end-positive and 3'-end-negative strands of mouse hepatitis virus RNA.

The termini of viral genomic RNA and its complementary strand are important in the initiation of viral RNA replication, which probably involves both viral and cellular proteins. To detect the possible cellular proteins involved in the replication of mouse hepatitis virus RNA, we performed RNA-protein binding studies with RNAs representing both the 5' and 3' ends of the viral genomic RNA and the 3' end of the negative-strand complementary RNA. Gel-retardation assays showed that both the 5'-end-positive- and 3'-end-negative-strand RNA formed an RNA-protein complex with cellular proteins from the uninfected cells. UV cross-linking experiments further identified a 55-kDa protein bound to the 5' end of the positive-strand viral genomic RNA and two proteins 35 and 38 kDa in size bound to the 3' end of the negative-strand cRNA. The results of the competition assay confirmed the specificity of this RNA-protein binding. No proteins were found to bind to the 3' end of the viral genomic RNA under the same conditions. The binding site of the 55-kDa protein was mapped within the 56-nucleotide region from nucleotides 56 to 112 from the 5' end of the positive-strand RNA, and the 35- and 38-kDa proteins bound to the complementary region on the negative-strand RNA. The 38-kDa protein was detected only in DBT cells but was not detected in HeLa or COS cells, while the 35-kDa protein was found in all three cell types. The juxtaposition of the different cellular proteins on the complementary sites near the ends of the positive- and negative-strand RNAs suggests that these proteins may interact with each other and play a role in mouse hepatitis virus RNA replication.     

Structure of the intracellular defective viral RNAs of defective interfering particles of mouse hepatitis virus.

The intracellular defective RNAs generated during high-multiplicity serial passages of mouse hepatitis virus JHM strain on DBT cells were examined. Seven novel species of single-stranded polyadenylic acid-containing defective RNAs were identified from passages 3 through 22. The largest of these RNAs, DIssA (molecular weight [mw], 5.2 X 10(6)), is identical to the genomic RNA packaged in the defective interfering particles produced from these cells. Other RNA species, DIssB1 (mw, 1.9 X 10(6) to 1.6 X 10(6)), DIssB2 (mw, 1.6 X 10(6)), DIssC (mw, 2.8 X 10(6)) DIssD (mw, 0.82 X 10(6)), DIssE (mw, 0.78 X 10(6)), and DIssF (mw, 1.3 X 10(6)) were detected at different passage levels. RNase T1-resistant oligonucleotide fingerprinting demonstrated that all these RNAs were related and had multiple deletions of the genomic sequences. They contained different subsets of the genomic sequences from those of the standard intracellular mRNAs of nondefective mouse hepatitis virus JHM strain. Thus these novel intracellular viral RNAs were identified as defective interfering RNAs of mouse hepatitis virus JHM strain. The synthesis of six of the seven normal mRNA species specific to mouse hepatitis virus JHM strain was completely inhibited when cells were infected with viruses of late-passage levels. However, the synthesis of RNA7 and its product, viral nucleoprotein, was not significantly altered in late passages. The possible mechanism for the generation of defective interfering RNAs was discussed.     

High-frequency leader sequence switching during coronavirus defective interfering RNA replication.

A system was developed that exploited defective interfering (DI) RNAs of coronavirus to study the role of free leader RNA in RNA replication. A cDNA copy of mouse hepatitis virus DI RNA was placed downstream of the T7 RNA polymerase promoter to generate DI RNAs capable of extremely efficient replication in the presence of a helper virus. We demonstrated that, in the DI RNA-transfected cells, the leader sequence of these DI RNAs was switched to that of the helper virus during one round of replication. This high-frequency leader sequence exchange was not observed if a nine-nucleotide stretch of sequence (UUUAUAAAC) at the junction between the leader and the remaining DI sequence was deleted. This observation suggests that a free leader RNA generated from the genomic RNA of mouse hepatitis virus may participate in the replication of DI RNA.     

Restricted replication of human hepatitis A virus in cell culture: intracellular biochemical studies.

When hepatitis A virus was inoculated into Vero cells, virus-specified protein and RNA synthesis was detected. Production of viral protein was detected by electrophoretic analysis in polyacrylamide gels by using a double-label coelectrophoresis and subtraction method which eliminated the contribution of host protein components from the profiles of virus-infected cytoplasm. Eleven virus-specified proteins were detected in the net electrophoretic profiles of hepatitis A virus-infected cells. The molecular weights of these proteins were very similar to those detected in cells infected with poliovirus type 1. Virus-specified protein synthesis could be detected at 3 to 6 h and continued for at least 48 h postinfection, but no significant effect on host-cell macromolecular synthesis was observed. Limited viral RNA replication occurred between 2 and 6 h postinfection. The genomic RNA of hepatitis A virus was extracted and shown to be capable of infecting cells and inducing the same set of proteins as intact virus, indicating that the RNA genome is positive stranded. Progeny virus was never detected in the supernatant fluids of infected cell cultures, and the cells showed no observable cytopathology, even though hepatitis A virus-specific proteins and antigens were being produced. The nature of the defect in the replicative cycle of hepatitis A virus in this system remains unknown.     

In vitro synthesis of full-length influenza virus complementary RNA.

Influenza virus-specific RNA has been synthesized in vitro, using cytoplasmic or microsomal fractions of influenza virus-infected MDCK cells. The RNA polymerase activity was stimulated 5-30 times by priming with ApG. About 20-30% of the product was polyadenylated. Most of the in vitro product was of positive polarity, as shown by hybridization to strand specific probes and by T1 fingerprinting of the poly(A)+ and poly(A)- RNA segments encoding haemagglutinin and nucleoprotein. The size of poly(A)- RNA segments, determined on sequencing gels, was indistinguishable from that of virion RNA, whereas poly(A)+ RNA segments contain poly(A) tails approximately 50 nucleotides long. The size of in vitro synthesized RNA segments was also determined by gel electrophoresis of S1-treated double-stranded RNAs, obtained by hybridization of poly(A)+ or poly(A)- RNA fractions with excess of unlabelled virion RNA. The results of these experiments indicate that poly(A)- RNA contains full-length complementary RNA. This conclusion is further substantiated by the presence of additional oligonucleotides in the T1 fingerprints of in vitro synthesized poly(A)- haemagglutinin or nucleoprotein RNA, selected by hybridization to cloned DNA probes corresponding to the 3' termini of the genes.     

Characterization of two RNA polymerase activities induced by mouse hepatitis virus

RNA-dependent RNA polymerase activity was found in mouse hepatitis virus strain A59 (MHV-A59)-infected cells. The enzyme was induced in the infected cells and could not be detected in the MHV-A59 virion. Two peaks of RNA polymerase activity, one early and the other late in infection, were detected. These polymerase activities were in temporal sequence with early and late virus-specific RNA synthesis. Both of them were found to be associated with membrane fractions. There were significant differences in the enzymatic properties of the two polymerases. The early polymerase, but not the late polymerase, could be activated by potassium ions in the absence of magnesium ions and also had a lower optimum pH than the late polymerase. It was therefore probable that the enzymes represent two different species of RNA polymerase and perform different roles in virus-specific RNA synthesis. The effects of cycloheximide on MHV-specific RNA synthesis were determined. Continuous protein synthesis was required for both early and late RNA synthesis and might also be required for shutoff of early RNA synthesis.     

Further characterization of mRNA''s of mouse hepatitis virus: presence of common 5''-end nucleotides

The mouse hepatitis virus strain A59 codes for seven RNA species in the infected cells. These virus-specific RNAs were found to be polysome associated and therefore likely to represent mRNA's. All of them have common 3'-end sequences (Lai et al., J. Virol. 39:823-834, 1981). Their structure was further studied with respect to their 5'-end sequences. It was found that all of these mRNA's contained cap structures at their 5' ends. Furthermore, the cap-containing oligonucleotides which represent the sequences immediately adjacent to the 5' ends were found to be the same for most, if not all, of the seven virus-specific mRNA's. These sequences are also identical to the 5'-end sequences of the virion RNA genome. The 5'-end sequences were tentatively determined to be 5'-cap-N-UAAG. The presence of the common nucleotides in all of the virus-specific RNAs in mouse hepatitis virus strain A59 suggests several possible mechanisms of synthesis for these RNAs. The significance of these findings is discussed.