Relative importance of 7-methylguanosine in ribosome binding and translation of vesicular stomatitis virus mRNA in wheat germ and reticulocyte cell-free systems.

Vesicular stomatitis virus mRNAs with these four types of 5'-termini, (a) m7G5'ppp5'(m)Am, (b) ppp5'(m)Am, (c) m7G5'-ppp5' Am, and (d) G5'ppp5'A, were prepared and their translation and ribosome binding analyzed in wheat germ and reticulocyte cell-free protein synthesis systems. The relative efficiencies of translation of individual vesicular stomatitis virus (VSV) mRNAs having type 2 termini ranged from 23 to 29% of the control (type 1) RNA in the reticulocyte system and 6 to 7% of control RNA in the wheat germ system. A similar difference between the two systems was seen in ribosome-binding experiments in which type 2 RNA formed an 80 S initiation complex with high efficiency (70% of control type 1 RNA) in the reticulocyte system, but with low efficiency (17% of control RNA) in the wheat germ system. Similar differences in the importance of m7G in translation in the two systems were seen when VSV mRNAs synthesized in vitro with type 3 and type 4 termini were analyzed. However, the analysis of type 4 RNA (which was synthesized in vitro in the presence of S-adenosylhomocysteine) was complicated by the presence of abnormally large poly(A) at its 3'-end. Another series of experiments showed that compounds such as 5'pm7G and m7G5'ppp5'Np are potent and specific inhibitors of translation of all types of VSV mRNAs in the wheat germ system (greater than 98% inhibition) but cause less than 20% inhibition of translation in the reticulocyte system. Taken together, all of the results indicate that a 5'-terminal m7G is far more important in translation of VSV mRNAs in the heterologous plant cell-free system than in the reticulocyte lysate system.     

Heterogneeous 5'-terminal structures occur on vesicular stomatitis virus mRNAs.

Four alternative structures occur at the 5' ends of vesicular stomatitis virus mRNAs synthesized in infected cells and are separated conveniently by a technique described here. Sixty-five to seventy per cent of the mRNA molecules have the 5' end structure m7G5'ppp5'(m)AmpAp and about 20% have a more highly modified structure m7G5'ppp5'(m)AmpmAmpCp. The base of the first adenosine in each sequence is methylated in about one-half of the ends of each type and kinetic experiments suggest that the latter sequence is derived from the former by further methylations. The remaining 10 to 15% of the 5' ends are pppAp and pppGp in approximately equimolar yields. This heterogeneity with respect to 5' end structure is found within each of the vesicular stomatitis virus mRNA species examined. The mRNA molecules with 5'-triphosphate ends accumulate throughout the infection but are not found on ribosomes, suggesting that they lack a structure(s) required for ribosome recognition. In contrast to mRNA, virion RNA has a single 5' end structure, pppAp.     

In vitro RNA transcription by the New Jersey serotype of vesicular stomatitis virus. I. Characterization of the mRNA species.

The in vitro RNA synthesis by the virion-associated RNA polymerase of vesicular stomatitis virus (VSV), New Jersey serotype, was compared with that of the serologically distinct Indiana serotype of VSV. The New Jersey serotype of VSV synthesized five distinct mRNA species in vitro, three of which were smaller than the corresponding species synthesized by the Indiana serotype of VSV. These included the mRNA's coding for the G, M, and NS proteins. By hybridization experiments, virtually no sequence homology was detected between the mRNA's of the two serotypes. Despite this lack of overall homology, the 12 to 18S mRNA species of both serotype contained a common 5'-terminal hexanucleotide sequence, G(5')ppp(5')A-A-C-A-G. The signicance of this finding in light of specific interactions between the two serotypes of VSV in vivo is discussed.     

Two methyltransferase activities in the purified virions of vesicular stomatitis virus.

In addition to an RNA-dependent RNA polymerase, purified vesicular stomatitis virus contains a methyltransferase activity which transfers the methyl group from the methyl donor, S-adenosyl-L-methionine, to two positions in the 5'-terminal capped structure of the nascent mRNA's synthesized in vitro as 7mG-(5)'ppp(5')Apm... In the present study it is shown that two distinct methyltransferase activities are discernible in the purified virus. The in vitro concentrations of the methyl donor specify the number and location of the methyl groups transferred to the capped 5'-termini of VSV mRNA's. Limited concentrations of the methyl donor result in a single methylation of the penultimate base in the 2'-hydroxyl position, that is, G(5')ppp(5')Apm..., whereas saturating concentrations of the methyl donor methylate the blocking guanosine residue at the 7-position, resulting in the dimethylated cap, 7mG(5')ppp(5')Apm... Pulse-chase experiments demonstrate that the monomethylated cap structure is the precursor substrate for the dimethylated cap. In this respect, vesicular stomatitis virus system is quite distinct from the vaccinia and reovirus systems. Virus purified from different host cells including hamster, mouse, and human contain both methyltransferase activities. The mRNA's containing monomethylated capped structures are poor templates for protein synthesis in vitro.     

mRNA methylation and protein synthesis in extracts from embryos of brine shrimp, Artemia salina.

Cell-free protein-synthesizing extracts prepared from the brine shrimp, Artemia salina, translate methylated mRNAs. Reovirus unmethylated mRNA is inactive as a template when methylation is prevented by the inhibitor, S-adenosylhomocysteine. A salina mRNAs from both undeveloped and developed embryos contain 5'-terminal 7-methylguanosine in an inverted 5'-5' linkage through three phosphate groups to the rest of the polynucleotide chain. Removal of the 7-methylguanosine by beta elimination converts the mRNA from an active form to one inactive in protein synthesis in extracts of A. salina or wheat germ. Extracts of undeveloped and developed embryos methylate reovirus unmethylated mRNA at the 5' ends to form 5'-terminal structures of the type, m7G(5')ppp(5')G and m7G(5')ppp(5')Gm.     

Increase in S-adenosylhomocysteine concentration in interferon-treated HeLa cells and inhibition of methylation of vesicular stomatitis virus mRNA

A fraction of the viral mRNA synthesized in interferon-treated HeLa cells infected with vesicular stomatitis virus (VSV) lacks the 7-methyl group in the 5'-terminal guanosine of the cap; this mRNA is not associated with polyribosomes and does not bind to ribosomes in an assay for initiation of protein synthesis (de Ferra, F., and Baglioni, C. (1981) Virology 112, 426-435). To establish whether this defect in methylation is due to changes in the level of the methyl donor S-adenosylmethionine (AdoMet) and of its competitive inhibitor S-adenosylhomocysteine (AdoHcy), we measured the concentration of these compounds in HeLa cells treated with interferon. An increase in both AdoMet and AdoHcy was detected 3 to 6 h after addition of interferon. The level of these compounds increased gradually and in proportion to the interferon concentration used. With 125 reference units/ml of beta interferon, for example, the AdoHcy concentration increased more than 3-fold and that of AdoMet about 1.5-fold with a consequent change in the AdoHcy/AdoMet ratio. An increased AdoHcy/AdoMet ratio was also found in HeLa cells treated with pure alpha 2 interferon produced in Escherichia coli by recombinant DNA techniques. When the methylation of VSV mRNA was measured in assays carried out with permeabilized virions at the AdoHcy and AdoMet concentrations found in interferon-treated cells, a preferential inhibition of the viral (guanine-7-)methyltransferase activity was observed. Such an inhibition may account for the synthesis of VSV mRNA lacking the 7-methyl group of guanosine in the cap.     

Translation and identification of the viral mRNA species isolated from subcellular fractions of vesicular stomatitis virus-infected cells.

The cytoplasm of vesicular stomatitis virus (VSV)-infected BHK cells has been separated into a fraction containing the membrane-bound polysomes and the remaining supernatant fraction. Total poly(A)-containing RNA was isolated from each fraction and purified. A 17S class of VSV mRNA was found associated almost exclusively with the membrane-bound polysomes, whereas 14,5S and 12S RNAs were found mostly in the postmembrane cytoplasmic supernatant. Poly(A)-containing VSV RNA synthesized in vitro by purified virus was resolved into the same size classes. The individual RNA fractions isolated from VSV-infected cells or synthesized in vitro were translated in cell-free extracts of wheat germ, and their polypeptide products were compared by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. The corresponding in vivo and in vitro RNA fractions qualitatively direct the synthesis of the same viral polypeptides and therefore appear to contain the same mRNA species. By tryptic peptide analysis of their translation products, the in vivo VSV mRNA species have been identified. The 17S RNA, which is compartmentalized on membrane-bound polysomes, codes for a protein of molecular weight 63,000 (P-63) which is most probably a nonglycosylated form of the viral glycoprotein, G. Of the viral RNA species present in the remaining cytoplasmic supernatant, the 14.5S RNA codes almost exclusively for the N protein, whereas the 12S RNA codes predominantly for both the NS and M proteins of the virion.     

Amino acid residues within conserved domain VI of the vesicular stomatitis virus large polymerase protein essential for mRNA cap methyltransferase activity

During mRNA synthesis, the polymerase of vesicular stomatitis virus (VSV) copies the genomic RNA to produce five capped and polyadenylated mRNAs with the 5'-terminal structure 7mGpppA(m)pApCpApGpNpNpApUpCp. The 5' mRNA processing events are poorly understood but presumably require triphosphatase, guanylyltransferase, [guanine-N-7]- and [ribose-2'-O]-methyltransferase (MTase) activities. Consistent with a role in mRNA methylation, conserved domain VI of the 241-kDa large (L) polymerase protein shares sequence homology with a bacterial [ribose-2'-O]-MTase, FtsJ/RrmJ. In this report, we generated six L gene mutations to test this homology. Individual substitutions to the predicted MTase active-site residues K1651, D1762, K1795, and E1833 yielded viruses with pinpoint plaque morphologies and 10- to 1,000-fold replication defects in single-step growth assays. Consistent with these defects, viral RNA and protein synthesis was diminished. In contrast, alteration of residue G1674 predicted to bind the methyl donor S-adenosylmethionine did not significantly perturb viral growth and gene expression. Analysis of the mRNA cap structure revealed that alterations to the predicted active site residues decreased [guanine-N-7]- and [ribose-2'-O]-MTase activity below the limit of detection of our assay. In contrast, the alanine substitution at G1674 had no apparent consequence. These data show that the predicted MTase active-site residues K1651, D1762, K1795, and E1833 within domain VI of the VSV L protein are essential for mRNA cap methylation. A model of mRNA processing consistent with these data is presented.     

Assembly of viral membranes. I. Association of vesicular stomatitis virus membrane proteins and membranes in a cell-free system.

We report here an in vitro system designed to study the interactions of vesicular stomatitis virus (VSV) proteins with cellular membranes. We have synthesized the VSV nucleocapsid (N) protein, nonstructural (NS) protein, glycoprotein (G protein), and membrane (M) protein in a wheat germ, cell-free, protein-synthesizing system directed by VSV 12 to 18S RNA. When incubated at low salt concentrations with purified cytoplasmic membranes derived from Chinese hamster ovary cells, the VSV M andG proteins bind to membranes, whereas the VSV N and NS proteins do not. The VSV M protein binds to membranes in low or high divalent cation concentrations, whereas binding of significant amounts of G protein requires at least 5 mM magnesium acetate concentrations.     

In vitro RNA transcription by the New Jersey serotype of vesicular stomatitis virus. II. Characterization of the leader RNA.

The New Jersey serotype of vesicular stomatitis virus (VSV) was able to synthesize a small RNA (leader RNA) approximately 70 bases in length similar to the leader RNA synthesized in vitro by the genetically distinct Indiana serotype of VSV. Also, the New Jersey leader RNA contained the same 5'-terminal sequence, ppA-C-G, as the Indiana leader RNA and had a very similar base composition, with 42% AMP, 16% CMP, 18.6% GMP, and 23.4% UMP. The 3'-terminal sequence of the VSV New Jersey genome RNA was detemined and found to contain the sequence- Py-G-UOH, again the same as that of the Indiana serotype of VSV. Evidence that the New Jersey leader RNA is transcribed from the 3' end of the genome RNA was obtained from the fact that it can protect the 3'-terminal base of [3H]borohydride-labeled New Jersey genome RNA from RNase digestion. Although the New Jersey and Indiana leader RNAs were similar in many respects, they were unable to form RNase-resistant hybrids when annealed to heterologous genome RNA.     

Transmembrane biogenesis of the vesicular stomatitis virus glycoprotein

Previous work has shown that the mRNA encoding the vesicular stomatitis virus (VSV) glycoprotein (G) is bound to the rough endoplasmic reticulum (RER) and that newly made G protein is localized to the RER. In this paper, we have investigated the topology and processing of the newly synthesized G protein in microsomal vesicles. G was labeled with [35S]methionine ([35S]met), either by pulse-labeling infected cells or by allowing membrane-bound polysomes containing nascent G polipeptides to complete G synthesis in vitro. In either case, digestion of microsomal vesicles with any of several proteases removes approximately 5% (30 amino acids) from each G molecule. These proteases will digest the entire G protein if detergents are present during digestion. Using the method of Dintzis (1961, Proc. Natl. Acad. Sci. U. S. A. 47:247--261) to order tryptic peptides (8), we show that peptides lost from G protein by protease treatment of closed vesicles are derived from the carboxyterminus of the molecule. The newly made VSV G in microsomal membranes is glycosylated. If carbohydrate is removed by glycosidases, the resultant peptide migrates more rapidly on polyacrylamide gels than the unglycosylated, G0, form synthesized in cell-free systems in the absence of membranes. We infer that some proteolytic cleavage of the polypeptide backbone is associated with membrane insertion of G. Further, our findings demonstrate that, soon after synthesis, G is found in a transmembrane, asymmetric orientation in microsomal membranes, with its carboxyterminus exposed to the extracisternal, or cytoplasmic, face of the vesicles, and with most or all of its amino-terminal peptides and its carbohydrate sequestered within the bilayer and lumen of the microsomes.     

Terminal sequences of vesicular stomatitis virus RNA are both complementary and conserved.

The nucleotide sequences at the 5' and 3' termini of RNA isolated from the New Jersey serotype of vesicular stomatitis virus [vsV(NJ)] and two of its defective interfering (DI) particles have been determined. The sequence differs from that previously demonstrated for the RNA from the Indiana serotype of VSV at only 1 of the first 17 positions from the 3' terminus and at only 2 of the first 17 positions from the 5' terminus. The 5'-terminal sequence of VSV(NJ) RNA is the complement of the 3'-terminal sequence, and duplexes which are 20 bases long and contain the 3' and 5' termini have been isolated from this RNA. The RNAs isolated from DI particles of VSV(NJ) have the same base sequences as do the RNAs from the parental virus. These results are in sharp contrast to those obtained with the Indiana serotype of VSV and its DI particles, in which the 3'-terminal sequences differ in 3 positions within the first 17. However, with both serotypes, the 3'-terminal sequence of the DI RNA is the complement of the 5'-terminal sequence of the RNA from the infectious virus. These findings suggest that the 3' and 5' RNA termini are highly conserved in both serotypes and that the 3' terminus of DI RNA is ultimately derived by copying the 5' end of the VSV genome, as recently proposed (D. Kolakofsky, M. Leppert, and L. Kort, in B. W. J. Mahy and R. D. Barry, ed., Negative-Strand Virus and the Host Cell, 1977; M. Leppert, L. Kort, and D. Kolakofsky, Cell 12:539-552, 1977; A. S. Huang, Bacteriol. Rev. 41:811-8218 1977).     

Protein synthesis in lysates of Aedes albopictus cells infected with vesicular stomatitis virus.

Aedes albopictus cells (clone LT-C7) showed a marked cytopathic effect and inhibition of protein synthesis (both host and viral) after infection with vesicular stomatitis virus (VSV), but only if (i) cultures were incubated at 34 degrees C rather than 28 degrees C and (ii) serum was present in the medium (S. Gillies and V. Stollar, Mol. Cell. Biol. 2:66-75, 1982). To learn more about how protein synthesis is shut off in VSV-infected A. albopictus cells, we have compared cell-free protein synthesis in extracts prepared from VSV-infected cells and control cells. Extracts prepared 6 h after infection from VSV-infected cells maintained at 34 degrees C in the presence of serum reflected what was observed with intact cells in at least two respects: (i) they showed a markedly diminished capacity to carry out protein synthesis (whether directed by endogenous or exogenously added mRNA), and (ii) there was decreased phosphorylation in vitro by [gamma-32P]ATP of a specific ribosomal protein (Gillies and Stollar, Mol. Cell. Biol. 2:66-75, 1982). In addition, and consistent with a block at the level of initiation, the formation of 80S initiation complexes, as measured by binding of VSV 12 to 18S mRNA, was reduced in the inactive extracts. Addition of an S-100 fraction from uninfected cells to the inactive extract reversed each of the aforementioned changes; i.e., it restored protein synthetic activity, it stimulated the formation of 80S initiation complexes, and it increased phosphorylation of the specific ribosomal protein referred to above. The active component in the S-100 fraction was heat labile and non-dialyzable and, upon ammonium sulfate fractionation of the S-100 fraction, was found in the 40 to 70% saturation fraction. Our findings suggest that VSV infection of A. albopictus cells inhibits protein synthesis by inactivating a macromolecular component, probably a protein, in the S-100 fraction which may be involved in the initiation of protein synthesis. More specifically, we suggest that this component is involved in the joining of the ribosomal subunits to form 80S initiation complexes.     

In vitro methylation of undermethylated yeast poly(A)-rich RNA using mRNA(guanine-7-)-methyltransferase purified from wheat germ or yeast

By crossing two strains of Saccharomyces cerevisiae deficient for each of the two methionine adenosyltransferase isoenzymes (ATP: L-methionine S-adenosyltransferase EC 2.5.1.6) respectively, we have constructed a strain strictly auxotrophic for S-adenosylmethionine and used it as a source of undermethylated mRNA suitable for in vitro transmethylation studies. RNA has been phenol-extracted from yeast cells shifted down to S-adenosylmethionine-free medium for 90 min and poly(A)-rich RNA has been prepared by oligo(dT)-cellulose chromatography. Upon incubation in vitro in the presence of methyl-labeled S-adenosylmethionine and mRNA (guanine-7-)-methyltransferase purified from wheat germ or yeast, undermethylated poly(A)-rich RNA became significantly labeled as compared to non-starved cells from the same strain, or from a wild-type control. Cap structures were resolved by paper chromatography afer T2 and P1 RNase digestion, and shown to be a mixture of m7G5'ppp5'G and m7G5'ppp5'A, irrespective of the enzyme source, in agreement with earlier in vivo studies in yeast mRNA capping and methylation.