Characterization and translation of methylated and unmethylated vesicular stomatitis virus mRNA synthesized in vitro by ribonucleoprotein particles from vesicular stomatitis virus-infected L cells.

Ribonucleoprotein particles isolated from extracts of vesicular stomatitis virus (VSV) -infected L cells synthesized in vitro four classes of polyadenylated RNA sedimenting at 29S, 19S, 17S, and 13S. When synthesized in vitro in the presence of the methyl donor S-adenosyl methionine, these RNA species contained the following 5'-terminal structures: (i) m7G5ppp5'AmpAp(70%) ; (ii) m7G5'ppp5'AmpAmpNp (20%) and (iii) pppAp (10%). In the presence of the methylation inhibitor S-adenosylhomocysteine, however, the mRNA contained the 5'-terminal structures G5'ppp5'Ap (80%) and pppAp (20%). The mRNA's synthesized in vitro were translated in the homologous ascites and the heterologous wheat embryo cell-free systems. In both, the products were shown by sodium dodecyl sulfate gel electrophoresis and by immunoprecipitation to contain all five viral proteins, L, G, N, NS, and M. The presumed precursor to the G protein (G*) was also identified by fingerprint analysis. Methylated VSV mRNA was more active in protein synthesis than unmethylated mRNA in both the ascites system and the wheat embryo systems. Addition of S-adenosylmethionine stimulated translation of unmethylated mRNA in the wheat embryo but not in the ascites extract. S-adenosylhomocysteine, however, by preventing mRNA methylation inhibited the translation of unmethylated VSV mRNA in both systems. The mRNA methylating activity present in wheat embryo S-30 extracts was recovered in the ribosome-free supernatant fraction (S-150) and was insensitive to the protein synthesis inhibitor pactamycin.     

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.     

The 5' terminal structure of the methylated mRNA synthesized in vitro by vesicular stomatitis virus.

The 5' terminal structure of the mRNA synthesized in vitro by the virion-associated RNA polymerase of vesicular stomatitis virus in the presence of S-adenosyl-L-methione consists of 7-methyl guanosine linked to 2'-O-methyl adenosine through a 5'-5' pyrophosphate bond as m7G(5')ppp(5')A-m-p ... The alpha and beta phosphated of GTP and alpha phosphate of ATP are incorporated into the blocked 5' terminal structure.     

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.     

Influence of 5'-terminal cap structure on the initiation of translation of vaccinia virus mRNA

The ability of methylated vaccinia virus mRNA to bind to ribosomes derived from wheat germ of rabbit reticulocyte lysates has been studied after beta elimination, to remove the 5'-terminal m7G, and after "recapping" of beta-eliminated mRNA molecules using guanylyltransferase.guanine-7-methyltransferase complex from vaccinia virions. Removal of m7G from the mRNA results in significant loss of ability to bind to ribosomes and to simulate protein synthesis in vitro. Readdition of m7G, but not of unmethylated guanosine to the 5' end results in recovery of both of these functions. To evaluate the role of 2'-O-methylation of the penultimate ribonucleoside, mRNAs containing m7G-(5')pppA- and m7G(5')pppG- as well as m7G(5')pppAm- and m7G(5')pppGm- ends were synthesized in vitro at limiting S-adenosylmethionine concentrations by vaccinia virus cores. By comparing the cap sequences of ribosome-bound and unbound mRNAs, we concluded that 2'-O-methylation has at most a minor effect compared to that of m7G upon ribosome binding under in vitro conditions. Only at high input mRNA concentrations, at which competition might occur, was there some ribodomal enrichment of mRNAs containing a specific terminal structure, namely m7G(5')pppAm-.     

Translation of capped and uncapped vesicular stomatitis virus and reovirus mRNA'S. Sensitivity to m7GpppAm and ionic conditions.

In an attempt to elucidate the role of the 5'-terminal 7-methylguanosine residue in translation of mammalian mRNAs, vesicular stomatitis virus (VS virus), and reovirus mRNAs containing and lacking this residue, and also Qbeta RNA, were translated in cell-free extracts from reticulocytes and wheat germ under a variety of ionic conditions. Optimal translation of mRNAs lacking a 5' m7G occurred at concentrations of KOAc or KCl which were lower than those optimal for normal "capped" mRNAs. However, this salt dependence was much less marked in the mammalian reticulocyte extract and, at salt concentrations optimal for translation of normal capped mRNAs, reticulocyte lysates translated uncapped with mRNAs at 30 to 60% the normal efficiency. At low K+ concentrations, wheat germ ribosomes bound and translated appreciable amounts of uncapped VS virus mRNA; controls showed that no m7G residue is added to the 5' end of the bound RNA. Analogues of the 5' end, such as m7GpppAm, inhibited translation of both normal and uncapped VS virus RNAs in wheat germ extracts to about the same extent, but the efficiency of its action was reduced at low K+ concentrations. We conclude that there is a reduced importance of the 5' m7G residue in ribosome-mRNA recognition at low K+ concentrations, and that translation of mRNAs in reticulocyte extract is, under any reaction conditions, less dependent on the presence of a 5' "cap" than in wheat germ extracts.     

m7G5''ppp5''GmptcpUp at the 5'' terminus of reovirus messenger RNA.

In the presence of S-adenosyl methionine the 5' terminal guanosine residue of in vitro synthesized reovirus mRNA becomes methylated at the 2'-OH position. In addition, 7-methyl guanylic acid is condensed covalently at the 5' terminus resulting in the formation of a 5' to 5' triphosphate bridge. Analysis of the 5' terminal sequence of methylated reovirus mRNA revealed that it has the structure m7G5'ppp5'GmpCpUp.     

Defective interfering particle generated by internal deletion of the vesicular stomatitis virus genome.

The genome structure of the long, truncated defective interfering particle derived from the heat-resistant strain of vesicular stomatitis virus has been examined. Stocks of this defective interfering particle are shown to contain several different species having information primarily from the 3' half of the vesicular stomatitis virus genome; the proportions of these components vary depending on the passage history of the stock. The two most abundant types have been identified and characterized. One has complementary 5' and 3' termini and consequently appears as a circular molecule when examined by electron microscopy. The other cannot circularize and remains linear. The circular forms are consistently 8 to 10% longer than the linear molecules. Rapid sequencing analyses reveal that both forms retain the 5' parental viral terminal sequence, but only the linear form retains the parental 3'-terminal sequence which is the complement of the 5' end. Hybridization experiments and electron microscopic analyses indicate that the linear form has retained 320 to 350 nucleotides of the 5' parental sequence and was probably generated by an internal deletion of the vesicular stomatitis virus genome.     

Effect of viral infection on host protein synthesis and mRNA association with the cytoplasmic cytoskeletal structure

We studied the association of several eucaryotic viral and cellular mRNAs with cytoskeletal fractions derived from normal and virus-infected cells. We found that all mRNAs appear to associate with the cytoskeletal structure during protein synthesis, irrespective of their 5' and 3' terminal structures: e.g., poliovirus that lacks a 5' cap structure or reovirus and histone mRNAs that lack a 3' poly A tail associated with the cytoskeletal framework to the same extent as capped, polyadenylated actin mRNA. Cellular (actin) and viral (vesicular stomatitis virus and reovirus) mRNAs were released from the cytoskeletal framework and their translation was inhibited when cells were infected with poliovirus. In contrast, actin mRNA was not released from the cytoskeleton during vesicular stomatitis virus infection although actin synthesis was inhibited. In addition, several other conditions under which protein synthesis is inhibited did not result in the release of mRNAs from the cytoskeletal framework. We conclude that the association of mRNA with the cytoskeletal framework is required but is not sufficient for protein synthesis in eucaryotes. Furthermore, the shut-off of host protein synthesis during poliovirus infection and not vesicular stomatitis virus infection occurs by a unique mechanism that leads to the release of host mRNAs from the cytoskeleton.     

Nucleotide sequences from the 3''-ends of vesicular stomatitis virus mRNA''s as determined from cloned DNA.

Molecular clones of vesicular stomatitis virus mRNA's were used to determine the 3'-terminal sequences of mRNA's encoding the N and NS proteins. This new approach to VSV mRNA sequencing allowed the first comparison of 3'-terminal sequences. The sequences showed a tetranucleotide homology, UAUG, immediately preceding the polyadenylic acid. In addition, both mRNA's had an AU-rich region including the tetranucleotide AUAU at positions 16 to 19 nucleotides from the polyadenylic acid. A possible secondary structure between the 3' end of N mRNA and the 5' end of the adjacent NS mRNA is noted. These structural features may serve as signals for termination (or cleavage) and polyadenylation of vesicular stomatitis virus mRNA's. Neither mRNA had the polyadenylic acidproximal hexanucleotide, AAUAAA, found in eucaryotic cellular and viral mRNA's transcribed from nuclear DNA. The probable location of the translation termination codon for the NS protein is only six nucleotides from polyadenylic acid in NS mRNA.     

The 5'' end group of tobacco mosaic virus RNA is m7G5'' ppp5'' Gp.

RNA extracted from CsC1-purified virions of tobacco mosaic virus is shown to give rise to an unusual nucleotide on digestion which RNAase T2, in addition to the four major nucleotides. This minor component has the electrophoretic characteristics of a phosphorylated end group, but is partially resistant to bacterial alkaline phosphatase. It is, however, a substrate for venom phosphodiesterase or nucleotide pyrophosphatase, yielding products which imply the structure m7G5'ppp5'Gp. TMV RNA, like many animal cellular and viral mRNAs recently examined, therefore has a 5' terminus blocked by a methylated nucleotide inverted with respect to the rest of the chain.     

Complete sequences of the ribosome recognition sites in vesicular stomatitis virus mRNAs: recognition by the 40S and 80S complexes.

Nucleotide sequences of the ribosome-protected translation initiation sites from the vesicular stomatitis virus (VSV) M and L protein mRNAs have been determined, completing the sequences of the sites from all the VSV mRNAs. A low level of protection at two internal AUG-containing sites in the N mRNA is also described. Small homologies are evident among some of the sites, but there are no obvious features common to all the sites other than a single AUG codon. In contrast, a large homology between the VSV M mRNA site and the alfalfa mosaic virus coat mRNA site (Koper-Zwarthoff et al., 1977) is noted. This homology suggests the existence of a common ancestral gene for these two apparently unrelated viruses. For each VSV mRNA species, the smallest sites protected in either the 40S or 80S initiation complexes are identical. These sites always contained the initiation codon, but only contained the capped 5' end in those mRNAs having the 5' end near the initiation site. If 40S ribosomes bind to the capped 5' end, either they do not protect it from nuclease digestion or the protection is only transitory in some VSV mRNAs. Consideration of the structures of the ribosome binding sites suggests that the differential effects of hypertonic shock on translation (Nuss and Koch, 1976) may be related to the distance between the 5' end of the mRNA and the initiation codon.     

Presence of 5''-terminal cap structures in virus-specific RNA from feline leukemia virus-infected cells.

The F-422 line of feline thymus tumor cells, chronically infected with the Rickard strain of feline leukemia virus (R-FeLV), was labeled with 32P, and the total cytoplasmic RNA was isolated. The RNA was centrifuged through sucrose gradients, and R-FeLV virus-specific RNA (vRNA) was located by hybridization of portions of the gradient fractions to R-FeLV complementary DNA. vRNA classes with average sedimentation coefficients of approximately 36S, 28S, 23S, and 15S were identified. Each class of RNA was recovered by hybridized with mercurated R-FeLV complementary DNA, and the hybrids were chromatographed on columns of sulfhydryl-Sepharose to separate them from unhybridized cellular RNA. Although insufficient amount of 36S and 28S vRNA were obtained for further analysis, the 23S and 15S VRNA classes were analyzed to determine the nature of their 5' termini. Each of these vRNA classes was found to contain stoichiometric amounts of cap structures per unit length of RNA, consistent with the presence of one cap per molecule. The structure of the 23S vRNA cap was found to be m7G5'ppp5'GmpAp, whereas that of the 15S vRNA cap was m7G5'ppp5'GmpGp.     

Characterization of Novikoff hepatoma mRNA methylation and heterogeneity in the methylated 5' terminus.

KOH digestion of methyl-labeled poly(A)+ mRNA purified by (dT)-cellulose chromatography produced mononucleotide and multiple peaks of a large oligonucleotide (-6 to -8 charge) when separated on the basis of charge by Pellionex-WAX high-speed liquid chromatography in 7 M urea. Heat denaturation of the RNA before application to (dT)-cellulose was required to release contaminants (mostly 18S rRNA) that persisted even after repeated binding to (dT)-cellulose at room temperature. Analysis of the purified poly(A)+ mRNA by enzyme digestion, acid hydrolysis, and a variety of chromatographic techniques has shown that the monucleotide (53%) is due entirely to N6-methyladenosine. The large oligonucleotides (47%) were found to contain 7-methylguanosine and the 2'-0-methyl derivatives of all four nucleosides. No radioactivity was found associated with the poly(A) segment. Periodate oxidation of the mRNA followed by beta elimination released only labeled 7-methylguanine consistent with a blocked 5' terminus containing an unusual 5'-5' bond. Alkaline phosphatase treatment of intact mRNA had no effect on the migration of the KOH produced oligonucleotides on Pellionex-WAX. When RNA from which 7-methylguanine was removed by beta elimination was used for the phosphatase treatment, distinct dinucleotides (NmpNp) and trinucleotides (NmpNmpNp) occurred after KOH hydrolysis and Pellionex-WAX chromatography. Thus Novikoff hepatoma poly(A)+ mRNA molecules can contain either one or two 2'-0-methylnucleotides linked by a 5'-5' bond to a terminal 7-methylguanosine and the 2'-0-methylation can occur with any of the four nucleotides. The 5' terminus may be represented by m7G5'ppp5' (Nmp)lor2Np, a general structure proposed earlier as a possible 5' terminus for all eucaryotic mRNA molecules (Rottman, F., Shatkin, A., and Perry, R. (1974), Cell 3, 197). The composition analyses indicate that there are 3.0 N6-methyladenosine residues, 1.0 7-methylguanosine residue, and 1.7 2'-0-methylnucleoside residues per average mRNA molecule.     

RNA synthesis of vesicular stomatitis virus. VIII. Oligonucleotides of the structural genes and mRNA.

The single-stranded RNA genome of vesicular stomatitis virus (VSV, Indiana serotype, San Juan strain) yields approx. 75 RNase T1-resistant oligonucleotides ranging in size from 10 to 50 bases. Each of the five structural genes, isolated as duplex RNA molecules hybridized to complementary mRNA, contains two or more of these large oligonucleotides. One of the oligonucleotides is identified as part of the non-coding region near the 3' end of the genome. Comparison of these results with others indicate that the RNA sequence of VSV is apparently stable in the laboratory but not in the wild. RNase T1-resistant oligonucleotides are also shown for all five VSV mRN species. Whether the mRNA for these digestions are are isolated from duplex RNA molecules or as single-stranded RNA species, the oligonucleotide patterns for each mRNA are virtually identical, indicating that each mRNA is transcribed from contiguous sequences on the genome. Comparison with published oligonucleotide patterns obtained from other isolates of VSV or from VSV deletion mutants indicate that identity and changes in their genome structure can be correlated with specific structural genes.