Initiation sites for translation of sindbis virus 42S and 26S messenger RNAs.

Sindbis virus 26S RNA is the principal species of virus-specific RNA found in the infected cell; it is derived from a one third segment of virion 42S RNA. When translated in cell-free extracts from mouse ascites cells or rabbit reticulocytes, 26S RNA directed the synthesis primarily of the 33,000 dalton virus capsid protein, and the protein products were in the form of free peptides rather than peptidyl-tRNA. In contrast, the polypeptides synthesized in either extract in response to Sindbis virus 42S RNA were heterogeneous, ranging in molecular weight from 33,000 to 190,000, and were largely in the form of peptidyl-tRNA. The number of independent initiation sites on the 26S and 42S RNAs was determined by analyzing a tryptic digest of reaction products labeled with yeast N-formyl-35S-methionyl-tRNAFmet. The 26S RNA appeared to contain a single initiation site, and this site could also be found in varying amounts in different preparations of 42S RNA. However, a second initiation site, distinct from that of 26S RNA, was the major site in 42S virion RNA. These results suggest that 42S virion RNA contains two potential sites for initiation of protein synthesis. Only one of these may be active, however, and it is postulated that the second site functions primarily, if not exclusively, in the subgenomic 26S RNA species. In this regard, Sindbis virus 42S RNA may represent a novel form of a eucaryotic messenger RNA.     

Translational control by influenza virus. Selective and cap-dependent translation of viral mRNAs in infected cells.

In cells infected by influenza virus type A, host protein synthesis undergoes a rapid and dramatic shutoff. To define the molecular mechanisms underlying this selective translation, a transfection/infection protocol was developed utilizing viral and cellular cDNA clones. When COS-1 cells were transfected with cDNAs encoding nonviral genes and subsequently infected with influenza virus, protein expression from the exogenous genes was diminished, similar to the endogenous cellular genes. However, when cells were transfected with a truncated influenza viral nucleocapsid protein (NP-S) gene, the NP-S protein was made as efficiently in influenza virus infected cells as in uninfected cells, showing that the NP-S mRNA, although expressed independently of the influenza virus replication machinery, was still recognized as a viral and not a cellular mRNA. Northern blot analysis demonstrated that the selective blocks to nonviral protein synthesis were at the level of translation. Moreover, polysome experiments revealed that the translational blocks occurred at both the initiation and elongation stages of cellular protein synthesis. Finally, we utilized this transfection/infection system as well as double infection experiments to demonstrate that the translation of influenza viral mRNAs probably occurred in a cap-dependent manner as poliovirus infection inhibited influenza viral mRNA translation.     

Cell-free translation of bovine viral diarrhea virus RNA.

Bovine viral diarrhea virus RNA was translated in a reticulocyte cell-free protein synthesizing system. The purified, 8.2-kilobase, virus-specific RNA species was unable to serve an an efficient message unless it was denatured immediately before translation. In this case, several polypeptides, ranging in molecular weight from 50,000 to 150,000 and most of which were immunoprecipitated by bovine viral diarrhea virus-specific antiserum, were synthesized in vitro. When polyribosomes were used to program cell-free synthesis, mature viral 80,000- and 115,000-molecular-weight proteins were detected; no precursor to the viral 55,000-molecular-weight glycoprotein was noted. The implications of these results with respect to virus-specific protein synthesis are discussed.     

Cell-free translation analysis of messenger RNA in echinoderm and amphibian early development

A wheat germ cell-free translation system has been used to analyze populations of abundant messenger RNA from sea urchin eggs and embryos and from amphibian oocytes and ovaries. We show directly that sea urchin eggs and embryos contain translatable mRNA of three general classes: poly(A)⁺ mRNA, poly(A)^? histone mRNA, and poly(A)^? nonhistone mRNA. Additionally, some histone synthesis appears to be promoted by poly(A)⁺ RNA. Sea urchin eggs seem to contain a higher proportion of prevalent poly(A)^? nonhistone mRNAS than do embryos. Some differences in the proteins encoded by poly(A)⁺ and poly(A)^? RNAs are detectable. Many coding sequences in the egg appear to be represented in both poly(A)⁺ and poly(A)^? RNAs, since the translation products of the two RNA classes exhibit many common bands when run on one-dimensional polyacrylamide gels. However, some of this overlap is probably due to fortuitous comigration of nonidentical proteins. Distinct stage-specific changes in the spectra of prevalent translatable mRNAs of all three classes occur, although many mRNAs are detectable throughout early development. Particularly striking is the presence of an egg poly(A)^? mRNA, encoding a 70,000–80,000 molecular weight protein, which is not detected in morula or later-stage embryos. In amphibian (Xenopus laevis and Triturus viridescens) ovary RNA, the translation assay detects the following three mRNA classes: poly(A)⁺ nonhistone mRNA, poly(A)^? histone mRNA, and poly(A)⁺ histone mRNA. Amphibian ovary RNA appearently lacks an abundant poly(A)^? nonhistone mRNA component of the magnitude detectable in sea urchin eggs. mRNA encoding histone-like proteins is found in the very earliest (small stage 1) oocytes of Xenopus as well as in later stage oocytes. During oogenesis there appear to be no striking qualitative changes in the spectra of prevalent translatable mRNAs which are detected by the cell-free translation assay.     

Pre-early adenovirus 5 gene product regulates synthesis of early viral messenger RNAs.

The studies described here demonstrate that the expression of many early adenovirus mRNAs is dependent upon the activity of a pre-early viral product. This viral gene product is defective in adenovirus 5 host range (Ad hr) group I mutants. Adenovirus 5 host range mutants were previously isolated by their ability to replicate in the adenovirus 5-transformed human embryonic cell line 293 and by their inability to replicate efficiently in HeLa cells (Harrison, Graham and Williams, 1977). The group I complementation class of host range mutants has been mapped by marker rescue between 0 and 4.4 units (Frost and Williams, 1978). We have used the S1 nuclease gel technique to examine the expression of early mRNA after infection of HeLa cells with Ad5 hr group I and II mutants. The Ad5 hr group II mutants stimulate the synthesis of a wild-type pattern of early mRNAs. In contrast, infection of HeLa cells with Ad5 hr group I mutants gives rise to only two early mRNAs. These mRNAs map from 1.5–4.4 units, or in the same region as the Ad5 hr group I mutations. Since infection of HeLa cells with Ad5 hr group I mutants was defective for synthesis of cytoplasmic mRNAs complementary to three early regions in the right half of the genome and to the early region 4.5–11.0 units, we also analyzed nuclear RNA from these cells by the S1 nuclease gel technique for the presence of precursor RNA chains. Nuclear precursors were not detected in Ad5 hr group I-infected HeLa cells, suggesting that the gene product defective in these mutants is required for synthesis of stable nuclear RNA from the three early regions in the right half of the genome and from the early region 4.5–11.0 units.     

Cell-free translation of messenger RNAs from adult and fetal human muscle. Characterization of neosynthesized glycogen phosphorylase, phosphofructokinase and glucose phosphate isomerase

Using a procedure of ethanol precipitation in concentrated guanidine . HCl solutions followed by chloroform/isoamylic alcohol extraction and washing in 3 M sodium acetate, we isolated high-molecular-weight cellular RNA from human fetal and adult skeletal muscle. About 500 micrograms RNA were obtained/g of fetal muscle and 50 micrograms RNA/g of adult muscle. Both RNA preparations were efficiently translated in a cell-free reticulocyte lysate system and directed synthesis of various polypeptides, one of them of Mr 200,000 probably corresponding to myosin heavy chains. Dodecylsulphate/polyacrylamide gel electrophoretic pattern of polypeptides neosynthesized using either fetal or adult RNA exhibited several differences. Three neosynthesized cytosolic muscle enzymes were purified from the translation mixtures using a micro-method of immunoaffinity chromatography; specificity of the neosynthesized polypeptides purified according to this procedure was checked by immunological competition with the corresponding unlabeled pure muscle enzymes. Successful cell-free translation of RNA from adult skeletal muscle and purification of neosynthesized human enzymes are reported for the first time. These methods, indispensable for further studies on human adult muscle gene expression, could also shed light on the mechanism of some inherited molecular diseases and tumoral or dystrophic processes.     

Relationship between the messenger RNAs transcribed from two overlapping genes of influenza virus.

The relationship of the mRNAs encoding the NS1 and NS2 polypeptides of influenza virus has been investigated through synthesis and characterisation of complementary DNA copies of the mRNAs. Previous work had shown that both mRNAs are encoded by virion RNA segment 8, and that the sequences comprising the smaller of the two mRNAs (the NS2 mRNA) were also present on the NS1 mRNA. Our results indicate that the mRNA encoding the NS2 polypeptide of the avian influenza, fowl plague virus, is approximately 400 ntds long, and that its sequences correspond largely with the 3'-terminal region of the NS1 mRNA.     

The viral protein sigma 3 participates in translation of late viral mRNA in reovirus-infected L cells.

Reovirus late (uncapped) mRNA was previously shown to be efficiently translated in vitro extracts prepared from infected cells but not from uninfected cells. We demonstrated that different fractions from infected cells can stimulate translation of late viral mRNA when added to uninfected extracts. The activity of the different fractions correlated with their relative content of the sigma 3 capsid protein; the fraction prepared by high-salt wash of the ribosomes had the highest specific activity. The activity present in this fraction was abolished by preincubation with an anti-sigma 3 serum. Purified sigma 3 protein also stimulated the translation of late viral mRNA, confirming that it was the factor involved. Altogether, these results suggest that this protein plays the role of a late-viral-mRNA-specific initiation factor. The absence of an inhibitory effect of sigma 3 on the translation of other mRNAs indicates that this protein is not directly involved in the inhibition of host and early viral mRNA translation that occurs in infected cells but that a second mechanism is probably operative.     

Purification of virus-specific RNA from chicken cells infected with avian sarcoma virus: identification of genome-length and subgenome-leghth viral RNAs.

Avian sarcoma virus (ASV)-specific RNA was purified from ASV-infected cells by using hybridization techniques which employ polydeoxycytidylic acid-elongated DNA complementary to ASV RNA as well as chromatography on polyinosinic acid-Sephadex columns. The purity and nucleotide sequence composition of purified, virus-specific RNA were established by rehybridization experiments and analysis of labeled RNase T1-resistant oligonucleotides by two-dimensional polyacrylamide gel electrophoresis. Polyadenylic acid-containing RNA purified from ASV-infected cells contained approximately 1 to 4% virus-specific RNA, compared with 0.06 to 0.15% observed in uninfected cells. Sucrose gradient analysis of virus-specific RNA isolated from ASV-infected cells revealed two major classes of polyadenylated viral RNA with sedimentation values of 36S and 26-28S. Cells infected with transformation-defective ASV (virus containing a deletion of the sarcoma gene) contained 34S and 20-22S viral RNA species. Double-label experiments employing infected cells labeled initially for 48 h with [3H]uridine and then for either 30, 60, or 240 min with [32P]phosphate showed that the intracellular accumulation of genome-length RNA (36S) was significantly faster than that of the 26-28S viral RNA species.     

Oligonucleotide mapping of non-radioactive virus and messenger RNAs.

A modification of the known method for obtaining radioactive fingerprints from non-radioactive nucleic acids by labelling a digest with 5'-hydroxyl polynucleotide kinase and [gamma-32P]-ATP has been applied to RNase T1 digests from various high molecular weight virus RNAs and to ovalbumin mRNA. Fractionation of the resultant [32P]-labelled T1 RNase digests by two-dimensional polyacrylamide electrophoresis demonstrates that in the case of virus RNAs, the fingerprints thus obtained are very similar to those derived from uniformly labelled RNAs. The value of this technique is that it requires only 1-5 microgram of purified virus RNA and at least three orders of magnitude less radioactivity than is routinely employed in preparing uniformly labelled RNA.     

Simultaneous expression of early and late histone messenger RNAs in individual cells during development of the sea urchin embryo

The transition from early (E) to late (L) histone gene expression in developing sea urchin (Strongylocentrotus purpuratus) embryos was examined for H2B, H3, and H4 mRNAs by in situ hybridization of class-specific probes. Hybridization patterns indicate that the shift from E to L mRNAs occurs gradually and simultaneously in all blastomeres. Thus, during the transition the ratio of L to E mRNAs is similar in most cells. This suggests that no sudden changes in histone composition occur in individual cells which might be related to alterations in gene expression associated with differentiation of cell lineages. Around the midpoint of the transition, clusters of cells progressively appear which contain little, if any, E or L histone mRNA. This modulation of expression is coordinated for the three late genes examined because most individual cells contain either high or low levels of all three mRNAs. At blastula stage these clusters of unlabeled cells appear to be randomly distributed throughout the embryo. Subsequently the unlabeled regions expand and are found predominantly in aboral ectoderm as these cells cease to divide. Thus, the L/E histone mRNA ratio is not differentially regulated in diverse cell lineages, and the major differences in total histone mRNA content among individual cells may be related to cell cycle and/or the cessation of division.