Influenza B virus genome: sequences and structural organization of RNA segment 8 and the mRNAs coding for the NS1 and NS2 proteins.

Double-stranded DNA derived from influenza B virus genome RNA segment 8, which codes for the NS1 and NS2 proteins, was constructed by hybridization of full-length cDNA copies of RNA segment 8 and of the NS1 mRNA. This DNA was cloned in plasmid pBR322 and sequenced. The NS1 mRNA (approximately 1,080 viral nucleotides) contains nonviral nucleotides at its 5' end and is capable of coding for a protein of 281 amino acids. Sequencing of the NS2 mRNA has shown that it contains an interrupted sequence of 655 nucleotides and is most likely synthesized by a splicing mechanism. The first approximately 75 virus-specific nucleotides at the 5' end of the NS2 mRNA are the same as are found at the 5' -end of the NS1 mRNA. This region contains the initiation codon for protein synthesis and coding information for 10 amino acids common to the two proteins. The approximately 350-nucleotide body region of the NS2 mRNA can be translated in the +1 reading frame, and the sequence indicates that the NS1 and NS2 protein-coding regions overlap by 52 amino acids translated from different reading frames. Thus, between the influenza A and B viruses, the organization of the NS1 and NS2 mRNAs and the sizes of the NS2 mRNA and protein are conserved despite the larger size of the influenza B virus RNA segment, NS1 mRNA, and NS1 protein.     

Coronavirus multiplication: locations of genes for virion proteins on the avian infectious bronchitis virus genome.

Six overlapping viral RNAs are synthesized in cells infected with the avian coronavirus infectious bronchitis virus (IBV). These RNAs contain a 3'-coterminal nested sequence set and were assumed to be viral mRNAs. The seven major IBV virion proteins are all produced by processing of three polypeptides of ca. 23, 51, and 115 kilodaltons. These are the core polypeptides of the small membrane proteins, the nucleocapsid protein, and the 155-kilodalton precursor to the large membrane proteins GP90 and GP84, respectively. To determine which mRNAs specify these polypeptides, we isolated RNA from infected cells and translated it in a messenger-dependent rabbit reticulocyte lysate. Proteins of 23, 51, and 110 kilodaltons were produced. Two-dimensional tryptic peptide mapping demonstrated that these proteins were closely related to the major virion proteins. Fractionation of the RNA before cell-free translation permitted the correlation of messenger activities for synthesis of the proteins with the presence of specific mRNAs. We found that the smallest RNA, RNA A, directs the synthesis of P51, the nucleocapsid protein. RNA C, which contains the sequences of RNA A, directs the synthesis of the small membrane protein P23. RNA E directs the synthesis of the large virion glycoproteins. These results supported a model in which only the unique 5'-terminal domain of each IBV mRNA is active in translation and enabled us to localize genes for virion proteins on the IBV genome.     

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 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).     

Influenza virus RNA's in the cytoplasm of chicken embryo cells treated with 3'-deoxyadenosine.

3'-Deoxyadenosine (75 to 100 mug/ml) permitted analysis of the cytoplasmic influencza virus-specific RNAs synthesized early in the replicative cycle-a phase that has hitherto been obscurred by host cell RNA synthesis. In addition, late in the cycle (6 to 8) complementary virus-specific RNA's were the predominantly labeled species, suggesting that higher concentrations of 3'-deoxyadenosine selectively inhibit influenza viral genome replication.     

Translational control by influenza virus: suppression of the kinase that phosphorylates the alpha subunit of initiation factor eIF-2 and selective translation of influenza viral mRNAs.

Selective translation of influenza viral mRNAs occurs after influenza virus superinfection of cells infected with the VAI RNA-negative adenovirus mutant dl331 (M. G. Katze, Y.-T. Chen, and R. M. Krug, Cell 37:483-490, 1984). Cell extracts from these doubly infected cells catalyze the initiation of essentially only influenza viral protein synthesis, reproducing the in vivo situation. This selective translation is correlated with a 5- to 10-fold suppression of the dl331-induced kinase that phosphorylates the alpha subunit of eucaryotic initiation factor eIF-2. This strongly suggests that influenza virus encodes a gene product that, analogous to the adenoviral VAI RNA, prevents the shutdown of overall protein synthesis caused by an eIF-2 alpha kinase turned on by viral infection. Adenoviral mRNA translation was restored to the extract from the doubly infected cells by the addition of the guanine nucleotide exchange factor eIF-2B, which is responsible for the normal recycling of eIF-2 during protein synthesis. This indicates that the residual kinase in the doubly infected cells leads to a limitation in functional (nonsequestered) eIF-2B and hence functional (GTP-containing) eIF-2 and that under these conditions influenza viral mRNAs are selectively translated over adenoviral mRNAs. Addition of double-stranded RNA to the extracts from these cells restored the eIF-2 alpha kinase to a level approaching that seen in extracts from cells infected with dl331 alone and caused the inhibition of influenza viral mRNA translation. This suggests that the putative influenza viral gene product acts against the double-stranded RNA activation of the kinase and indicates that influenza viral mRNA translation is also linked to the level of functional eIF-2. Our results thus indicate that a limitation in functional eIF-2 which causes a nonspecific reduction in the rate of initiation of protein synthesis results in the preferential translation of the better mRNAs (influenza viral mRNAs) at the expense of the poorer mRNAs (adenoviral mRNAs).     

Translation of three mouse hepatitis virus strain A59 subgenomic RNAs in Xenopus laevis oocytes

We have purified the seven virus-specific RNAs which were previously shown to be induced in Sac(-) cells upon infection with mouse hepatitis virus strain A59 (W. J. M. Spaan, P. J. M. Rottier, M. C. Horzinek, and B. A. M. van der Zeijst, Virology 108:424-434, 1981). The individual RNAs, prepared by agarose gel electrophoresis of the polyadenylated RNA fraction from infected cells, were obtained pure, except for the preparations of RNAs 4, 5, and 6, which contained some contamination of RNA 7. The RNAs were microinjected into Xenopus laevis oocytes, and after incubation of these cells in the presence of [35S]methionine, the proteins synthesized were analyzed by polyacrylamide gel electrophoresis. Whereas no translation products of RNAs 1, 2, 4, and 5 were detected, the synthesis of virus-specific polypeptides coded by RNAs 3, 6, and 7 was observed. RNA 7 (0.6 X 10(6) daltons) directed the synthesis of a 54,000-molecular-weight polypeptide which comigrated with viral nucleocapsid protein and which was immunoprecipitated by antiserum from mice that had been infected with the virus. RNA 6 (0.9 X 10(6) daltons) directed the synthesis of three polypeptides with molecular weights of 24,000, 25,500, and 26,500, which migrated with the same electrophoretic mobilities as three low-molecular-weight virion polypeptides. After injection of RNA 3 (3.0 X 10(6) daltons), a polypeptide with a molecular weight of about 150,000 was immunoprecipitated. This polypeptide had no counterpart in the virion, but comigrated with a virus-specific glycoprotein present in infected cells which is immunoprecipitated by a rabbit antiserum against the mouse hepatitis virus strain A59 structural proteins. This antiserum could also immunoprecipitate the translation products of RNAs 3, 6, and 7. These results indicate that RNAs 3, 6, and 7 encode viral structural proteins. The significance of the data with respect to the strategy of coronavirus replication is discussed.     

Influenza virus assembly and its defects

The most abundant protein within the influenza virus particles is membrane protein (M protein) which forms an inner virus membrane under a lipid bilayer and plays the role of mediator during the process of assembly of a virus particle on plasma membranes. Ehrlich ascites tumor cells (EAT) when infected with influenza virus, strain WSN, produced virus-like particles containing greatly reduced amounts of M protein. Such particles were extremely fragile and easily lost hemagglutinins. The loss of this glycoprotein was accompanied by a decrease in infectious activity.SDS-PAGE analysis of RNA duplexes formed after hybridization of intracellular labeled mRNAs and unlabeled virion RNA showed that the mRNA for M protein was synthesized in EAT nearly in the same amounts as in productively infected chicken fibroblasts. Accordingly, M protein was readily revealed when the polypeptides of infected EAT were analyzed by SDS-PAGE. Thus, the reduced amount of M protein in virus particles was likely not due to the decrease in its synthesis but rather to its defective structure or to its defective transport and misintegration into plasma membranes of EAT.