Distinct oligonucleotide patterns of distinct influenza virus RNA's

Three molecular-weight fractions of influenza virus RNA (SS₁ SS₂ and SS₃) were prepared as described previously (Content &; Duesberg, 1971) and subjected to digestion with RNase T₁. Two-dimensional analyses of the digests by electrophoresis and homochromatography led to distinctive oligonucleotide patterns for each fraction of viral RNA. Almost all physically distinguishable large oligo-nucleotides of a given RNA species had a distinct base composition. It was concluded that each of the three fractions of viral RNA investigated contained different nucleotide sequences and presumably different genetic information.     

Antisense oligonucleotide inhibition of encephalomyocarditis virus RNA translation

We report the inhibition of encephalomyocarditis virus (EMCV) RNA translation in cell-free rabbit reticulocyte lysates by antisense oligonucleotides (13-17-base oligomers) complementary to (a) the viral 5' non-translated region, (b) the AUG start codon and (c) the coding sequence. Our results demonstrate that the extent of translation inhibition is dependent on the region where the complementary oligonucleotides bind. Non-complementary and 3'-non-translated-region-specific oligonucleotides had no effect on translation. A significant degree of translation inhibition was obtained with oligonucleotides complementary to the viral 5' non-translated region and AUG initiation codon. Digestion of the oligonucleotide:RNA hybrid by RNase H did not significantly increase translation inhibition in the case of 5'-non-translated-region-specific and initiator-AUG-specific oligonucleotides; in contrast, RNase H digestion was necessary for inhibition by the coding-region-specific oligonucleotide. We propose that (a) 5'-non-translated-region-specific oligonucleotides inhibit translation by affecting the 40S ribosome binding and/or passage to the AUG start codon, (b) AUG-specific oligonucleotides inhibit translation initiation by inhibiting the formation of an active 80S ribosome and (c) the coding-region-specific oligonucleotide does not prevent protein synthesis because the translating 80S ribosome can dislodge the oligonucleotide from the EMCV RNA template.     

Features of mutated changes of genomic RNA of cold-adapted and hr-variants of influenza group A virus, detected by RNA:RNA hybridization]

The presence of mutations in the majority of the genes of cold-adapted strains A/Leningrad/134/17/57 (H2N2), A/Leningrad/134/47/57 (H2N2) and A/PR/8/59/1 (H1N1) of influenza A virus has been demonstrated by the RNA-RNA hybridization with the subsequent electrophoresis of double-stranded RNA in 7.5% polyacrylamide gel. The strains were cultivated 17, 47 and 59 passages in the chicken embryos at 25 degrees C. In the genomes of variants passaged in chicken embryos at optimal temperature of incubation 36 degrees C (hr-variants) the used technique permits identification of a single mutant gene. The obtained data suppose the attenuation of cold-adapted vaccine strains of influenza A virus and their high genetic stability to be a result of selection of the variants obtaining multiple mutations in the genome during passaging of the virions at cold temperature. The attenuation of hr-variants is defined by 1-2 mutations (first of all in HA-gene) that makes understandable their inability to serve as donors for recombinant live influenza vaccines construction.     

Suppression of Leishmania RNA virus replication by capsid protein overexpression.

Some strains of the protozoan parasite genus Leishmania are persistently infected with single-segmented double-stranded RNA viruses, which are termed LRV. The function of these cytoplasmic viruses is unknown. In order to address the question of whether LRV affects the parasite's phenotype, pairs of isogenic LRV(+)-LRV- lines are required. Since the persistent nature of these viruses precludes de novo infection of virus-negative strains, LRV(+)-LRV- strains were transformed with a Leishmania expression vector expressing the LRV capsid protein with the aim of determining if LRV- promastigotes support capsid assembly and if LRV replication is affected by excess capsid protein. I found that in LRV- promastigotes, capsid protein was capable of self-assembly into virus-like capsids and that capsid overexpression in a naturally infected LRV+ line resulted in a progressive reduction in LRV copy number. Clonal lines derived from an LRV+ capsid overexpressor had no detectable levels of LRV. These results demonstrate that LRV replication can be inhibited and that a significant reduction of viral copy number has no effect on the parasite's viability in liquid medium.     

RNA polymerase of influenza virus. III. Isolation of RNA polymerase-RNA complexes from influenza virus PR8

Ribonucleoprotein (RNP) cores with RNA-synthesizing activity were prepared in two fractions, M protein-free and M protein-associated, from detergent-treated influenza virus PR8 by centrifugation through a discontinuous triple gradient of cesium sulfate, glycerol, and NP-40. The M-free RNP was fractionated by phosphocellulose column chromatography into two major RNP forms, A and B, which differed in the content of P proteins, while the M-associated RNP gave only the low P-content Form-B RNP. Starting from the high P-content Form-A RNP, an RNA-P proteins complex virtually free from NP protein was isolated by cesium sulfate equilibrium centrifugation. The complex, containing only three P proteins (P1, P2, and P3), was still active in catalyzing RNA synthesis in vitro without addition of exogenous template, indicating that NP protein is not required for the catalysis of RNA synthesis. RNA synthesis by the isolated RNA-P proteins complex was dependent on either ApG or capped RNA primers, and required four ribonucleoside triphosphates as substrates. The RNA product in this reaction was hybridizable to viral RNA. A complex of one each of the three P proteins was separated from RNA by glycerol gradient centrifugation after ribonuclease treatment or cesium chloride equilibrium centrifugation.     

Metal ion catalysis of RNA cleavage by the influenza virus endonuclease

The influenza virus RNA-dependent RNA polymerase protein complex contains an associated RNA endonuclease activity, which cleaves host mRNA precursors in the cell nucleus at defined positions 9-15 nucleotides downstream of the cap structure. This reaction provides capped oligoribonucleotides, which function as primers for the initiation of viral mRNA synthesis. The endonuclease reaction is dependent on the presence of divalent metal ions. We have used a number of divalent and trivalent metal ions alone and in combination to probe the mechanism of RNA cleavage by the influenza virus endonuclease. Virus-specific cleavage was observed with various metal ions, and maximum cleavage activity was obtained with 100 microM Mn2+ or 100 microM Co2+. This activity was about 2-fold higher than that observed with Mg2+ at the optimal concentration of 1 mM. Activity dependence on metal ion concentration was cooperative with Hill coefficients close to or larger than 2. Synergistic activation of cleavage activity was observed with combinations of different metal ions at varying concentrations. These results support a two-metal ion mechanism of RNA cleavage for the influenza virus cap-dependent endonuclease. The findings are also consistent with a structural model of the polymerase, in which the specific endonuclease active site is spatially separated from the nucleotidyl transferase active site of the polymerase module.     

Suppression of hepatitis C virus replication by baculovirus vector-mediated short-hairpin RNA expression

Short-hairpin RNAs (shRNAs) inhibit gene expression by RNA interference. Here, we report on the inhibition, by baculovirus-based vector-derived shRNAs, of core-protein expression in full-length hepatitis C virus (HCV) replicon cells. shRNAs were designed to target the highly conserved core region of the HCV genome. In particular, the core-shRNA452 containing nucleotides 452-472, as the target in the HCV core gene, dramatically inhibited the expression of the HCV core protein in replicon cells. Furthermore, HCV core-protein expression was inhibited more strongly by the vesicular stomatitis virus glycoprotein (VSV-G)-pseudotyped baculovirus vector than by the wild-type baculovirus vector.