Semiconservative synthesis of single-stranded RNA by bacteriophage phi 6 RNA polymerase.

The RNA polymerase in the nucleocapsid of Pseudomonas phaseolicola bacteriophage phi 6 transcribed large, medium, and small single-stranded RNA from the viral double-stranded RNA genome by a semiconservative (displacement) mechanism. Approximately 23%, 63%, and 65% of the nucleocapsid particles in the assay mixture synthesized at least one round of large, medium, and small single-stranded RNA molecules, respectively. Some of these particles reinitiated synthesis such that an average of 1.5 large, 33 medium, and 24 small single-stranded RNAs were synthesized from each double-stranded RNA.     

Virus-specific RNA synthesis in the midgut of silkworm, Bombyx mori, infected with cytoplasmic-polyhedrosis virus

Virus-specific RNA synthesis in the midgut of silkworm infected with cytoplasmic-polyhedrosis virus was investigated under the condition inhibiting host RNA synthesis by actinomycin D injection. Two species of virus-induced RNA were formed; one was sensitive to ribonuclease (RNase) but the other was resistant. The resistant RNA had a sedimentation coefficient of 15 S and was considered as viral progeny with doublestranded RNA. The sensitive RNA, presumably single-stranded RNA, consisted of two classes with 15 S and 22 S sedimentation coefficients. Annealing the single-stranded RNA with heat-denatured CPV-RNA indicated that the single-stranded RNA was transcribed from viral genome RNA. The function of 22 S and 15 S single-stranded RNAs was discussed from the viewpoint of virus multiplication.     

Structure of retroviral RNAs produced by cell lines derived from spontaneous lymphomas of AKR mice.

The retrovirus expression of eight independent lymphoid cell lines derived from spontaneous thymomas of AKR mice was investigated. The RNase T1 fingerprints of viral 70S RNA produced by these cell lines were compared with genome structures of the non-leukemogenic Akv virus and with two types of cloned leukemogenic viruses derived from one of the thymoma cell lines. Viral RNAs from three cell lines, SL3, 4, and 7, were indistinguishable from one another. The fingerprint patterns indicated that these cell lines produce equal amounts of two prototype, leukomogenic SL viruses that were previously isolated from the SL3 cell line. Viral RNA produced by the SL1 and SL2 cell lines contained similar components, but at a different ratio. Two other cell lines (SL5 and SL11) produced viral RNAs that resemble those of AKR mink cell focus-forming viruses. One additional line, SL9, produced viral RNA of a novel structure. The complex pattern of viral RNA expression observed for these lymphoid cell lines can be interpreted in terms of recombination among three types of endogenous viral sequences: the Akv virus, a xenotropic virus, and an SL (for spontaneous leukemia) virus.     

Viral RNAs Associated with Ribosomes in Sindbis Virus-Infected HeLa Cells

Virus specific RNA ribosome complexes were isolated by sucrose density gradient centrifugation of cytoplasmic extracts from HeLa cells infected at 42 C with an RNA(+) mutant (ts2) of Sindbis virus. Viral RNA-ribosome complexes were accumulated by infected cells treated with sodium fluoride and cycloheximide. The RNA-ribosome complexes were characterized by (i) their sensitivity to the action of ribonuclease or ethylenediaminetetraacetic acid, (ii) their density in cesium chloride gradients, and (iii) presence of host ribosomes and viral RNAs. The viral RNAs were isolated and characterized. The results showed that two species of single-stranded RNAs (a 28s and 18 to 15s species) were associated with the complexes. Base composition analysis of the viral RNAs indicated that both species had a higher adenine content than the 42s or 26s forms of viral RNAs. The RNAs associated with the ribosome complexes were virus specific since they annealed with denatured double-stranded RNAs from the infected cells. Little or no 42S RNA was associated with the RNA-ribosome complexes. The results suggest that the 28s and 18 to 15s forms of RNAs may represent viral messenger RNAs.     

RNA dependent RNA polymerase activity associated with the double-stranded RNA virus of Giardia lamblia.

Giardia lamblia, a parasitic protozoan, can contain a double-stranded RNA (dsRNA) virus, GLV (1). We have identified an RNA polymerase activity present specifically in cultures of GLV infected cells. This RNA polymerase activity is present in crude whole cell lysates as well as in lysates from GLV particles purified from the culture medium. The RNA polymerase has many characteristics common to other RNA polymerases (e.g. it requires divalent cations and all four ribonucleoside triphosphates), yet it is not inhibited by RNA polymerase inhibitors such as alpha-amanitin or rifampicin. The RNA polymerase activity synthesizes RNAs corresponding to one strand of the GLV genome, although under the present experimental conditions, the RNA products of the reaction are not full length viral RNAs. The in vitro products of the RNA polymerase reaction co-sediment through sucrose gradients with viral particles; and purified GLV viral particles have RNA polymerase activity. The RNA polymerase activities within and outside of infected cells closely parallel the amount of virus present during the course of viral infection. The similarities between the RNA polymerase of GLV and the polymerase associated with the dsRNA virus system of yeast are discussed.     

Alignment of a restriction map with the genetic map of bacteriophage T4.

We reported previously that polycytidylate [poly(C)]-dependent RNA polymerase activity was a property of small spherical or triangular reovirus-specific particles which sedimented at 13 to 19S and were composed solely of the reovirus protein, sigma NS. Depending on the fraction of cellular extracts from which they were obtained, these particles exhibited marked differences in stability. Most 13 to 19S particles from a particular fraction repeatedly disaggregated into smaller 4 to 5S subunits with no enzymatic activity. Disruption of many particles could be prevented and polymerase activity retained after these particles had bound different single-stranded (ss) RNAs. Our previous results indicated that there was heterogeneity among the 13 to 19S particles in that possession of poly(C)-dependent RNA polymerase activity was a property of only some. Support for this heterogeneity was derived from the demonstration in this report that there were at least three types of binding sites present within particles in any purified preparation: (i) those binding only poly(C); (ii) those binding only reovirus ss RNAs; and (iii) those binding one or the other, but not both at the same time. It is suggested that only those particles able to bind either poly(C) or reovirus ss RNAs had poly(C)-dependent RNA polymerase activity, as reovirus ss RNAs markedly inhibited the polymerase activity. All three size classes of reovirus ss RNAs were equally effective in binding, but once bound, they were not copied. It is possible that heterogeneity in binding capacity of different particles comprised of only one protein, sigma NS, could result from the ability of subunits containing this protein to assemble into slightly different 13 to 19S particles with specificity of binding or polymerase activity conferred by the configuration of the assembled particles. The high capacity of sigma NS to bind many different nucleic acids with some specificity suggests that these particles may act during infection as condensing agents to bring together 10 reovirus ss RNA templates in preparation for double-stranded RNA synthesis.