Inhibition of host protein synthesis by vaccinia virus: fate of cell mRNA and synthesis of small poly (A)-rich polyribonucleotides in the presence of actinomycin D.

Purified vaccinia virus rapidly inhibited HeLa cell protein synthesis in the presence of actinomycin D. Under these conditions host polyribosomes were extensively degraded but the mRNA was stable as indicated by a greater than 90% recovery of prelabeled polyadenylylated RNA. Although actinomycin D prevented the synthesis of host mRNA and poly(A) in uninfected cells, incorporation of adenosine into poly(A) was inhibited by less than 50% in infected cells. Further analysis indicated that there was little or no normal size viral mRNA but that a unique class of small poly(A)-rich RNA was made in the presence of actinomycin D. From measurements of the RNase resistance and base composition of the RNA, approximately 40% of the nucleotide sequence was estimated to be poly(A). The poly(A)-rich RNA was found associated with small polyribosomes and monoribosomes that were inactive in protein synthesis. It was suggested that the poly(A) segment of the RNA is formed by the poly(A) polymerase previously found in vaccinia virus cores and that the inactive RNA, by competing with host mRNA, may contribute to the virus-mediated inhibition of host protein synthesis observed in the presence of actinomycin D.     

DNA methylation. Inhibition of de novo and maintenance methylation in vitro by RNA and synthetic polynucleotides

A partially purified HeLa cell DNA methylase will methylate a totally unmethylated DNA (de novo methylation) at about 3-4% the rate it will methylate a hemimethylated DNA template (maintenance methylation). Our evidence suggests that many, if not most, dCpdG sequences in a natural or synthetic DNA can be methylated by the enzyme. There is a powerful inhibitor of DNA methylase activity in crude extracts which has been identified as RNA. The inhibition of DNA methylase by RNA may indicate that this enzyme is regulated in vivo by the presence of RNA at specific chromosomal sites. The pattern of binding of RNA to DNA in the nucleosome structure and the DNA replication complex may determine specific sites of DNA methylation. An even more potent inhibition of DNA methylase activity is observed with poly(G), but not poly(C), poly(A), or poly(U). The only other synthetic polynucleotides studied which inhibit DNA methylation as well as poly(G) are the homopolymers poly(dC).poly(dG) and poly (dA).poly(dT). These results point out the unique importance of the guanine residue itself in the binding of the DNA methylase to dCpdG, the site of cytosine methylation. The surprising inhibition of the methylation reaction by poly(dA).poly(dT), which is itself not methylated by the enzyme, suggests the possible involvement of adjacent A and T residues in influencing the choice of sites of methylation by the enzyme.     

Isolation and characterization of poly(A)-containing polyoma "early" and "late" messenger RNAs.

During late lytic infection of mouse kidney cell cultures polyoma 16S and 19S (late 19S RNA) were isolated by oligo(dT)-cellulose chromatography. Approximately 60-80% of total cytoplasmic polyoma RNA contained tracts of poly(A) which were retained by oligo(dT)-cellulose. Early in lytic infection when viral DNA synthesis and the production of capsid protein are blocked by the addition of 5-fluorodeoxyuridine, approximately 100% of polyoma "early" 19S RNA was quantitatively retained by oligo(dT)-cellulose indicating the presence of poly(A) tracts on most 19S mRNA molecules. In addition, 2 classes polyoma RNA, synthesized after the onset of cellular RNA synthesis under conditions where DNA synthesis is inhibited with 5-fluorodeoxyuridine, were found to contain tracts of poly(A). These species sedimenting at 16S and 19S in aqueous sucrose density gradients were also quantitatively retained by oligo (dT)-cellulose.     

Poly(dA).poly(dT) rich sequences are not sufficient to exclude nucleosome formation in a constitutive yeast promoter.

It was suggested that poly(dA).poly(dT) rich sequences in yeast Saccharomyces cerevisiae act as elements of constitutive promoters by exclusion of nucleosomes (Struhl, K. (1985). Proc. Natl. Acad. Sci. USA 82, 8419-8423). We have mapped the chromatin structure of the pet56-his3-ded1 region in minichromosomes and show that the poly(dA).poly(dT) sequences are located in nuclease sensitive regions. DNA fragments from the nuclease sensitive promoter region of DED1 were used for nucleosome reconstitution in vitro. We show that all sequences can form nucleosome cores and that the poly(dA).poly(dT) sequence can be incorporated in nucleosome cores. The results suggest that the nuclease sensitivity found in vivo is not established by poly(dA).poly(dT) mediated exclusion of nucleosomes.     

Model RNA-directed DNA synthesis by avian myeloblastosis virus DNA polymerase and its associated RNase H.

A model RNA template-primer system is described for the study of RNA-directed double-stranded DNA synthesis by purified avian myeloblastosis virus DNA polymerase and its associated RNase H. In the presence of complementary RNA primer, oligo(rI), and the deoxyribonucleoside triphosphates dGTP, dTTP, and dATP, 3'-(rC)30-40-poly(rA) directs the sequential synthesis of poly(dT) and poly(dA) from a specific site at the 3' end of the RNA template. With this model RNA template-primer, optimal conditions for double-stranded DNA synthesis are described. Analysis of the kinetics of DNA synthesis shows that initially there is rapid synthesis of poly(dT). After a brief time lag, poly(dA) synthesis and the DNA polymerase-associated RNase H activity are initiated. While poly(rA) is directing the synthesis of poly(dT), the requirements for DNA synthesis indicate that the newly synthesized poly(dT) is acting as template for poly(dA) synthesis. Furthermore, selective inhibitor studies using NaF show that activation of RNase H is not just a time-related event, but is required for synthesis of the anti-complementary strand of DNA. To determine the specific role of RNase H in this synthetic sequence, the primer for poly(dA) synthesis was investigated. By use of formamide--poly-acrylamide slab gel electrophoresis, it is shown that poly(dT) is not acting as both template and primer for poly(dA) synthesis since no poly(dT)-poly(dA) covalent linkages are observed in radioactive poly(dA) product. Identification of 2',3'-[32P]AMP on paper chromatograms of alkali-treated poly(dA) product synthesized with [alpha-32P]dATP as substrate demonstrates the presence of rAMP-dAMP phosphodiester linkages in the poly(dA) product. Therefore, a new functional role of RNase H is demonstrated in the RNA-directed synthesis of double-stranded DNA. Not only is RNase H responsible for the degradation of poly(rA) following formation of a poly(rA)-poly(dT) hybrid but also the poly(rA)fragments generated are serving as primers for initiation of synthesis of the second strand of the double-stranded DNA.     

Mitochondrial poly(A) RNA synthesis during early sea urchin development

The synthesis of mitochondrial messenger RNA during early sea urchin development was examined. Oligo(dT) chromatography and electrophoresis on aqueous or formamide gels of mitochondrial RNA from pulse-labeled embryos showed the presence of eight distinct poly(A)-containing RNA species, ranging in size from 9 to 22 S. Nuclease digestion of these RNAs revealed poly(A) sequences of 4 S size. Using sea urchin anucleate fragments, we were able to demonstrate that all eight messenger RNAs are transcribed from mitochondrial DNA, rather than being transcribed from nuclear DNA and imported into the mitochondria.There was no change in the electrophoretic profile of the eight poly(A) RNAs when embryos were pulsed with [³H]uridine at various times after fertilization. Neither was there any change in the incorporation of [³H]uridine into these species or in the percentage of total newly synthesized mitochondrial RNA that contains poly(A) sequences as development progresses. Even though these RNAs appear to be transcribed at a constant rate throughout early development, they were not detected in mitochondrial polysomes until 18 hr after fertilization.     

Inhibition of a novel subspecies of DNA polymerase α by 2′-deoxy-2′-azidoadenosine 5′-triphosphate

DNA polymerase α₁, a subspecies of DNA polymerase α of Ehrlich ascites tumor cells, was associated with a novel RNA polymerase activity and utilized poly(dT) and single-stranded circular fd DNA as a template without added primer in the presence of ribonucleoside triphosphates and a specific stimulating factor. DNA synthesis in the above system was inhibited by the ATP analogue, 2′-deoxy-2′-azidoadenosine 5′-triphosphate more than the DNA synthesis with poly(dT)·oligo(rA) by DNA polymerase α₁ and RNA synthesis by mouse RNA polymerases I and II. Kinetic analysis showed that the analogue inhibited DNA polymerase α₁ activity on poly(dT) competitively with respect to ATP, suggesting that the analogue inhibited RNA synthesis by the associated RNA polymerase activity.     

The poly(A)(+)RNA sequence complexity is also represented in poly(A)(-)RNA in sea-urchin embryos

The extent to which the poly(A)(+)RNA sequence complexity from sea-urchin embryos is also represented in poly(A)(-)RNA was determined by cDNA cross-hybridization. Eighty percent or more of both the cytoplasmic poly(A)(+)RNA and polysomal poly(A)(+)RNA sequences appeared in a poly(A)(-) form. In both cases, the cellular concentrations of the poly(A)(-)RNA molecules that reacted with the cDNA were similar to the concentrations of the homologous poly(A)(+) sequences. Additionally, few, if any, abundant poly(A)(+)mRNA molecules were quantitatively discriminated by polyadenylation, since the abundant poly(A)(+)sequences were also abundant in poly(A)(-)RNA. Neither degradation nor inefficient binding to oligo (dT)-cellulose can account for the observed cross-reactivity. These data indicate that, in sea-urchin embryos, the poly(A) does not regulate the utilization of mRNA by demarcating an mRNA subset that is specifically and completely polyadenylated.