Identification of a protein linked to nascent poliovirus RNA and to the polyuridylic acid of negative-strand RNA.

A protein similar to that previously demonstrated on poliovirus RNA and replicative intermediate RNA (VPg) was found on all sizes of nascent viral RNA molecules and on the polyuridylic acid isolated from negative-strand RNA. 32P-labeled nascent chains were released from their template RNA and fractionated by exclusion chromatography on agarose. Fingerprint analysis using two-dimensional polyacrylamide gels of RNase T1 oligonucleotides derived from nascent chains of different lengths showed that a size fractionation of nascent chains was achieved. VPg was recovered from nascent chains varying in length from 7,500 nucleotides (full-sized RNA) to about 500 nucleotides. No other type of 5' terminus could be demonstrated on nascent RNA, and the yield of VPg was consistent with one molecule of the protein on each nascent chain. These results are consistent with the concept that the protein is added to the 5' end of the growing RNA chains at a very early stage, possibly as a primer of RNA synthesis. Analysis of the polyuridylic acid tract isolated from the replicative intermediate and double-stranded RNAs indicated that a protein of the same size as that found on the nascent chains and virion RNA is also linked to the negative-strand RNAs. It is likely that a similar mechanism is responsible for initiation of synthesis of both plus- and minus-strand RNAs.     

Dexamethasone increases the number of RNA polymerase II molecules transcribing integrated mouse mammary tumor virus DNA and flanking mouse sequences.

In mouse Ltk- cells that were transfected with recombinant bacteriophage DNA containing a complete proviral copy of an integrated endogenous mouse mammary tumor virus (MMTV) with its flanking cellular sequences, the newly acquired MMTV proviruses were transcribed in a glucocorticoid-responsive fashion. After hormone treatment of selected cell clones in culture we isolated the nuclei, elongated the nascent RNA chains in vitro, and determined the number of RNA polymerase II molecules on the transcribed MMTV DNA as well as on the flanking mouse DNA sequences. We found that the specific increase in the polymerase loading after hormone treatment is proportional to the increase in the amount of stable MMTV mRNA. When the DNA sequences which are responsible for hormone-receptor binding and for the increased MMTV mRNA levels were deleted, no increase in RNA polymerase II loading on MMTV DNA was observed. Nuclear RNA chains which were transcribed in response to hormone treatment were detected not only from the transfected MMTV DNA but also from the mouse DNA sequences adjacent to the 3' end of the provirus.     

Template recognition and chain elongation in DNA synthesis in vitro.

DNA polymerase from Escherichia coli (Pol I) and from avian myeloblastosis virus (AMV polymerase) were compared for the manner in which they catalyze the polymerization of deoxynucleotides upon a variety of synthetic and natural templates. It was found that the rates of nucleotide incorporation with different natural RNAs were similar. Both polymerases have an associated RNA endonuclease which hydrolyses RNA templates containing double-stranded regions. This activity depends on the presence of the complementary deoxynucleoside triphosphates, and/or polymerization. Both enzymes copy natural DNA, which has been sonicated and treated with E. coli exonuclease III, at the same rate. However, avian myeloblastosis virus DNA polymerase, which has no associated DNA exonuclease activity, is unable to copy double-stranded DNA and copies DNAase-treated DNA only 10% as well as Pol I. Pol I copied all the homopolymers investigated at a greater rate than AMV polymerase with the exception of poly(C) · oligo(dG). However, the initial rate of chain elongation, as measured by gel electrophoresis, was the same for the two polymerases, approximately 300 nucleotides incorporated per minute. Template saturation experiments show a stoichiometric relationship between template and enzyme at optimal rates of nucleotide incorporation which suggests that all enzyme molecules are potential catalysts. Enzyme saturation experiments indicate that not all enzyme molecules are “effectively” bound to a template. Fewer AMV polymerase than Pol I molecules are functionally bound to a particular template. From these data, it is concluded that the two polymerases elongate DNA chains in a similar way and that the manner in which the polymerases bind to a particular template accounts for the discrepancies found in their turnover numbers.