Characterization of the 5''-terminal capped structures of late simian virus 40-specific mRNA.

32P-labeled, late simian virus 40-specific RNA was isoalted from infected CV1 cells and completely degraded with RNase T2 and bacterial alkaline phosphatase. The RNase-resistant material was fractionated two dimensionally and further characterized with Penicillium nuclease and nucleotide pyrophosphatase. Two major 5' termini were identified in late simian virus 40 RNA, namely, 7-methyl Gppp 2',6-dimethyl ApUp and 7-methyl Gppp 2',6-dimethyl Ap 2'-methyl, UpUp. Both 5' termini are present in unfractionated viral RNA as well as in the separated 16S and 19S species. As both caps differ only in secondary modification, it is possible that they are derived from the same site on the DNA. The relatively higher cap II content of the 16S mRNA may be related to its slower rate of turnover.     

Multiple 5' terminal cap structures in late polyoma virus RNA.

Nuclear and cytoplasmic polyoma virus-specific RNA extracted from 32P-labeled mouse embryo cells late during productive viral infection was analyzed for the presence of 5' terminal capped structures by complete digestion with RNAases T1, T2 and A, followed by two-dimensional electrophoretic fractionation. Seven major cap I structures (m7 GpppNm1pN2p) were observed in both cases. These termini were further characterized by digestion with penicillium nuclease P1, followed by product analysis in a variety of alternative separate systems. Each structure had an individual combination of N1 and N2 nucleotides, where N1 was always a purine nucleotide but N2 was any nucleotide subject to the single exception that m7GpppGmpCp is found only in low yield. Four different cap II derivatives (m7GpppNm1pNm2pN3p) of four of the cap I structures were also detected in cytoplasmic RNA. None of the termini described derived from contaminating host cell RNA. All of these cap structures mapped on the polyoma viral DNA genome between 66 and 71 map units, a region distant from the 5' end of the bodies of two of the three late polyoma mRNAs. All the polyoma virus-specific cap structures, however, were present in each of the purified 16S, 18S and 19s late mRNAs. These data suggested that families of capped leader sequences of varying sizes are attached to the main body of each late polyoma mRNA species by a splicing mechanism.     

Altered utilization of splice sites and 5'' termini in late RNAs produced by leader region mutants of simian virus 40.

We compared the 5' termini and splices of the late 16S and 19S RNAs synthesized by wild-type simian virus 40 and five mutants containing deletions in their late leader region. All mutants produced more unspliced 19S RNA than did wild-type virus, and in two mutants, unspliced 19S RNA constituted more than 60% of the total 19S species. The other three mutants each utilized predominantly a different one of the three spliced species of 19S mRNA. All mutants also produced decreased quantities of 16S mRNA, indicating that they may be defective for splicing both late RNAs. None of the 5' termini of the 16S and 19S RNAs made by the five mutants predominated as in those made by the wild type. Some of the mutant 5' termini were the same as those used by the wild type, whereas others were different. Although present, the major 5'-end positions used by the wild type were frequently not used as major sites by the mutants. In addition, mutants with very similar deletion endpoints synthesized RNAs with different 5' ends. Thus, downstream mutations have a pronounced effect on the location of 5' ends of the late RNAs, and there is no obvious involvement of a measuring function in the placement of 5' ends. For all mutants and wild-type virus, the 5' termini used for 16S and 19S RNAs showed major differences, with some degree of correlation found between the 5' ends and the internal splices of specific mRNA species. A model for the regulation of simian virus 40 late gene expression is presented to explain these findings.     

A splice junction deletion deficient in the transport of RNA does not polyadenylate nuclear RNA.

A late region deletion mutant of simian virus 40 (dl5) was previously shown to be deficient in the transport of nuclear RNA. This is a splice junction deletion that has lost the 3' end of an RNA leader, an intervening sequence, and the 5' end of the splice acceptor site on the body of the mRNA. In this report, we analyzed the steady-state structure of the untransported nuclear RNA. The 5' ends of this RNA are heterogeneous but contain a prominent 5' end at the normal position (nucleotide 325) in addition to several other prominent 5' ends not seen in wild-type RNA. The 3' end of this RNA does not occur at the usual position (nucleotide 2674) of polyadenylation; instead, this RNA is non-polyadenylated, with the 3' end occurring either downstream or upstream of the normal position.     

5'' Caps in hnRNA: absence of m32,2,7G and size distribution of capped molecules.

In HeLa cells the "small nuclear" RNA has a cap II 5' structure (8)-- m32,2,7G(5') pppXmpYmp-- where X and Y are 2'0 methylated adenosine and uridine. In contrast hnRNA contains only cap I structures were the 2'0 methylated residue may be any base as was earlier reported for cytoplasmic mRNA (8,9,11). With a clear distinction between the source of these two caps an analysis of the size distribution of capped hnRNA could be performed which revealed over 65% of the capped hnRNA molecules were larger than cytoplasmic mRNA.