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.     

Mapping 5'' termini of JC virus early RNAs.

Within its enhancer promoter region, the MAD-1 strain of JC virus (JCV) has two 98-base-pair tandem repeats, each containing a TATA box-like sequence. In the present study, polyadenylated early JCV mRNAs were isolated 5 or 29 days after infection of primary human fetal glial (PHFG) cells. By using S1 nuclease, the 5' termini of the early mRNAs were mapped to nucleotide position(s) (np) 122 through 125, which lies within an AT rich region (at np 113 through 127). In contrast, when JCV DNA was transcribed in vitro, we observed a single major cluster of 5' start sites at np 94 through 97, which is approximately 25 base pairs downstream from one of the TATA boxes. By day 5, the earliest time at which JCV RNA was detected, viral DNA replication had begun; it continued for at least an additional 20 days. Since more late than early RNA was present at 5 days postinfection, the early RNAs whose synthesis began at np 122 through 125 may be analogous to SV40 late early mRNA (Ghosh and Lebowitz, J. Virol. 40:224-240, 1981). However, we have not detected RNAs with 5' termini 25 to 30 bp downstream from the TATA box at earlier times. While JCV contains two identical TATA boxes, one in each of the 98-bp repeats, only the upstream TATA box functions as an early promoter element.     

The translational map of the Autographa californica nuclear polyhedrosis virus (AcNPV) genome.

We have mapped early and late viral gene products expressed in Autographa californica nuclear polyhedrosis virus ( AcNPV )-infected Spodoptera frugiperda cells by cell-free translation of virus-specific RNA which was selected by hybridization to cloned restriction endonuclease fragments of AcNPV DNA. Proteins synthesized in vitro were labeled with [35S]methionine and analyzed by SDS-polyacrylamide gel electrophoresis followed by fluorography. At least four early AcNPV -specific polypeptides were found which mapped in two regions of the genome (9-25 and 43-59 map units). These early mRNAs are also synthesized at late times in the infection cycle. Cell-free translation of restriction fragment-selected late AcNPV -specific RNA (24 h post-infection) resulted in the identification and mapping of 24 viral proteins. Curiously, the region between approximately 70 and 80 map units on the viral genome has been found silent with respect to mRNA which is translatable in a cell-free system. However, there may be RNA transcribed from this viral DNA segment.     

tRNA-like structures of plant viral RNAs: conformational requirements for adenylation and aminoacylation

Bromo- and cucumovirus RNAs contain a tRNA-like structure as an integral part of their genome. This structure is located at the 3' end of the viral RNA and is an acceptor of tyrosine. The 3' regions of representative viral RNAs have been sequenced and quite unorthodox secondary foldings have been proposed for these 3' ends. The question therefore remained as to how these structures could be recognized by tRNA-specific enzymes. We have established the minimum number of nucleotides from the 3' end of the brome mosaic virus and broad bean mottle virus RNAs required for the formation of structures recognized by the tyrosyl-tRNA synthetase and/or the tRNA nucleotidyltransferase. The results obtained delineate the length of the tRNA-like region, and indicate that the 5' region of the tRNA-like structure participates in the formation of the amino acid stem. This has led us to propose an 'L'-shaped secondary structure for these tRNA-like regions.     

At least 104 nucleotides are transposed from the 5' terminus of the avian sarcoma virus genome to the 5' termini of smaller viral mRNAs.

Cells producing avian sarcoma virus (ASV) contain at least three virus-specific mRNAs, two of which are encoded within the 3' half of the viral genome. Each of these viral RNAs can hybridize with single-stranded DNA(cDNA5') that is complementary to a sequence of 101 nucleotides found at the 5' terminus of the ASV genome, but not within the 3' half of the genome. We proposed previously (Weiss, Varmus and Bishop, 1977) that this nucleotide sequence may be transposed to the 5' termini of viral mRNAs during the genesis of these RNAs. We now substantiate this proposal by reporting the isolation and chemical characterization of the nucleotide sequences complementary to cDNA5' in the genome and mRNAs of the Prague B strain of ASV. We isolated the three identified classes of ASVmRNA (38, 28 and 21S) by molecular hybridization; each class of RNA contained a "capped" oligonucleotide identical to that found at the 5' terminus of the ASV genome. When hybridized with cDNA5', each class of RNA gave rise to RNAase-resistant duplex hybrids that probably encompassed the full extent of cDNA5'. The molar yields of duplex conformed approximately to the number of virus-specific RNA molecules in the initial samples; hence most if not all of the molecules of virus-specific RNA could give rise to the duplexes. The duplexes prepared from the various RNAs all contained the capped oligonucleotide found at the 5' terminus of the viral genome and had identical "fingerprints" when analyzed by two-dimensional fractionation following hydrolysis with RNAase T1. In contrast, RNA representing the 3' half of the ASV genome did not form hybrids with cDNA5'. We conclude that a sequence of more than 100 nucleotides is transposed from the 5' end of the ASV genome to the 5' termini of smaller viral RNAs during the genesis of these RNAs. Transposition of nucleotide sequences during the production of mRNA has now been described for three families of animal viruses and may be a common feature of mRNA biogenesis in eucaryotic cells. The mechanism of transposition, however, and the function of the transposed sequences are not known.     

The rhinovirus type 14 genome contains an internally located RNA structure that is required for viral replication.

Cis-acting RNA signals are required for replication of positive-strand viruses such as the picornaviruses. Although these generally have been mapped to the 5' and/or 3' termini of the viral genome, RNAs derived from human rhinovirus type 14 are unable to replicate unless they contain an internal cis-acting replication element (cre) located within the genome segment encoding the capsid proteins. Here, we show that the essential cre sequence is 83-96 nt in length and located between nt 2318-2413 of the genome. Using dicistronic RNAs in which translation of the P1 and P2-P3 segments of the polyprotein were functionally dissociated, we further demonstrate that translation of the cre sequence is not required for RNA replication. Thus, although it is located within a protein-coding segment of the genome, the cre functions as an RNA entity. Computer folds suggested that cre sequences could form a stable structure in either positive- or minus-strand RNA. However, an analysis of mutant RNAs containing multiple covariant and non-covariant nucleotide substitutions within these putative structures demonstrated that only the predicted positive-strand structure is essential for efficient RNA replication. The absence of detectable minus-strand synthesis from RNAs that lack the cre suggests that the cre is required for initiation of minus-strand RNA synthesis. Since a lethal 3' noncoding region mutation could be partially rescued by a compensating mutation within the cre, the cre appears to participate in a long-range RNA-RNA interaction required for this process. These data provide novel insight into the mechanisms of replication of a positive-strand RNA virus, as they define the involvement of an internally located RNA structure in the recognition of viral RNA by the viral replicase complex. Since internally located RNA replication signals have been shown to exist in several other positive-strand RNA virus families, these observations are potentially relevant to a wide array of related viruses.     

The structure of two subgenomic RNAs from human influenza virus A/PR/8/34.

The nucleotide sequences of two subgenomic RNA segments from influenza virus A/PR/8/34 have been determined by cloning viral cDNA into the vector M13mp7. Sequence analysis was facilitated by a re-cloning strategy which takes advantage of both wild-type and amber derivatives of the M13 vector. The RNA species (444 and 480 nucleotides) contain the 5' and 3' termini of segment 1 and therefore derive by simple internal deletions of this segment. However, these species are not exact copies of the terminal regions of the progenitor segment but contain a few base changes. These differences suggest that after these RNAs have arisen, their sequences can drift, presumably reflecting a lower selective pressure than on the standard RNA segments.