Mapping 5'' termini of JC virus late RNA.

The 5' termini of late mRNAs were mapped 17 to 19 days after primary human fetal glial cells were infected with JC virus. The major 5' start sites spanned a region of approximately 250 nucleotides, starting at nucleotide 5114, which was on the early side of the replication origin, and extending to nucleotide 242, which was on the late side of the 98-base-pair (bp) repeats. The sequence TATATAT was contained within each of the 98-bp repeats but does not specify 5' start sites in vivo. However, the sequence TACCTA, which occurred 25 to 30 bp upstream of the simian virus 40 nucleotide position 325 start site (J. Brady, M. Radonovich, M. Vodkin, V. Natarajan, M. Thoren, G. Das, J. Janik, and N. P. Salzman, Cell 31:625-633, 1982) and functions as a surrogate TATA box, was present 30 bp upstream of two JC virus start sites.     

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 actin gene in yeast Saccharomyces cerevisiae: 5'' and 3'' end mapping, flanking and putative regulatory sequences

The 5' and 3' flanking regions of the yeast actin gene have been sequenced and the ends of the actin mRNA were determined by the single-strand nuclease mapping procedure. The mRNA starts with a pyrimidine residue 141 (or 140) nucleotides upstream from the initiation codon. The actin gene lacks a typical "TATA" box 30 base pairs upstream from the mRNA start site but it contains a region homologous to the canonical sequence 5'-GGCTCAATCT-3' which is found in several eukaryotic genes 70 to 80 bp upstream from the mRNA cap site. Judging from the S1 nuclease mapping, there are two populations of actin mRNA terminating 98 and 107 nucleotides downstream from the stop codon. The 3' termini are preceded by three AATAAA sequences found in most eukaryotic polyadenylated mRNAs.     

Nucleotide sequence of the 5'' noncoding region and part of the gag gene of mouse mammary tumor virus; identification of the 5'' splicing site for subgenomic mRNAs

We have determined the sequence of the first 1371 nucleotides at the 5' end of the genome of mouse mammary tumor virus using molecularly cloned proviral DNA of the GR virus strain. The most likely initiation codon used for the gag gene of mouse mammary tumor virus is the first one, located 312 nucleotides from the 5' end of the viral RNA. The 5' splicing site for the subgenomic mRNA's is located approximately 288 nucleotides downstream from the 5' end of the viral RNA. From the DNA sequence the amino acid sequence of the N-terminal half of the gag precursor protein, including p10 and p21, was deduced (353 amino acids).     

Mapping of the 5' termini of two adeno-associated virus 2 RNAs in the left half of the genome.

The left 45% of the adeno-associated virus 2 genome was sequenced. The 5' termini of two adeno-associated virus-specific RNAs were mapped at the nucleotide level within this region of the genome (nucleotides 286 to 288 and 871 to 874). Both of these 5' termini map 31 +/- 2 nucleotides downstream from the start of "TATA' boxes.     

Identification of a specific exon sequence that is a major determinant in the selection between a natural and a cryptic 5'' splice site.

The first intron of the early region 3 from adenovirus type 2 contains a cryptic 5' splice site, Dcr1, 74 nucleotides downstream from the natural site D1. The cryptic site can be activated when the natural site is inactivated by mutagenesis. To investigate the basis for selection between a natural and a cryptic 5' splice site, we searched for cis-acting elements responsible for the exclusive selection of the natural site. We show that both the relative intrinsic strength of the sites and the sequence context affect the selection. A 120-nucleotide segment located at the 3' end of exon 1 enhances splicing at the proximal site D1; in its absence the two sites are used according to their strength. Thus, three cis-acting elements are involved in the silencing of the cryptic site: the sequence of D1, the sequence of Dcr1, and an upstream exonic sequence. We show that the exonic element folds, in solution, into a 113-nucleotide-long stem-loop structure. We propose that this potential stem-loop structure which is located 6 nucleotides upstream of the exon 1-intron junction is responsible for the preferential use of the natural 5' splice site.     

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.     

The consensus sequence YGTGTTYY located downstream from the AATAAA signal is required for efficient formation of mRNA 3'' termini.

Our previous DNA sequence comparisons of 3' terminal portions from equivalent herpes simplex virus type 1 (HSV-1) and HSV-2 genes identified a conserved sequence (consensus YGTGTTYY; Y = pyrimidine) located approximately 30bp downstream from the AATAAA signal. We report here that this signal is located downstream from 67% of the mammalian mRNA 3' termini examined. Using constructions with the bacterial chloramphenicol acetyl transferase (CAT) gene linked to an HSV 'terminator' fragment, we show that deletions in the 'terminator' reduce CAT activities and the levels of CAT mRNA 3' termini. Specifically: (1) deletions of downstream sequences which extend up to the consensus YGTGTTYY signal reduce CAT levels to values 35% of those obtained with undeleted plasmids, (2) a deletion of a further 14bp, which removes the YGTGTTYY consensus but not the poly A site, reduces CAT activities to 1%-4%. The levels of CAT mRNA 3' termini reflect the reductions in CAT activities however, levels of mRNA 5' termini are unaffected by these deletions. The RNA produced in the absence of the YGTGTTYY signal is present in the cytoplasm although no CAT activity is detectable.     

The primary structure of the Saccharomyces cerevisiae gene for alcohol dehydrogenase

The DNA sequence of the gene for the fermentative yeast alcohol dehydrogenase has been determined. The structural gene contains no introns. The amino acid sequence of the protein as determined from the nucleotide sequence disagrees with the published alcohol dehydrogenase isozyme I (ADH-I) sequence for 5 of the 347 amino acid residues. At least one, and perhaps as many as four, of these differences is probably due to ADH-I protein heterogeneity in different yeast strains and not to sequencing errors. S1 nuclease was used to map the 5' and 3' ends of the ADH-I mRNA. There are two discrete, mature 5' ends of the mRNA, mapping 27 and 37 nucleotides upstream of the translation initiating ATG. These two equally prevalent termini are 101 and 91 nucleotides, respectively, downstream from a TATAAA sequence. Analysis of the 3' end of ADH-I mRNA disclosed two minor ends upstream of the major poly(A) addition site. These three ends map 24, 67, and 83 nucleotides, respectively, downstream from the translation-terminating TAA triplet. The sequence AA-TAAG is found 28 to 34 nucleotides upstream of each ADH-I mRNA poly(A) addition site. Sequence comparisons of these three 3' ends with those for four other yeast mRNAs yielded a 13-nucleotide consensus sequence to which TAAATAAGA is central. All of the known yeast poly(A) addition sites map at or near the A residue of a CTA site 25 to 40 nucleotides downstream from this consensus octamer.     

Analysis of cDNAs of the proto-oncogene c-src: heterogeneity in 5'' exons and possible mechanism for the genesis of the 3'' end of v-src.

To further characterize the gene structure of the proto-oncogene c-src and the mechanism for the genesis of the v-src sequence in Rous sarcoma virus, we have analyzed genomic and cDNA copies of the chicken c-src gene. From a cDNA library of chicken embryo fibroblasts, we isolated and sequenced several overlapping cDNA clones covering the full length of the 4-kb c-src mRNA. The cDNA sequence contains a 1.84-kb sequence downstream from the 1.6-kb pp60c-src coding region. An open reading frame of 217 amino acids, called sdr (src downstream region), was found 105 nucleotides from the termination codon for pp60c-src. Within the 3' noncoding region, a 39-bp sequence corresponding to the 3' end of the RSV v-src was detected 660 bases downstream of the pp60c-src termination codon. The presence of this sequence in the c-src mRNA exon supports a model involving an RNA intermediate during transduction of the c-src sequence. The 5' region of the c-src cDNA was determined by analyzing several cDNA clones generated by conventional cloning methods and by polymerase chain reaction. Sequences of these chicken embryo fibroblast clones plus two c-src cDNA clones isolated from a brain cDNA library show that there is considerable heterogeneity in sequences upstream from the c-src coding sequence. Within this region, which contains at least 300 nucleotides upstream of the translational initiation site in exon 2, there exist at least two exons in each cDNA which fall into five cDNA classes. Four unique 5' exon sequences, designated exons UE1, UE2, UEX, and UEY, were observed. All of them are spliced to the previously characterized c-src exons 1 and 2 with the exception of type 2 cDNA. In type 2, the exon 1 is spliced to a novel downstream exon, designated exon 1a, which maps in the region of the c-src DNA defined previously as intron 1. Exon UE1 is rich in G+C content and is mapped at 7.8 kb upstream from exon 1. This exon is also present in the two cDNA clones from the brain cDNA library. Exon UE2 is located at 8.5 kb upstream from exon 1. The precise locations of exons UEX and UEY have not been determined, but both are more than 12 kb upstream from exon 1. The existence and exon arrangements of these 5' cDNAs were further confirmed by RNase protection assays and polymerase chain reactions using specific primers. Our findings indicate that the heterogeneity in the 5' sequences of the c-src mRNAs results from differential splicing and perhaps use of distinct initiation sites. All of these RNAs have the potential of coding for pp60c-src, since their 5' exons are all eventually joined to exon 2.