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.     

Sequence and structure of the nucleolin promoter in rodents: characterization of a strikingly conserved CpG island

We report the isolation of the complete genes encoding nucleolin from rat and hamster. The DNA clones were obtained from partial genomic libraries by probing with a genomic DNA fragment containing the leader and promoter regions of the mouse nucleolin gene. We have determined the complete nucleotide sequence of the 5'-terminal region for the three rodent species. The sequenced regions extend over 1 kb downstream and upstream from the cap sites and include a conserved CpG island 1500 nucleotides (nt) long. The 5' end of the CpG island in each species has maintained a long alternating purine-pyrimidine sequence which could adopt a Z-DNA conformation. By sequence comparison, 42 blocks of homology are defined in the 5'-terminal region, of which 36 appear in the CpG island and contain numerous conserved CpG dinucleotides. Two blocks, 110 and 49 nt long, encompassing the cap sites and the region immediately upstream, respectively, present features characteristic of regulated genes: a possible TATA box (ATTA), two pyrimidine-rich nucleotide stretches and two inverted juxtaposed CCAAT-like boxes (GGTTGG). Furthermore, the adjacent upstream conserved region presents features characteristic of housekeeping genes: four G/C boxes, embedded in a high G + C-content sequence, among them one presenting a perfect consensus Sp 1-binding site (GCCCCGCCCC). Among unusual features, we report numerous large G + C-rich conserved sequences located in the first intron. One of these sequences contains two G/C boxes which border a sequence presenting a dyad symmetry (GCGCACGTGCTC). Our findings shed some light on the putative role of the CpG island. We show that CpG-rich sequence motifs are under strong selective pressure over the whole 5'-terminal region and are presumably involved in regulatory mechanisms.     

The cyclic nucleotide phosphodiesterase gene of Dictyostelium discoideum contains three promoters specific for growth, aggregation, and late development.

The cyclic nucleotide phosphodiesterase (phosphodiesterase) plays essential roles throughout the development of Dictyostelium discoideum. It is crucial to cellular aggregation and to postaggregation morphogenesis. The phosphodiesterase gene is transcribed into three mRNAs, containing the same coding sequence connected to different 5' untranslated sequences, that accumulate at different times during the life cycle. A 1.9-kilobase (kb) mRNA is specific for growth, a 2.4-kb mRNA is specific for aggregation, and a 2.2-kb mRNA is specific for late development and is only expressed in prestalk cells. Hybridization of RNA isolated from cells at various stages of development with different upstream regions of the gene indicated separate promoters for each of the three mRNAs. The existence of specific promoters was confirmed by fusing the three putative promoter regions to the chloramphenicol acetyltransferase reporter gene, and the analysis of transformants containing these constructs. The three promoters are scattered within a 4.1-kilobase pair (kbp) region upstream of the initiation codon. The late promoter is proximal to the coding sequence, the growth-specific promoter has an initiation site that is 1.9 kbp upstream of the ATG codon, and the aggregation-specific promoter has an initiation site 3 kbp upstream.     

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.     

S1 nuclease mapping of viral RNAs from a temperature-sensitive transformation mutant of murine sarcoma virus

The structures of murine sarcoma virus (MuSV) ts110 viral RNA and intracellular RNA present in MuSV ts110-infected cells (6m2 cells) have been examined by S1 nuclease analysis. A previous study involving heteroduplex analysis of MuSV ts110 viral RNAs hybridized to wild-type DNA revealed the presence of two MuSV ts110 RNAs, 4.0 and 3.5 kilobases (kb) in length, containing overlapping central deletions relative to wild-type MuSV 124 viral RNA (Junghans et al., J. Mol. Biol. 161:229-255, 1982). Here we show that the deletion (termed delta 1) in the 4.0-kb RNA has a 5' border located at about nucleotide 2409 (using the numbering system of Van Beveren et al., Cell 27:97-108, 1981), a position 63 bases upstream of the junction of the p30 and p10 coding sequences. The 3' border of the delta 1 deletion is found 1,473 bases downstream at approximately nucleotide 3883, 10 nucleotides downstream of the first mos gene initiation codon. In the 3.5-kb MuSV ts110 RNA, the 5' border of the deleted central region (termed delta 2) is located in a splice consensus donor site at approximately nucleotide 2017, 330 bases downstream from the junction of the p12 and p30 coding sequences, and extends about 1,915 bases in the downstream direction to nucleotide 3935, found in a splice consensus acceptor site about 55 nucleotides downstream of the first mos gene initiation codon and 30 bases upstream of the second initiation codon. No alteration of polyadenylate addition sites was observed in either MuSV ts110 RNA species, as compared with MuSV 349 RNA. The observation that the 5' and 3' borders of the deletion in the 3.5-kb RNA are within in-frame splice donor and acceptor sites suggests strongly that the 3.5-kb RNA is derived from the 4.0-kb RNA by a temperature-sensitive splice mechanism. Data presented here show unequivocally that formation of the 3.5-kb MuSV ts110 RNA from which the P85gag-mos polypeptide is translated is temperature sensitive. At 33 degrees C, with S1 analysis, the 3.5-kb RNA is found readily in 6m2 cells. Within 4 h of a shift to 39 degrees C, however, only trace amounts of this RNA can be found. Moreover, reshifting 6m2 cells to 33 degrees C permits the reappearance of the 3.5-kb RNA at its original level.     

Multiple mRNAs are generated from the chicken lysozyme gene

We have determined the DNA sequence of a 770 by Pst I fragment containing 450 nucleotides of the 5′ flanking region of the chicken lysozyme gene. S1-nuclease mapping was performed to localize the 5′ end of nuclear RNA containing lysozyme-specific sequences and of the mRNA. We present evidence that the 5′ noncoding region of the chicken lysozyme mRNA is heterogeneous in length. The 5′ termini of the different mRNAs map 29, 31 and 53 nucleotides upstream from their common initiation codon. The 5′ ends of lysozyme-specific nuclear RNAs map at positions similar to that of the mRNA. AT-rich regions and sequences similar to the E. coli RNA polymerase recognition sequence are found around 30 and 70 nucleotides upstream from each of these 5′ termini. The AT-rich regions differ, however, from the canonical Goldberg-Hogness box in that they do not contain the extremely conserved TATA sequence motif. Sequence comparison at the 5′ end of the lysozyme, conalbumin and ovalbumin genes reveals only one region of partial homology, 140 nucleotides upstream from the mRNA start sites.