Transcription termination occurs within a 1000 base pair region downstream from the poly(A) site of the mouse beta-globin (major) gene

Fine-structure analysis of the processing and polyadenylation region of the herpes simplex virus type 1 thymidine kinase gene by using linker scanning, internal deletion, and insertion mutations

Most eucaryotic mRNAs are polyadenylated. In higher eucaryotes, the sequence AATAAA is located 7 to 30 base pairs (bp) upstream from the site of processing and polyadenylation and is a critical part of the signal for processing and polyadenylation. Efficient cleavage and polyadenylation also require sequences downstream of polyadenylation sites. The herpes simplex virus type 1 thymidine kinase (tk) gene contains two copies of the AATAAA hexanucleotide and a GT box (18 of 19 consecutive residues are G or T) previously shown to be required for efficient processing and polyadenylation of tk mRNA (C. N. Cole and T. P. Stacy, Mol. Cell. Biol., 5:2104-2113). To define further the sequence requirements for efficient polyadenylation, we prepared linker scanning, internal deletion, and small insertion mutations in the polyadenylation region of the tk gene. These mutations were analyzed by S1 nuclease protection analysis of cytoplasmic RNA isolated from transfected Cos-1 monkey kidney cells. When the proximal AATAAA was deleted, no tk mRNA polyadenylated in the normal region was detected, whereas replacement of the second AATAAA with an XbaI linker had no effect on polyadenylation. When various portions of the GT box were replaced with linker, the amount of tk mRNA produced was reduced to 23 to 82% of the normal amount, but polyadenylation in the normal region was never abolished. Thus, no single portion of the GT box was absolutely required. In some cases, extended transcripts, polyadenylated at a cryptic site within pBR322, were detected. A spacing of 6 bp between AATAAA and the GT box was too short for efficient processing and polyadenylation. A spacing of 30 bp appeared to work almost as efficiently as did the wild-type spacing of 18 bp. Taken together, these results indicate that efficient polyadenylation requires both AATAAA and downstream GT-rich sequences. In addition, processing and polyadenylation are affected both qualitatively and quantitatively by sequences at polyadenylation sites and at more distant locations.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

A specific DNA sequence controls termination of transcription in the gastrin gene

We located and characterized a downstream transcriptional regulatory element in the human gastrin gene by transferring the gastrin gene 3' fragment, from which the polyadenylation signal sequence was deleted, into the shuttle vector pSCAT10 at a site located immediately downstream from the chloramphenicol acetyltransferase (CAT) gene and upstream from the simian virus 40 polyadenylation region. Study of CAT RNA derived from the hybrid plasmids, indicated regulation of transcription on the gastrin gene fragment. Analysis of deletion mutants generated from the 5' region of the fragment by CAT assay and by S1 nuclease mapping of mRNAs indicated the possible involvement of an oligothymidylate-rich sequence in transcription regulation. Mapping of gastrin gene RNA 3' ends to the 5' side proximal to the oligothymidylate-rich sequence clearly demonstrated that this sequence is a transcriptional terminator element. This unique sequence, interspersed with one or two adenines, which also functions in an orientation-dependent manner, is located 192 nucleotides downstream from the gastrin gene polyadenylation site, and serves as a transcriptional termination signal.

Fine-structure analysis of the processing and polyadenylation region of the herpes simplex virus type 1 thymidine kinase gene by using linker scanning, internal deletion, and insertion mutations

Most eucaryotic mRNAs are polyadenylated. In higher eucaryotes, the sequence AATAAA is located 7 to 30 base pairs (bp) upstream from the site of processing and polyadenylation and is a critical part of the signal for processing and polyadenylation. Efficient cleavage and polyadenylation also require sequences downstream of polyadenylation sites. The herpes simplex virus type 1 thymidine kinase (tk) gene contains two copies of the AATAAA hexanucleotide and a GT box (18 of 19 consecutive residues are G or T) previously shown to be required for efficient processing and polyadenylation of tk mRNA (C. N. Cole and T. P. Stacy, Mol. Cell. Biol., 5:2104-2113). To define further the sequence requirements for efficient polyadenylation, we prepared linker scanning, internal deletion, and small insertion mutations in the polyadenylation region of the tk gene. These mutations were analyzed by S1 nuclease protection analysis of cytoplasmic RNA isolated from transfected Cos-1 monkey kidney cells. When the proximal AATAAA was deleted, no tk mRNA polyadenylated in the normal region was detected, whereas replacement of the second AATAAA with an XbaI linker had no effect on polyadenylation. When various portions of the GT box were replaced with linker, the amount of tk mRNA produced was reduced to 23 to 82% of the normal amount, but polyadenylation in the normal region was never abolished. Thus, no single portion of the GT box was absolutely required. In some cases, extended transcripts, polyadenylated at a cryptic site within pBR322, were detected. A spacing of 6 bp between AATAAA and the GT box was too short for efficient processing and polyadenylation. A spacing of 30 bp appeared to work almost as efficiently as did the wild-type spacing of 18 bp. Taken together, these results indicate that efficient polyadenylation requires both AATAAA and downstream GT-rich sequences. In addition, processing and polyadenylation are affected both qualitatively and quantitatively by sequences at polyadenylation sites and at more distant locations.

Tripartite sequences within and 3' to the sea urchin H2A histone gene display properties associated with a transcriptional termination process

We have defined a DNA sequence that behaves as an RNA polymerase II termination signal by using the human HeLa cell transient expression system. Surprisingly, this sequence is tripartite, including part of the coding region of the sea urchin H2A histone gene together with two separate sequences in the 3' flanking region of the gene. We demonstrate that this signal functions both in its normal gene environment and also when placed within the human alpha-globin gene. However, we have failed to detect a discrete 3' terminus. Rather, our data indicate the presence of an extremely heterogeneous series of nonpolyadenylated RNAs. These heterogeneous nonpolyadenylated RNAs are stable when transcribed from the intact histone gene but are highly unstable within the human alpha-globin gene. This provides evidence for the role of poly(A) in the stability of mRNA.

Identification of sequences in the herpes simplex virus thymidine kinase gene required for efficient processing and polyadenylation

The herpes simplex virus (HSV) type 1 thymidine kinase gene (tk) was resected from its 3' end with BAL 31 exonuclease. Two sets of plasmids were isolated that lacked information distal to the two copies of the hexanucleotide 5'-AATAAA-3' located at the 3' end of the HSV tk gene. The presence of a simian virus 40 origin of DNA replication in each plasmid facilitated analysis of patterns of transcription in transfected Cos-1 monkey cells. Transcription analyses were performed with an S1 nuclease protection assay. Efficient processing and polyadenylation at the normal site still occurred when all sequences more than 44 or 46 base pairs (bp) downstream from the first AATAAA were removed (pTK311R/SV010 and pTK209R/SV010). Removal of an additional 7 bp (pTK312R/SV010) decreased the amount of tk mRNA processed at that normal site, and tk mRNA polyadenylated at a cryptic site within pBR322 sequences began to appear. The normal processing and polyadenylation site was not used at all when an additional 12 bp was removed (pTK314R/SV010); the small amount of tk mRNA produced was processed and polyadenylated at the cryptic pBR322 site. The region of the tk gene critical for efficient processing and polyadenylation of tk mRNA is located 20 to 38 bp downstream from the first AATAAA, distal to the polyadenylation site, and as RNA can form a stem-loop structure containing AAUAAA. Similar G + T-rich elements were located in DNA fragments which substitute efficiently for the HSV tk processing and polyadenylation signal and were not found in AATAAA-containing DNA fragments which substitute inefficiently for the HSV tk signal.

Molecular localization, developmental expression and nucleotide sequence of the alpha-methyldopa hypersensitive gene of Drosophila

The region surrounding the dopa decarboxylase gene of Drosophila contains a cluster of functionally related genes, many of which affect cuticle development and/or catecholamine metabolism. In this report we describe the molecular mapping and sequencing of a full-length cDNA copy of a transcript that maps to the alpha-methyldopa hypersensitive region. Developmental RNA blots show stage-specific patterns of transcription and multiple RNA transcripts. A 2-kb transcript is most abundant at about 12 hr of embryogenesis, and lower levels are detected throughout most of embryogenesis. Lower levels of this transcript are also detected in adults. Smaller stage-specific transcripts are detected in late third-instar larvae. This pattern of transcription is consistent with the known lethal phases and phenotypes of the alpha-methyldopa hypersensitive gene (amd). Based on map position, pattern of transcription, homology with dopa decarboxylase and association with altered DNA in mutants, we conclude that this transcript represents the amd gene.

Evidence for evolutionary duplication of genes in the dopa decarboxylase region of Drosophila

The region surrounding the dopa decarboxylase gene (Ddc) of Drosophila contains a cluster of genes, many of which appear to be functionally related by virtue of their effects on cuticle development and/or catecholamine metabolism. In this report we describe evidence that the Ddc gene and the closely linked alpha-methyldopa hypersensitive (amd) gene share extensive sequence homology and are the products of a gene duplication event. The two genes are transcribed convergently and are separated by 2.4 kb. A gene located between Ddc and amd expresses a 2.0-kb mRNA and appears to partially overlap the Ddc gene. The organization of these transcripts implies a complex series of events giving rise to the present pattern. The patterns of expression of these genes do not support a model of coordinate regulation, but are more consistent with a pattern of duplication and divergence to various related metabolic subspecialties. These data provide the first evidence for structural relationships among genes in the 37C cluster.

ATTAAA as well as downstream sequences are required for RNA 3'-end formation in the E3 complex transcription unit of adenovirus

We mapped the location of the E3A RNA 3' end site in the E3 transcription unit of adenovirus 2. The procedure used was nuclease-gel analysis with 32P-labeled RNA probes. The poly(A) addition sites were microheterogeneous and were located approximately 17 to 29 nucleotides downstream from an ATTAAA sequence. To identify the sequences that make up the E3A RNA 3' end signal, we constructed five viable virus mutants with deletions in or near the E3A RNA 3' end site. The mutants were analyzed for E3A RNA 3' end formation in vivo. No effect was observed from a 47-base-pair (bp) deletion (dl716) or a 72-bp deletion (dl714) located 22 and 19 nucleotides, respectively, upstream of the ATTAAA. In contrast, E3A RNA 3' end formation was abolished by a 554-bp deletion (dl708) that removes both the ATTAAA and the poly(A) addition sites, a 124-bp deletion (dl713) that removes the ATTAAA but leaves the poly(A) addition sites, and a 65-bp deletion (dl719) that leaves the ATTAAA but removes the poly(A) addition sites. These results indicate that the ATTAAA, as well as downstream sequences, including the poly(A) addition sites, are required for E3A RNA 3' end formation.

Transcription boundaries of U1 small nuclear RNA

Transcription-proximal stages of U1 small nuclear RNA biosynthesis were studied by 32P labeling of nascent chains in isolated HeLa cell nuclei. Labeled RNA was hybridized to nitrocellulose-immobilized, single-stranded M13 DNA clones corresponding to regions within or flanking a human U1 RNA gene. Transcription of U1 RNA was inhibited by greater than 95% by alpha-amanitin at 1 microgram/ml, consistent with previous evidence that it is synthesized by RNA polymerase II. No hybridization to DNA immediately adjacent to the 5' end of mature U1 RNA (-6 to -105 nucleotides) was detected, indicating that, like all studied polymerase II initiation, transcription of U1 RNA starts at or very near the cap site. However, in contrast to previously described transcription units for mRNA, in which equimolar transcription occurs for hundreds or thousands of nucleotides beyond the mature 3' end of the mRNA, labeled U1 RNA hybridization dropped off sharply within a very short region (approximately 60 nucleotides) immediately downstream from the 3' end of mature U1 RNA. Also in contrast to pre-mRNA, which is assembled into ribonucleoprotein (RNP) particles while still nascent RNA chains, the U1 RNA transcribed in isolated nuclei did not form RNP complexes by the criterion of reaction with a monoclonal antibody for the small nuclear RNP Sm proteins. This suggests that, unlike pre-mRNA-RNP particle formation, U1 small nuclear RNP assembly does not occur until after the completion of transcription. These results show that, despite their common synthesis by RNA polymerase II, mRNA and U1 small nuclear RNA differ markedly both in their extents of 3' processing and their temporal patterns of RNP assembly.

Cell-specific expression of secreted versus membrane forms of immunoglobulin gamma 2b mRNA involves selective use of alternate polyadenylation sites

Immunoglobulin heavy chain genes encode at least two forms of mRNA, secretory- and membrane-specific. In less mature B cells and tumors arising from them, lymphomas, the membrane form of the protein and mRNA are in high abundance, while in more mature stages, plasma cells, and myeloma tumor cells, the secreted forms of protein and mRNA predominate. In myeloma cells producing approximately 8:1 ratios of secretory- to membrane-encoding forms of gamma-heavy chain mRNA, we observed equimolar transcription of the secretory- and membrane-encoding exons of the gene. In isolated nuclei from 4T001 (gamma 2b) and K23 (gamma 2a) myeloma cells, the secretory-encoding mRNA polyadenylation site was used at least three times as often as the membrane-encoding mRNA polyadenylation site. In the A20 (gamma 2a) lymphoma, which produces equal amounts of mature secretory- and membrane-encoding heavy chain mRNAs, results of experiments with isolated nuclei showed that the membrane mRNA polyadenylation site was used about two times as often as the secretory mRNA polyadenylation site. Selective use of alternate polyadenylation and cleavage sites, therefore, can modulate the production of the two mRNAs from a single gene during B cell differentiation.

Transcriptional interference and termination between duplicated alpha-globin gene constructs suggests a novel mechanism for gene regulation

The interesting possibility that transcriptional interference can occur between eukaryotic genes was raised by studies on the avian leukosis retrovirus (ALV) which showed that deletion of the promoter in the 5' long terminal repeat (LTR) activates the 3' LTR promoter, linked to a downstream gene. These observations provide a molecular explanation for the fact that insertional oncogenesis by the ALV promoter is invariably associated with either a rearranged or deleted 5' LTR sequence. This letter extends these findings to chromosomal RNA polymerase II genes by studying transcriptional interference between duplicated alpha-globin gene constructions. I demonstrate that transcriptional interference causes substantial inhibition of the downstream alpha gene by transcription of the upstream alpha gene. Furthermore, this inhibition is alleviated by placing transcriptional termination signals between the two alpha genes. Because many eukaryotic genes may be arranged in tandem on a chromosome, these observations suggest that transcriptional termination is an important mechanism for preventing interference between adjacent genes. The selective use of termination signals may provide a novel way of regulating the activity of eukaryotic genes.

Expression of three mRNA species from a single rat aldolase A gene, differing in their 5' non-coding regions

The complete nucleotide sequence of the rat aldolase A isozyme gene, including the 5' and 3' flanking sequences, was determined. The gene comprises ten exons, spans 4827 base-pairs and occurs in a single copy per haploid rat genome. The genomic DNA sequence was compared with those of three species of rat aldolase A mRNA (mRNAs I, II and III) that have been found to differ from each other only in the 5' non-coding region and to be expressed tissue-specifically. It revealed that the first exon (exon M1) encodes the 5' non-coding sequence of mRNA I, while the second exon (exon AH1) encodes those of mRNAs II and III and the following eight exons (exons 2 to 9) are shared commonly by all the mRNA species. These results allowed us to conclude that mRNA I and mRNAs II, III were generated from a single aldolase A gene by alternative usage of exon M1 or exon AH1 in addition to exons 2 to 9. S1 nuclease mapping of the 5' ends of their precursor RNAs suggested that these three mRNA species were transcribed from three different initiation sites on the single gene.

Sequences upstream from the mouse c-mos oncogene may function as a transcription termination signal

A region upstream from the mouse c-mos proto-oncogene, termed upstream mouse sequence (UMS), prevents expression of mos transforming activity. Previous studies suggested that the UMS prevented transcription readthrough. In this study, we constructed a recombinant DNA clone, pHTS3MS, with the UMS inserted downstream from both the mos gene and a truncated long terminal repeat containing only the U3 enhancer region. In this position UMS did not inhibit mos transforming activity. We examined cells transformed by pHTS3MS for RNA expression. S1 nuclease analysis showed that the UMS provides two polyadenylation signals to mos-containing RNA and nuclear run-on transcription showed that the primary transcripts terminate in UMS. In addition, using portions of the UMS, we found that a 360-bp fragment containing the UMS polyadenylation signals and sites inserted between the herpes simplex virus type 1 (HSV-1) thymidine kinase gene (tk) and its promoter inhibits tk transforming activity by 99% and prevents detectable expression of this construct in transient expression assays. Thus, the UMS must contain signals for polyadenylation and appears to function as a transcription terminator.

Mutations downstream of the polyadenylation site of a Xenopus beta-globin mRNA affect the position but not the efficiency of 3' processing

In order to identify nucleotide sequences required for efficient and accurate polyadenylation of mRNA precursors, we have constructed a series of mutations in the X. laevis beta 1-globin gene and analyzed transcripts produced upon microinjection into Xenopus oocytes. Small deletion and linker replacement mutations, which lie in the region from 8 to 39 bp downstream of the AATAAA sequence and which effectively remove previously identified second components of the polyadenylation signal, do not greatly reduce the efficiency of processing, but in some cases alter the precise site of cleavage. We conclude that sequences downstream of the polyadenylation site affect the position of 3' RNA processing, but have minimal effects on its efficiency.

Transcription unit mapping in adenovirus: regions of termination

Using a series of single-stranded clones of adenovirus DNA, we determined the extent of RNA polymerase II transit early in infection for two rightward-reading transcription units. RNA synthesis beginning at the major late promoter (16.5 on the genomic map) continued until approximately 65 to 70 map units so that differential choices of mRNAs within that region were not based primarily on transcriptional decisions but rather on posttranscriptional decisions. Transcription from the major late promoter beginning at 16.5 map units, however, did greatly decrease before approximately 75 map units, ensuring that no mRNAs were formed with sequences beyond approximately 75 map units. Early transcription from E3 then began just past 75 map units (at a higher rate than transcription from the major late promoter); E3 transcripts terminated at least 2 kilobases downstream from a second and final poly(A) site in this transcription unit. The effectiveness of termination in E3 was greater than 95 to 99%.

Duplication of functional polyadenylation signals in polyomavirus DNA does not alter efficiency of polyadenylation or transcription termination

We constructed viable insertion mutants of polyomavirus that contain duplications of the nucleotide sequences surrounding the polyadenylation sites for both E- and L-strand RNAs. Our results showed that formation of poly(A)+ 3'termini of L-strand mRNAs requires sequence elements located between 12 and 87 nucleotides downstream of AAUAAA. No more than 19 nucleotides upstream and 44 nucleotides downstream of AAUAAA are required for polyadenylation of E-strand mRNAs. Our results and those of others suggest that there are three distinct sequence elements required for mRNA 3' end formation: AAUAAA and two downstream elements. An insertion mutant containing two adjacent functional polyadenylation signals produced E-strand and L-strand mRNAs with 3' ends at both sites. However, the overall level of polyadenylation of L-strand RNAs was not increased over the low (10 to 25%) levels seen with wild-type virus. Neither was the efficiency of termination of L-strand transcription increased in mutant virus-infected cells. We conclude that factors required for both polyadenylation and transcription termination are limiting in polyomavirus-infected mouse cells.

Structural features of the murine dihydrofolate reductase transcription termination region: identification of a conserved DNA sequence element

Structural features of the transcription termination region for the mouse dihydrofolate reductase gene have been determined and compared with those of several other known termination regions for protein coding genes. A common feature identified among these termination regions was the presence of a 20 bp consensus DNA sequence element (ATCAGAATATAGGAAAGTAGCAAT). The results imply that the 20 bp consensus DNA sequence element is important for signaling RNA polymerase II transcription termination at least in the several vertebrate species investigated. Furthermore, the results suggest that for the dhfr gene and possibly for other genes in mice as well, the potential termination consensus sequence can exist as part of a long interspersed repetitive DNA element.

A specific DNA sequence controls termination of transcription in the gastrin gene

We located and characterized a downstream transcriptional regulatory element in the human gastrin gene by transferring the gastrin gene 3' fragment, from which the polyadenylation signal sequence was deleted, into the shuttle vector pSCAT10 at a site located immediately downstream from the chloramphenicol acetyltransferase (CAT) gene and upstream from the simian virus 40 polyadenylation region. Study of CAT RNA derived from the hybrid plasmids, indicated regulation of transcription on the gastrin gene fragment. Analysis of deletion mutants generated from the 5' region of the fragment by CAT assay and by S1 nuclease mapping of mRNAs indicated the possible involvement of an oligothymidylate-rich sequence in transcription regulation. Mapping of gastrin gene RNA 3' ends to the 5' side proximal to the oligothymidylate-rich sequence clearly demonstrated that this sequence is a transcriptional terminator element. This unique sequence, interspersed with one or two adenines, which also functions in an orientation-dependent manner, is located 192 nucleotides downstream from the gastrin gene polyadenylation site, and serves as a transcriptional termination signal.

mRNA transcripts of several plant genes are polyadenylated at multiple sites in vivo

We have analyzed the polyadenylation sites for the small subunit of ribulose bisphosphate carboxylase and chlorophyll a/b binding protein genes of Petunia (Mitchell) and the bronze gene of Zea mays. Sequence analysis of multiple cDNA clones revealed that polyadenylation of the transcripts occurred at either 2 or 3 sites for all three groups of genes. In the examples where 3 polyadenylation sites were detected, the middle site was the one predominantly used. Putative polyadenylation signals preceding the poly A tails diverged significantly from the animal consensus sequence AATAAA. In all the genes examined the first A residue in the poly A tail of the cDNA clones corresponded to an A residue in the homologous genomic sequence.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

Transcription of mouse rDNA terminates downstream of the 3' end of 28S RNA and involves interaction of factors with repeated sequences in the 3' spacer

RNA polymerase I terminates transcription of mouse rDNA 565 bp downstream of the 3' end of mature 28S rRNA. This specific termination event can be duplicated in a nuclear extract system. RNA molecules with authentic 3' ends are transcribed from ribosomal minigene constructs provided the templates retain a minimal length of downstream spacer sequences. The nucleotide sequence of the region of transcription termination contains a set of repetitive structural elements consisting of 18 bp conserved nucleotides surrounded by stretches of pyrimidines. Termination in vivo occurs within the first element. This site is preferentially used in vitro at low template concentrations. At increasing DNA concentrations a termination site within the second repetitive element is used. Competition experiments with defined 3'-terminal fragments suggest that transcription termination by RNA polymerase I requires interaction of some factor (or factors) with the repetitive structural elements in the 3' nontranscribed spacer.

ATTAAA as well as downstream sequences are required for RNA 3'-end formation in the E3 complex transcription unit of adenovirus

We mapped the location of the E3A RNA 3' end site in the E3 transcription unit of adenovirus 2. The procedure used was nuclease-gel analysis with 32P-labeled RNA probes. The poly(A) addition sites were microheterogeneous and were located approximately 17 to 29 nucleotides downstream from an ATTAAA sequence. To identify the sequences that make up the E3A RNA 3' end signal, we constructed five viable virus mutants with deletions in or near the E3A RNA 3' end site. The mutants were analyzed for E3A RNA 3' end formation in vivo. No effect was observed from a 47-base-pair (bp) deletion (dl716) or a 72-bp deletion (dl714) located 22 and 19 nucleotides, respectively, upstream of the ATTAAA. In contrast, E3A RNA 3' end formation was abolished by a 554-bp deletion (dl708) that removes both the ATTAAA and the poly(A) addition sites, a 124-bp deletion (dl713) that removes the ATTAAA but leaves the poly(A) addition sites, and a 65-bp deletion (dl719) that leaves the ATTAAA but removes the poly(A) addition sites. These results indicate that the ATTAAA, as well as downstream sequences, including the poly(A) addition sites, are required for E3A RNA 3' end formation.

Cell-specific expression of secreted versus membrane forms of immunoglobulin gamma 2b mRNA involves selective use of alternate polyadenylation sites

Immunoglobulin heavy chain genes encode at least two forms of mRNA, secretory- and membrane-specific. In less mature B cells and tumors arising from them, lymphomas, the membrane form of the protein and mRNA are in high abundance, while in more mature stages, plasma cells, and myeloma tumor cells, the secreted forms of protein and mRNA predominate. In myeloma cells producing approximately 8:1 ratios of secretory- to membrane-encoding forms of gamma-heavy chain mRNA, we observed equimolar transcription of the secretory- and membrane-encoding exons of the gene. In isolated nuclei from 4T001 (gamma 2b) and K23 (gamma 2a) myeloma cells, the secretory-encoding mRNA polyadenylation site was used at least three times as often as the membrane-encoding mRNA polyadenylation site. In the A20 (gamma 2a) lymphoma, which produces equal amounts of mature secretory- and membrane-encoding heavy chain mRNAs, results of experiments with isolated nuclei showed that the membrane mRNA polyadenylation site was used about two times as often as the secretory mRNA polyadenylation site. Selective use of alternate polyadenylation and cleavage sites, therefore, can modulate the production of the two mRNAs from a single gene during B cell differentiation.

Termination of a transcription unit comprising highly expressed genes in the archaebacterium Methanococcus voltae

The 3'termini of transcripts originating from genes organized in a highly expressed transcription unit were analyzed in the archaebacterium Methanococcus voltae. The putative termination signals were found in an AT-rich intergenic region following the 3'-terminal gene. The two detected signals both contain oligo(T) sequences. A possible stem/loop structure immediately precedes one of the oligo(T) tracts. This secondary structure is considered to have an additional function in stabilizing the transcripts.

Transcription boundaries of U1 small nuclear RNA

Transcription-proximal stages of U1 small nuclear RNA biosynthesis were studied by 32P labeling of nascent chains in isolated HeLa cell nuclei. Labeled RNA was hybridized to nitrocellulose-immobilized, single-stranded M13 DNA clones corresponding to regions within or flanking a human U1 RNA gene. Transcription of U1 RNA was inhibited by greater than 95% by alpha-amanitin at 1 microgram/ml, consistent with previous evidence that it is synthesized by RNA polymerase II. No hybridization to DNA immediately adjacent to the 5' end of mature U1 RNA (-6 to -105 nucleotides) was detected, indicating that, like all studied polymerase II initiation, transcription of U1 RNA starts at or very near the cap site. However, in contrast to previously described transcription units for mRNA, in which equimolar transcription occurs for hundreds or thousands of nucleotides beyond the mature 3' end of the mRNA, labeled U1 RNA hybridization dropped off sharply within a very short region (approximately 60 nucleotides) immediately downstream from the 3' end of mature U1 RNA. Also in contrast to pre-mRNA, which is assembled into ribonucleoprotein (RNP) particles while still nascent RNA chains, the U1 RNA transcribed in isolated nuclei did not form RNP complexes by the criterion of reaction with a monoclonal antibody for the small nuclear RNP Sm proteins. This suggests that, unlike pre-mRNA-RNP particle formation, U1 small nuclear RNP assembly does not occur until after the completion of transcription. These results show that, despite their common synthesis by RNA polymerase II, mRNA and U1 small nuclear RNA differ markedly both in their extents of 3' processing and their temporal patterns of RNP assembly.

Identification of sequences in the herpes simplex virus thymidine kinase gene required for efficient processing and polyadenylation

The herpes simplex virus (HSV) type 1 thymidine kinase gene (tk) was resected from its 3' end with BAL 31 exonuclease. Two sets of plasmids were isolated that lacked information distal to the two copies of the hexanucleotide 5'-AATAAA-3' located at the 3' end of the HSV tk gene. The presence of a simian virus 40 origin of DNA replication in each plasmid facilitated analysis of patterns of transcription in transfected Cos-1 monkey cells. Transcription analyses were performed with an S1 nuclease protection assay. Efficient processing and polyadenylation at the normal site still occurred when all sequences more than 44 or 46 base pairs (bp) downstream from the first AATAAA were removed (pTK311R/SV010 and pTK209R/SV010). Removal of an additional 7 bp (pTK312R/SV010) decreased the amount of tk mRNA processed at that normal site, and tk mRNA polyadenylated at a cryptic site within pBR322 sequences began to appear. The normal processing and polyadenylation site was not used at all when an additional 12 bp was removed (pTK314R/SV010); the small amount of tk mRNA produced was processed and polyadenylated at the cryptic pBR322 site. The region of the tk gene critical for efficient processing and polyadenylation of tk mRNA is located 20 to 38 bp downstream from the first AATAAA, distal to the polyadenylation site, and as RNA can form a stem-loop structure containing AAUAAA. Similar G + T-rich elements were located in DNA fragments which substitute efficiently for the HSV tk processing and polyadenylation signal and were not found in AATAAA-containing DNA fragments which substitute inefficiently for the HSV tk signal.

Transcription termination within the E1A gene of adenovirus induced by insertion of the mouse beta-major globin terminator element

In induced erythroleukemia cells, transcription of the beta-globin gene terminates in a region 600-1500 nucleotides downstream of the poly(A) site. To determine whether this region of the mouse DNA functions to terminate transcription when moved to another genomic site, portions of the putative termination region have been inserted into the E1A transcription unit of the adenovirus (type 5) chromosome. Analysis of RNA labeled either in isolated nuclei or in whole cells early after infection with reconstructed viruses indicated that transcription is terminated if the inserted DNA is oriented in the same direction as in the beta-globin transcription unit and contains the globin poly(A) site plus an additional 1395 nucleotides downstream. In addition to halting transcription within the E1A unit, the insertion of the terminator region had a negative cis effect on the E1B transcription unit, which normally initiates 363 bp downstream of the site of the globin insert. The E1B transcription unit was the only early gene affected, and complementation of the terminator virus with a wild-type E1A gene did not restore transcription of the E1B gene.