Transcription units of adenovirus type 2. Termination of transcription beyond the poly(A) addition site in early regions 2 and 4

A history of poly A sequences: from formation to factors to function

Biological polyadenylation, first recognized as an enzymatic activity, remained an orphan enzyme until poly A sequences were found on the 3' ends of eukarvotic mRNAs. Their presence in bacteria viruses and later in archeae (ref. 338) established their universality. The lack of compelling evidence for a specific function limited attention to their cellular formation. Eventually the newer techniques of molecular biology and development of accurate nuclear processing extracts showed 3' end formation to be a two-step process. Pre-mRNA was first cleaved endonucleolytically at a specific site that was followed by sequential addition of AMPs from ATP to the 3' hydroxyl group at the end of mRNA. The site of cleavage was specified by a conserved hexanucleotide, AAUAAA, from 10 to 30 nt upstream of this 3' end. Extensive purification of these two activities showed that more than 10 polypeptides were needed for mRNA 3' end formation. Most of these were in complexes involved in the cleavage step. Two of the best characterized are CstF and CPSF, while two other remain partially purified but essential. Oddly, the specific proteins involved in phosphodiester bond hydrolysis have yet to be identified. The polyadenylation step occurs within the complex of poly A polymerase and poly A-binding protein, PABII, that controls poly A length. That the cleavage complex, CPSF, is also required for this step attests to a tight coupling of the two steps of 3' and formation. The reaction reconstituted from these RNA-free purified factors correctly processes pre-mRNAs. Meaningful analysis of the role of poly A in mRNA metabolism or function was possible once quantities of these proteins most often over-expressed from cDNA clones became available. The large number needed for two simple reactions of an endonuclease, a polymerase and a sequence recognition factor, pointed to 3' end formation as a regulated process. Polyadenylation itself had appeared to require regulation in cases where two poly A sites were alternatively processed to produce mRNA coding for two different proteins. The 64-KDa subunit of CstF is now known to be a regulator of poly A site choice between two sites in the immunoglobulin heavy chain of B cells. In resting cells the site used favors the mRNA for a membrane-bound protein. Upon differentiation to plasma cells, an upstream site is used the produce a secreted form of the heavy chain. Poly A site choice in the calcitonin pre-mRNA involves splicing factors at a pseudo splice site in an intron downstream of the active poly site that interacts with cleavage factors for most tissues. The molecular basis for choice of the alternate site in neuronal tissue is unknown. Proteins needed for mRNA 3' end formation also participate in other RNA-processing reactions: cleavage factors bind to the C-terminal domain of RNA polymerase during transcription; splicing of 3' terminal exons is stimulated port of by cleavage factors that bind to splicing factors at 3' splice sites. nuclear ex mRNAs is linked to cleavage factors and requires the poly A II-binding protein. Most striking is the long-sought evidence for a role for poly A in translation in yeast where it provides the surface on which the poly A-binding protein assembles the factors needed for the initiation of translation. This adaptability of eukaryotic cells to use a sequence of low information content extends to bacteria where poly A serves as a site for assembly of an mRNA degradation complex in E. coli. Vaccinia virus creates mRNA poly A tails by a streamlined mechanism independent of cleavage that requires only two proteins that recognize unique poly A signals. Thus, in spite of 40 years of study of poly A sequences, this growing multiplicity of uses and even mechanisms of formation seem destined to continue.

Transcription of adenovirus type 2 genes in a cell-free system: apparent heterogeneity of initiation at some promoters

We examined the transcription of a variety of adenovirus type 2 genes in a cell-free system containing purified ribonucleic acid polymerase II and a crude extract from cultured human cells. The early EIA, EIB, EIII, and EIV genes and the intermediate polypeptide IX gene, all of which contain a recognizable TATAA sequence upstream from the cap site, were actively transcribed in vitro, albeit with apparently different efficiencies, whereas the early EII (map position 74.9) and IVa2 genes, both of which lack a TATAA sequence, were not actively transcribed. A reverse transcriptase-primer extension analysis showed that the 5' ends of the in vitro transcripts were identical to those of the corresponding in vivo ribonucleic acids and that, in those instances where initiation was heterogeneous in vivo, a similar kind of heterogeneity was observed in the cell-free system. Transcription of the polypeptide IX gene indicated that this transcript was not terminated at, or processed to, the polyadenylic acid addition site in vitro. We also failed to observe, using the in vitro system, any indication of transcriptional regulation based on the use of adenovirus type 2-infected cell extracts.

Adenovirus E1A proteins can dissociate heteromeric complexes involving the E2F transcription factor: a novel mechanism for E1A trans-activation

Adenovirus infection activates the E2F transcription factor, in part through the formation of a heteromeric protein complex involving a 19 kd E4 gene product that then allows cooperative and stable promoter binding. We now find that cellular factors are complexed to E2F in extracts of several uninfected cell lines. E1A proteins can dissociate these complexes, releasing free E2F. This activity of E1A is independent of conserved domain 3 but is dependent on conserved domain 2 sequence. The E1A-mediated dissociation of the complexes allows the E4 protein to interact with E2F, generating a stable DNA-protein complex with the E2 promoter and a stimulation of transcription. These experiments demonstrate a function for E1A in mediating a dissociation of transcription factor complexes, allowing new interactions to form and thus changing the transcriptional specificity.

DNA sequences downstream of the adenovirus type 2 fiber polyadenylation site contain transcription termination signals

The major late transcription unit of adenovirus type 2 (Ad2) terminates in a region near the end of the linear DNA genome at map units 98.2 to 100. Specific 3' ends mapping in the transcription termination region were detected in nuclear but not cytoplasmic RNA isolated at 16 to 18 h postinfection. Using S1 nuclease protection analysis, a major nuclear RNA species with a 3' terminus at map unit 98.9 was detected. With the use of recombinant expression vectors and run-on transcription in isolated nuclei, we demonstrated that the Ad2 sequences from map units 97.1 to 100, inserted into either the 5' or 3' untranslated sequences of the chloramphenicol acetyltransferase gene (cat), terminated transcription in transfected cells. Termination occurred only when the 97.1- to 100-map-unit sequence was in the same direction of transcription as the major late transcript and was not observed with Ad2 sequences upstream of map unit 97.1.

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.

Molecular analysis of the locus elav in Drosophila melanogaster: a gene whose embryonic expression is neural specific

The embryonic lethal abnormal visual system (elav) locus in Drosophila melanogaster, a vital gene mapping within the 1B5-1B9 region of the X-chromosome has been cloned and analysed. Previous developmental analyses have shown that in addition to the embryonic requirement there is a post-embryonic requirement for elav function in the cells of the visual system. A DNA segment containing elav+ function was defined through germ line transformation experiments. This region encodes three embryonic poly(A)+ RNAs and two adult transcripts which are preferentially expressed in the head. In situ hybridization experiments clearly demonstrate that the embryonic expression of elav is restricted to the nervous system.

Transcription terminator-like element within a Saccharomyces cerevisiae promoter region

We analyzed a cloned fragment of the yeast URA3 promoter region that contains a sequence of DNA capable of functioning as a highly efficient transcription terminator. BAL 31 deletions have shown the signal for the transcription termination activity is less than or equal to 110 base pairs and resides between bases 45 and 155 upstream of the URA3 primary ATG codon at base 227. In our in vivo assay system, the DNA fragment is able to terminate transcripts very efficiently in either orientation. The terminated transcripts bind to oligodeoxythymidylate cellulose columns and promote the synthesis of full-length cDNAs, suggesting that the transcripts are polyadenylated. The 110-base-pair region contains no sequence resembling terminator consensus sequences described by Zaret and Sherman (K.S. Zaret and F. Sherman, Cell, 28:563-573, 1982) or Henikoff and Cohen (S. Henikoff and E.H. Cohen, Mol. Cell. Biol., 4:1515-1520, 1984). We discuss the possible physiological relevance of this sequence to bona fide termination of transcription and to URA3 regulation in Saccharomyces cerevisiae.

Transcriptional and post-transcriptional regulation of c-myc expression during the differentiation of murine erythroleukemia Friend cells

c-myc RNA rapidly decreases to barely detectable levels in Friend erythroleukemia cells induced to differentiate upon the addition of dimethylsulfoxide. We show here that c-myc gene is down-regulated both at the transcriptional level presumably by a block in the elongation of primary transcripts and at the post-transcriptional level by an increase in the degradation of its mRNA.

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.

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.

Differential processing of RNA transcribed from the single-copy Drosophila myosin heavy chain gene produces four mRNAs that encode two polypeptides

We report the sequence of genomic DNA at the 3' end of the single-copy Drosophila myosin heavy chain (MHC) gene and the structure and sequence at the 3' end of four MHC mRNAs. Two mRNAs, 7.2-kilobases (kb) and 8.0 kb in length, are expressed in all stages of development in which detectable levels of muscle-specific mRNAs accumulate. These mRNAs differ by alternate choice of two poly(A) sites within the same exon. Sequence information predicts that these two mRNAs can encode one MHC polypeptide. Two additional MHC mRNAs, 8.0 kb and 8.6 kb in length, are expressed only in late pupal and adult stages of development. These two stage-specific MHC mRNAs use the same poly(A) sites as the MHC mRNAs described above but have a different splicing pattern and thus include an additional exon. Sequence information predicts that these two stage-specific MHC mRNAs encode a second MHC polypeptide with a different COOH terminus.

Transcription terminator-like element within a Saccharomyces cerevisiae promoter region

We analyzed a cloned fragment of the yeast URA3 promoter region that contains a sequence of DNA capable of functioning as a highly efficient transcription terminator. BAL 31 deletions have shown the signal for the transcription termination activity is less than or equal to 110 base pairs and resides between bases 45 and 155 upstream of the URA3 primary ATG codon at base 227. In our in vivo assay system, the DNA fragment is able to terminate transcripts very efficiently in either orientation. The terminated transcripts bind to oligodeoxythymidylate cellulose columns and promote the synthesis of full-length cDNAs, suggesting that the transcripts are polyadenylated. The 110-base-pair region contains no sequence resembling terminator consensus sequences described by Zaret and Sherman (K.S. Zaret and F. Sherman, Cell, 28:563-573, 1982) or Henikoff and Cohen (S. Henikoff and E.H. Cohen, Mol. Cell. Biol., 4:1515-1520, 1984). We discuss the possible physiological relevance of this sequence to bona fide termination of transcription and to URA3 regulation in Saccharomyces cerevisiae.

Control of cellular and viral transcription during adenovirus infection

The control of transcription initiation is an issue central to the regulation of eukaryotic gene expression, and as such, the elucidation of the mechanisms of control of initiation frequency is critical. The study of adenovirus transcription control has provided insights into these mechanisms. Transcription of the early viral genes is activated by the product of the viral E1A gene. Possibly of greater importance is the fact that this activation does not appear to be "viral specific". Rather, the E1A protein effects a general activation of transcription in the cell, resulting in the stimulation of transcription of at least one cellular gene in addition to the viral genes. Furthermore, there appears to be a cellular activity that functions in a manner analogous to E1A. Recent experiments also suggest a role for E1A in negative regulation of transcription, mediated through enhancer elements, that may be one aspect of gene control during cellular differentiation. Therefore, the study of E1A action may well contribute to an understanding of cellular transcription control. Finally, other mechanisms of transcription control in adenovirus infected cells such as genome replication-dependent gene activation and transcription termination control will likely contribute to the overall understanding of the control of mammalian cell gene expression.

Poly(A) site cleavage in a HeLa nuclear extract is dependent on downstream sequences

Efficient utilization of the early SV40 poly(A) site in vivo requires sequences between 5 bp and 18 bp downstream of the cleavage site. We have used a HeLa nuclear extract to examine the sequence requirements for in vitro cleavage. DNA segments containing the SV40 poly(A) site were cloned into an SP6 vector. SP6 RNAs, accurately cleaved and polyadenylated, were detected by primer extension. Cleavage was enhanced by the presence of a cap on the primary transcript, and was inhibited by the addition of 10 microM 7meGpppG. In close agreement with the in vivo results, efficient processing at the poly(A) site in vitro required the specific downstream sequences in the SP6 RNA transcript. These experiments indicate that the sequence in the RNA precursor downstream of the cleavage site, shown to be important for efficient processing in vivo, is recognized in vitro.

Partial block to transcription of human adenovirus type 2 late genes in abortively infected monkey cells

The block to efficient growth of human adenovirus in monkey cells results in depressed synthesis of late viral polypeptides. This is attributable in part to reduced steady-state levels of the encoding mRNAs. To identify the molecular basis for the reduction in late cytoplasmic mRNA, we compared nuclear RNA synthesis and cytoplasmic mRNA stability in monkey cells abortively infected with wild-type adenovirus serotype 2 (Ad2) and productively infected with the host-range mutant of Ad2, Ad2hr400, or productively infected with Ad2 plus simian virus 40. The half-lives of cytoplasmic mRNA from late gene families L3 (hexon), L4 (100K protein), and L5 (fiber) are similar in abortively and productively infected cells. However, the rate of RNA transcription is reduced 4- to 10-fold and correlates with the reductions in steady-state levels of cytoplasmic RNA. The depression in the rate of transcription cannot be accounted for by a difference in the amount of viral DNA present in abortively and productively infected cells. These studies also suggest that transcription from the major late promoter of Ad2 prematurely terminates in both monkey cells and human cells during the late phase of infection. Premature termination appears to be enhanced in abortive compared with productive infections of monkey cells and may contribute to the reduction in rates of nuclear RNA synthesis. Since the simian virus 40 T antigen or the adenovirus host-range mutant DNA-binding protein overcome these transcriptional impediments, these proteins are either directly or indirectly involved in transcriptional regulation of Ad2 late gene expression.

The human HLA class II alpha chain gene DZ alpha is distinct from genes in the DP, DQ and DR subregions

A new human HLA class II alpha gene DZ alpha was sequenced. The structure and organisation of the gene was similar to other alpha chain genes except for a particularly small intron (95 bp) after the exon encoding the alpha 2 domain, and the position of the stop codon, which was on a different exon to that encoding the cytoplasmic portion of the molecule. Comparison of the DZ alpha sequence with other class II genes showed that the gene is about as distantly related to alpha chain genes in the DP, DQ and DR subregions as they are to each other. The DZ alpha gene results in an unusually large mRNA transcript of greater than 3.0 kb, detected on Northern blots of B cell lines. From the sequence, there are no obvious features that would render DZ alpha a pseudogene, except for an unusual poly(A)+ addition signal, ACTAAA. Analysis of Northern blots shows that sequences downstream (3') of this signal are present in mature mRNA. The large transcripts are probably due to defects in the signals for processing of the mRNA transcript at the 3' end.

Formation of the 3' end of U1 snRNA is directed by a conserved sequence located downstream of the coding region

U1 is a small non-polyadenylated nuclear RNA that is transcribed by RNA polymerase II and is known to play a role in mRNA splicing. The mature 3' end of U1 snRNA is formed in at least two steps. The first step generates precursors of U1 RNA with a few extra nucleotides at the 3' end; in the second step, these precursors are shortened to mature U1 RNA. Here, I have determined the sequences required for the first step. Human U1 genes with various deletions and substitutions near the 3' end of the coding region were constructed and introduced into HeLa cells by DNA transfection. The structure of the RNA synthesized during transient expression of the exogenous U1 gene was analyzed by S1 mapping. The results show that a 13 nucleotide sequence located downstream from the U1 coding region and conserved among U1, U2 and U3 genes of different species is the only sequence required to direct the first step in the formation of the 3' end of U1 snRNA.

Transcription unit of the rabbit beta 1 globin gene

We have hybridized pulse-labeled nuclear transcripts to cloned DNA fragments from the rabbit beta-like globin genes to determine the developmental timing, extent, and asymmetry of their transcription. The fetal-adult gene beta 1 was transcribed in fetal liver but not embryonic nuclei, whereas genes beta 3 and beta 4, which encode embryonic globin polypeptides, were transcribed only in embryonic nuclei. This shows that the switch from embryonic to fetal-adult globin production in rabbits is accomplished primarily by differential transcription of the beta-like globin genes. Gene beta 1 was subdivided into M13 subclones and tested for hybridization to nascent RNA. The nucleotide sequence of the 3' flanking region of gene beta 1 was also determined for 2,447 base pairs past the polyadenylation [poly(A)] site. No transcripts were found 5' to the cap site, but asymmetric transcription of gene beta 1 proceeded at a high level through the gene and past the poly(A) addition site for 603 nucleotides. The level of transcription declined after this, gradually dropping through the next 568 nucleotides. No polymerases were found on a fragment that begins 1,707 nucleotides past the poly(A) site; this fragment was part of a segment of repetitive DNA. These data show that the transcription unit of gene beta 1 begins at or near the cap nucleotide and extends at least 1,171 but no more than 1,706 nucleotides past the poly(A) addition site. The DNA segment that precedes the region of declining transcription contained an inverted repeat and encoded a short RNA transcribed by RNA polymerase II from the strand opposite the beta 1 transcript. These two features may function to attenuate the transcription of gene beta 1. An inverted repeat and a potential polymerase II transcription unit were also found in the homologous segment 3' to the human beta-globin gene. A short DNA segment close to the 3' end of the beta 1 transcription unit was transcribed more actively than the surrounding DNA, and it contained sequences that match the consensus internal control region for RNA polymerase III. This DNA segment may contain a separate polymerase III transcription unit. A member of the D repeat family located 3' to gene beta 1 was not transcribed in its entirety coordinately with beta 1.

Calcitonin/calcitonin gene-related peptide transcription unit: tissue-specific expression involves selective use of alternative polyadenylation sites

Different 3' coding exons in the rat calcitonin gene are used to generate distinct mRNAs encoding either the hormone calcitonin in thyroidal C-cells or a new neuropeptide referred to as calcitonin gene-related peptide in neuronal tissue, indicating the RNA processing regulation is one strategy used in tissue-specific regulation of gene expression in the brain. Although the two mRNAs use the same transcriptional initiation site and have identical 5' terminal sequences, their 3' termini are distinct. The polyadenylation sites for calcitonin and calcitonin gene-related peptide mRNAs are located at the end of the exons 4 and 6, respectively. Termination of transcription after the calcitonin exon does not dictate the production of calcitonin mRNA, because transcription proceeds through both calcitonin and calcitonin gene-related peptide exons irrespective of which mRNA is ultimately produced. In isolated nuclei, both polyadenylation sites appear to be utilized; however, the proximal (calcitonin) site is preferentially used in nuclei from tissues producing calcitonin mRNA. These data suggest that the mechanism dictating production of each mRNA involves the selective use of alternative polyadenylation sites.

Transcription unit of the rabbit beta 1 globin gene

We have hybridized pulse-labeled nuclear transcripts to cloned DNA fragments from the rabbit beta-like globin genes to determine the developmental timing, extent, and asymmetry of their transcription. The fetal-adult gene beta 1 was transcribed in fetal liver but not embryonic nuclei, whereas genes beta 3 and beta 4, which encode embryonic globin polypeptides, were transcribed only in embryonic nuclei. This shows that the switch from embryonic to fetal-adult globin production in rabbits is accomplished primarily by differential transcription of the beta-like globin genes. Gene beta 1 was subdivided into M13 subclones and tested for hybridization to nascent RNA. The nucleotide sequence of the 3' flanking region of gene beta 1 was also determined for 2,447 base pairs past the polyadenylation [poly(A)] site. No transcripts were found 5' to the cap site, but asymmetric transcription of gene beta 1 proceeded at a high level through the gene and past the poly(A) addition site for 603 nucleotides. The level of transcription declined after this, gradually dropping through the next 568 nucleotides. No polymerases were found on a fragment that begins 1,707 nucleotides past the poly(A) site; this fragment was part of a segment of repetitive DNA. These data show that the transcription unit of gene beta 1 begins at or near the cap nucleotide and extends at least 1,171 but no more than 1,706 nucleotides past the poly(A) addition site. The DNA segment that precedes the region of declining transcription contained an inverted repeat and encoded a short RNA transcribed by RNA polymerase II from the strand opposite the beta 1 transcript. These two features may function to attenuate the transcription of gene beta 1. An inverted repeat and a potential polymerase II transcription unit were also found in the homologous segment 3' to the human beta-globin gene. A short DNA segment close to the 3' end of the beta 1 transcription unit was transcribed more actively than the surrounding DNA, and it contained sequences that match the consensus internal control region for RNA polymerase III. This DNA segment may contain a separate polymerase III transcription unit. A member of the D repeat family located 3' to gene beta 1 was not transcribed in its entirety coordinately with beta 1.

Mouse c-mos oncogene activation is prevented by upstream sequences

Although the molecularly cloned mouse c-mos oncogene locus can be efficiently activated by insertion of a retroviral long terminal repeat (LTR) 5' to its coding region, only low-frequency transformation occurs with the LTR element inserted 3' to this region. Analysis of several of the latter transformed cell lines suggested that loss of 2 kilobases (kb) of normal mouse DNA sequences preceding c-mos was required for oncogene activation. The determination of the transforming potential of deletion mutants containing only portions of this region followed by analysis of their nucleotide sequences identified a region termed upstream mouse sequence (UMS) as a cis-acting locus that prevents c-mos activation by a 3' LTR. The UMS region is approximately 1 kb in length and is located 0.8-1.8 kb upstream from the first ATG in the open reading frame of c-mos. Insertion of UMS 5' to the v-mos coding region also prevents 3' LTR enhancement of its transforming activity, but this inhibition is position dependent and functions only when inserted between v-mos and its putative promoter. The results presented here suggest that UMS may function to regulate c-mos proto-oncogene expression and may explain the lack of detectable c-mos transcripts in normal mouse cells.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Processing and nucleo-cytoplasmic transport of histone gene transcripts

Precursors of Xenopus and sea urchin histone mRNAs were synthesized in vitro with the SP6 transcription system, and their maturation and nucleo-cytoplasmic transport was studied by frog oocyte injection. 3' processing is most rapid for homologous histone messenger sequences and does not require either genuine 5' or specific 3' ends of the precursor, but capping of the 5' terminus strongly influences the efficiency of 3' processing. No generation of 5' histone mRNA ends can be detected when precursors containing 5' spacer sequence extensions are injected into the oocyte nucleus. This finding may have some implications for the question whether histone gene transcription could be polycistronic. Using a novel oocyte technique, we have separated nuclei from cytoplasm and have studied the time course of exit of the processed RNA from the oocyte nucleus into the cytoplasm. The results suggest that RNA maturation and nucleo-cytoplasmic transport are not temporally coupled processes.

Calcitonin/calcitonin gene-related peptide transcription unit: tissue-specific expression involves selective use of alternative polyadenylation sites

Different 3' coding exons in the rat calcitonin gene are used to generate distinct mRNAs encoding either the hormone calcitonin in thyroidal C-cells or a new neuropeptide referred to as calcitonin gene-related peptide in neuronal tissue, indicating the RNA processing regulation is one strategy used in tissue-specific regulation of gene expression in the brain. Although the two mRNAs use the same transcriptional initiation site and have identical 5' terminal sequences, their 3' termini are distinct. The polyadenylation sites for calcitonin and calcitonin gene-related peptide mRNAs are located at the end of the exons 4 and 6, respectively. Termination of transcription after the calcitonin exon does not dictate the production of calcitonin mRNA, because transcription proceeds through both calcitonin and calcitonin gene-related peptide exons irrespective of which mRNA is ultimately produced. In isolated nuclei, both polyadenylation sites appear to be utilized; however, the proximal (calcitonin) site is preferentially used in nuclei from tissues producing calcitonin mRNA. These data suggest that the mechanism dictating production of each mRNA involves the selective use of alternative polyadenylation sites.

Termination of transcription in the mouse alpha-amylase gene Amy-2a occurs at multiple sites downstream of the polyadenylation site

We have delimited the region of transcription termination in the alpha-amylase gene Amy-2a. Mapping of in vitro elongated nascent transcripts to Amy-2a restriction fragments indicates that transcription terminates in a region between 2.5 and 4 kb downstream of the polyadenylation site. These runoff transcription experiments, combined with S1 nuclease mapping of nuclear transcripts at steady state, suggest that transcription termination occurs at multiple sites.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Specific termination of in vitro transcription by calf thymus RNA polymerase III

In vitro transcription of cleaved SV40 DNA with calf thymus RNA polymerase reveals a discrete transcript. The pattern of resistance to the inhibitor alpha-amanitin identifies the RNA as a product of RNA polymerase III transcription. The RNA is shown to initiate artificially near a DNA terminus created by cleavage and to terminate specifically near a cluster of 8 thymidine residues within the SV40 control region. Faithfully initiated transcripts cannot be detected using the calf thymus enzyme, supporting the idea that polymerase III termination can be accomplished by an initiation-deficient enzyme. Transcription of SV40 DNA in a HeLa cell lysate also leads to specific polymerase III transcription. When PvuII-cleaved DNA is the template, the same RNA is produced as with the calf thymus enzyme. At the lowered lysate concentration known to activate certain AluI-family transcripts, a collection of SV40 polymerase III transcripts is also produced. These do not depend on restriction cleavage of the DNA and thus arise from transcription of intact DNA.

Requirement of a downstream sequence for generation of a poly(A) addition site

The 3' terminus of most, if not all, eucaryotic polyadenylated mRNAs is formed as a result of endonucleolytic cleavage of a larger precursor RNA. That is, transcription does not terminate at the mRNA 3' sequence but rather proceeds through this site, terminating at some distance downstream. Using a plasmid containing the adenovirus E2A transcriptional unit, we have investigated the sequence requirement for the formation of a mature mRNA 3' terminus, focusing on the role of sequences immediately distal to the poly(A) addition site. Deletion mutants were constructed in the region distal to the poly(A) addition site and assayed by transfection into human 293 cells. The results demonstrate that 35 nucleotides distal to the site of poly(A) addition are sufficient for the formation of a mature E2 mRNA. However, removal of an additional 15 nucleotides, leaving 20 nucleotides distal to the poly(A) site, abolished the ability to produce functional E2A mRNA. The defect in the production of functional mRNA from such a mutant appears to be in the proper cleavage of the primary transcript at the poly(A) addition site. It would thus appear that sequences immediately distal to the site of poly(A) addition do not contribute to the mature mRNA but are essential for the formation of mature mRNA.

Requirement for the 3' flanking region of the bovine growth hormone gene for accurate polyadenylylation

We examined whether the sequence extending 3' to the polyadenylylation site of the bovine growth hormone gene contains any signal that affects the polyadenylylation of the growth hormone mRNA. For this purpose, cloned copies of this gene, each containing a different length of growth hormone-specific sequence 3' to the wild-type polyadenylylation site, were used to transfect COS-1 cells. The polyadenylylation site on the mRNAs produced from the exogenously added growth hormone genes were analyzed with an S1 nuclease mapping procedure. We found that a gene containing 84 base pairs of its own 3' flanking sequence is capable of producing an accurately polyadenylylated mRNA. On the other hand, genes containing only 1, 10, or 13 base pairs of 3' flanking sequence were principally polyadenylylated at discrete sites either upstream or downstream from the wild-type position. Using a computer program, we examined whether secondary structures on the primary growth hormone transcript correlated with the site where the mRNA is polyadenylylated.

Kinetics and efficiency of polyadenylation of late polyomavirus nuclear RNA: generation of oligomeric polyadenylated RNAs and their processing into mRNA

The rate and efficiency of polyadenylation of late polyomavirus RNA in the nucleus of productively infected mouse kidney cells were determined by measuring incorporation of [3H]uridine into total and polyadenylated viral RNAs fractionated by oligodeoxythymidylic acid-cellulose chromatography. Polyadenylation is rapid: the average delay between synthesis and polyadenylation of viral RNA in the nucleus is 1 to 2 min. However, only 10 to 25% of viral RNA molecules become polyadenylated. Polyadenylated RNAs in the nucleus are a family of molecules which differ in size by an integral number of viral genome lengths (5.3 kilobases). These RNAs are generated by repeated passage of RNA polymerase around the circular viral DNA, accompanied by addition of polyadenylic acid to a unique 3' end situated 2.2 + n(5.3) kilobases from the 5' end of the RNAs (n can be an integer from 0 to at least 3). Between 30 and 50% of the sequences in nuclear polyadenylated RNA are conserved during processing and transport to the cytoplasm as mRNA. This is consistent with the molar ratios of nuclear polyadenylated RNAs in the different size classes, and it suggests that most polyadenylated nuclear RNA is efficiently processed to mRNA. Thus, the low overall conservation of viral RNA sequences between nucleus and cytoplasm is explained by (i) low efficiency of polyadenylation of nuclear RNA and (ii) removal of substantial parts of polyadenylated RNAs during splicing. The correlation between inefficient termination of transcription and inefficient polyadenylation of transcripts suggests that these two events may be causally linked.

Are U4 small nuclear ribonucleoproteins involved in polyadenylation?

The mechanism whereby eukaryotic pre-messenger RNAs are polyadenylated is unknown. Most models for polyadenylation invoke cleavage of precursor transcripts at the site of poly(A) addition followed by polymerization of A residues by poly(A) polymerase. Analysis of the sequences surrounding poly(A) addition sites has identified the consensus recognition sequence element AAUAAA as necessary but not sufficient for polyadenylation. A second recognition sequence element CACUG , was observed by Benoit et al. to be adjacent to the site of poly(A) addition in several sequenced RNAs. Here, we analyse 61 vertebrate poly(A) addition sequences, define a more extensive recognition sequence for polyadenylation than previously recognized and suggest how the site of poly(A) addition may be chosen. Furthermore, we find that the defined recognition sequence has elements which are complementary to regions within the small nuclear RNA U4, suggesting that U4 small nuclear ribonucleoproteins (snRNPs) may mediate polyadenylation in a fashion similar to the role of U1 snRNPs in splicing. The model invokes hybridization of U4 RNA to AAUAAA recognition elements as related to primary site selection, and hybridization to CAYUG recognition elements as related to cleavage site selection.

Kinetics and efficiency of polyadenylation of late polyomavirus nuclear RNA: generation of oligomeric polyadenylated RNAs and their processing into mRNA

The rate and efficiency of polyadenylation of late polyomavirus RNA in the nucleus of productively infected mouse kidney cells were determined by measuring incorporation of [3H]uridine into total and polyadenylated viral RNAs fractionated by oligodeoxythymidylic acid-cellulose chromatography. Polyadenylation is rapid: the average delay between synthesis and polyadenylation of viral RNA in the nucleus is 1 to 2 min. However, only 10 to 25% of viral RNA molecules become polyadenylated. Polyadenylated RNAs in the nucleus are a family of molecules which differ in size by an integral number of viral genome lengths (5.3 kilobases). These RNAs are generated by repeated passage of RNA polymerase around the circular viral DNA, accompanied by addition of polyadenylic acid to a unique 3' end situated 2.2 + n(5.3) kilobases from the 5' end of the RNAs (n can be an integer from 0 to at least 3). Between 30 and 50% of the sequences in nuclear polyadenylated RNA are conserved during processing and transport to the cytoplasm as mRNA. This is consistent with the molar ratios of nuclear polyadenylated RNAs in the different size classes, and it suggests that most polyadenylated nuclear RNA is efficiently processed to mRNA. Thus, the low overall conservation of viral RNA sequences between nucleus and cytoplasm is explained by (i) low efficiency of polyadenylation of nuclear RNA and (ii) removal of substantial parts of polyadenylated RNAs during splicing. The correlation between inefficient termination of transcription and inefficient polyadenylation of transcripts suggests that these two events may be causally linked.

Site-specific polyadenylation in a cell-free reaction

A soluble HeLa cell extract accurately polyadenylates RNA transcribed from DNA templates containing the adenovirus L3 polyadenylation site. Regardless of the length of these DNA templates, the major polyadenylated species had 3' termini corresponding to the in vivo site. Polyadenylated RNA appears after an hour lag and only reaches maximum levels after 4 hr of incubation, a time course similar to that of splicing in this extract. Inhibitor studies suggest that the polyadenylation reaction is not coupled to active transcription. Unlike splicing in this extract where exogenous substrate is processed, addition of purified RNA precursor to the reaction does not yield product polyadenylated at L3 but rather results in addition of poly (A) to termini of the precursor. This suggests that part of the specificity of polyadenylation is established by in situ synthesis of RNA. Surprisingly, synthesis of accurately polyadenylated RNA may involve small nuclear ribonucleoprotein particles (snRNPs). The reaction is inhibited by antisera of Sm and U1 RNP specificities as well as antiserum to the nuclear antigen La, but is not inhibited by control serum and anti-(U2)RNP serum.

Tissue-specific expression of two mRNA species transcribed from a single vimentin gene

We have isolated chicken cDNA and genomic clones for the intermediate filament subunit vimentin and show that the gene for this protein, which exists in a single copy in the haploid chicken genome, is transcribed into two mature mRNA species with approximate lengths of 2.0 and 2.3 kb. We have found cell-specific regulation in the expression of these two mRNAs; whereas both mRNA species are present in muscle cells, fibroblasts, spinal cord and lens, erythroid cells from 10- and 15-day-old chicken embryos express predominantly the lower molecular weight RNA. The difference between these two mRNAs is due to different lengths of their 3' untranslated regions, suggesting that the cell-specific regulation of their expression occurs either by specific termination of transcription or by differential post-transcriptional processing of the 3' untranslated region. Additionally, a remarkable induction (40- to 50-fold) in the abundance of the vimentin mRNA is observed in erythroid cells as chicken development proceeds from 4 to 15 days, which suggests that the level of expression of vimentin during erythroid development is regulated at the transcriptional level.

The terminal RNA stem-loop structure and 80 bp of spacer DNA are required for the formation of 3' termini of sea urchin H2A mRNA

We have studied the exact sequence requirement for the formation of 3' termini of the sea urchin H2A mRNA in frog oocyte injection experiments. Point mutations destroying the symmetry of the inverted DNA repeat in the mRNA trailer coding sequences prevent the generation of genuine 3' termini. Mutants containing complementary base changes are pseudorevertants and allow the production of H2A mRNA with faithful 3' termini at wild-type levels. Our transcription analyses show that it is primarily the sequence of the transcribed strand that decides whether or not true 3' mRNA termini are produced. This is evidence that an RNA stem-loop structure, rather than a DNA cruciform, is essential for this process. Spacer sequences are absolutely required, because in their absence only H2A mRNA with spacer transcript extensions are found. Once the canonical CAAGAAAGA and flanking sequences are linked to the H2A gene, H2A messenger is synthesized at a suboptimal rate, which can be increased to wild-type levels by the addition of 80 bp of the spacer immediately adjacent to the H2A gene.

Alpha-thalassaemia caused by a polyadenylation signal mutation

Most eukaryotic messenger RNAs have the sequence AAUAAA 11-30 nucleotides from the 3'-terminal poly(A) tract. Since this is the only significant sequence homology in the 3' non-coding region it has been suggested that it may be a recognition site for enzymes involved in polyadenylation and/or termination of polymerase II transcription. This idea is strengthened by observations on the effect of deletion mutations in or around the AATAAA sequence on polyadenylation of late simian virus 40 (SV40) mRNA; removal of this sequence prevents poly(A) addition. Naturally occurring variants of this hexanucleotide are rare and hitherto their functional significance has not been assessed. We have now identified a human alpha 2-globin gene which contains a single point mutation in this hexanucleotide (AATAAA leads to AATAAG). The paired alpha 1 gene on the same chromosome is completely inactivated by a frame-shift mutation. This unique combination has enabled the expression of the mutant alpha 2 gene to be studied in vivo where it has been found that the accumulated level of alpha 2-specific mRNA in erythroid cells is reduced. Furthermore, readthrough transcripts extending beyond the normal poly(A) addition site are detected in mRNA obtained from HeLa cells transfected with cloned DNA from the mutant alpha 2 gene, suggesting that the single nucleotide change in the AATAAA sequence is the cause of its abnormal expression.

Inhibition of RNA cleavage but not polyadenylation by a point mutation in mRNA 3' consensus sequence AAUAAA

A single U leads to G transversion in the 3' consensus sequence AAUAAA of the adenovirus early region 1A gene was constructed and the effect of this mutation on processing of the 3' end of the nuclear early region 1A RNAs was analysed. The results demonstrate that the intact AAUAAA is not required for RNA polyadenylation but is required for the cleavage step preceding polyadenylation to occur efficiently.

DNA sequences of yeast H3 and H4 histone genes from two non-allelic gene sets encode identical H3 and H4 proteins

The complete DNA sequences of two loci encoding H3 and H4 histones in Saccharomyces cerevisiae have been determined. Each locus contains one H3 and one H4 gene. The genes at each locus are divergently transcribed and the coding sequences are separated by 646 base-pairs at one locus and 676 base-pairs at the other. The H3 genes code for identical histone H3 proteins and the H4 genes code for identical histone H4 proteins. The yeast proteins differ from histones H3 and H4 of calf by 15 and 8 amino acid substitutions, respectively, and these differences are largely confined to the carboxy-terminal halves of the proteins. The genes demonstrate a bias in synonymous codon usage similar to that noted for other yeast genes. This bias is confined to the coding sequences of the genes and is specific for the reading frame encoding the proteins. The coding sequence of each gene is flanked on both sides by DNA with an A + T content of 70 to 80%. Possible regulatory sequences are located relative to the 5' and 3'-termini of the histone H3 and H4 RNA transcripts.

Mammalian keratin gene families: organisation of genes coding for the B2 high-sulphur proteins of sheep wool

We have isolated two genomic clones containing three B2 high-sulphur keratin genes from a sheep genomic library constructed in Charon 4A. These genes do not contain intervening sequences. Two genes, encoding the B2A and B2D proteins are closely linked in the genome, being separated by 1.9 kb, and are transcribed in the same direction. Although there is extensive sequence conservation in the 5' non-coding and coding regions, the 3' non-coding regions diverge both in length and sequence. Within the 5' non-coding region adjacent to the initiating AUG there is a highly conserved 18 bp sequence which is also present in another gene coding for a member of a different, unrelated high-sulphur keratin family. In the B2A-B2D intergene region, tightly linked to the B2D gene, there is a putative, divergently transcribed gene.

A precise termination site in the mouse beta major-globin transcription unit

Nascent labeled RNA from induced, globin-producing mouse erythroleukemia cells was hybridized to cloned regions of the beta major-globin gene. Transcription ceases about 1,000 bases downstream from the poly(A) site as indicated by protection from nuclease digestion of a discrete-sized RNA fragment that it shorter than the protecting cloned DNA fragment. This defines an apparently unique termination site for a protein-coding gene that is transcribed by RNA polymerase II.

Analysis in Cos-1 cells of processing and polyadenylation signals by using derivatives of the herpes simplex virus type 1 thymidine kinase gene

Bal31 nuclease was used to resect the herpes simplex virus type 1 thymidine kinase (tk) gene from its 3' end, and a plasmid, pTK206, was isolated that lacked the processing and polyadenylation signals normally found at the 3' end of the gene. The wild-type gene, pTK2, and pTK206 were each transferred to pSV010, a plasmid containing the simian virus 40 (SV40) origin of DNA replication, allowing replication and analysis of the patterns of transcription in Cos-1 cells. Fragments of DNA containing processing and polyadenylation signals from SV40 and polyoma virus were inserted into the 3' end of the resected tk gene, pTK206. We found that tk gene expression requires a processing and polyadenylation signal, that signals from SV40 and polyoma virus could substitute for the herpes simplex virus tk signal, and that considerable differences in the levels of tk mRNA were present in Cos-1 cells transfected by these gene constructs. In addition, tk gene expression was restored to a low level after the insertion of an 88-base-pair fragment from the middle of the SV40 early region. Processing and polyadenylation do not occur in the vicinity of this fragment in SV40, even though it contains the hexanucleotide 5'-AAUAAA-3'.

Structure of three spliced mRNAs from region E3 of adenovirus type 2

A cDNA library representing early adenovirus type 2 (Ad2) mRNA was constructed. The cDNA copies were inserted into the PstI cleavage site of the pBR322 plasmid, and clones containing sequences from region E3 of the Ad2 genome were identified by colony hybridization. Selected clones were characterized by restriction enzyme cleavage, hybridization, and partial DNA sequence analysis. The precise structure of three spliced mRNAs was established by comparing the results with the DNA sequence of region E3 from Ad2 (Herissé et al., Nucl. Acids Res. 8 (1980) 2173--2191; Herissé and Galibert, Nucl. Acids Res. 9 (1981) 1229--1249). One of the characterized mRNA species encodes the E3/19K glycoprotein, whereas the other two most likely encode the E3/14K protein. The results demonstrate, moreover, that certain splice points which are used to generate the major E3 mRNAs are also used to splice the supplementary leader segments to the fibre mRNA at late times after infection. Two separate poly(A)-addition sites were identified in region E3 by analysis of the cDNA clones; one is preceded by the hexanucleotide sequence AAUAAA, whereas the other is preceded by an altered hexanucleotide, having the sequence AUUAAA.