Rna synthesis in isolated nuclei processing of adenovirus serotype 2 late messenger rna precursors

Protein factors in pre-mRNA 3'-end processing

Most eukaryotic mRNA precursors (premRNAs) must undergo extensive processing, including cleavage and polyadenylation at the 3'-end. Processing at the 3'-end is controlled by sequence elements in the pre-mRNA (cis elements) as well as protein factors. Despite the seeming biochemical simplicity of the processing reactions, more than 14 proteins have been identified for the mammalian complex, and more than 20 proteins have been identified for the yeast complex. The 3'-end processing machinery also has important roles in transcription and splicing. The mammalian machinery contains several sub-complexes, including cleavage and polyadenylation specificity factor, cleavage stimulation factor, cleavage factor I, and cleavage factor II. Additional protein factors include poly(A) polymerase, poly(A)-binding protein, symplekin, and the C-terminal domain of RNA polymerase II largest subunit. The yeast machinery includes cleavage factor IA, cleavage factor IB, and cleavage and polyadenylation factor.

Coupling of transcription termination to RNAi

In metazoans, the mechanisms of transcriptional termination by RNA polymerase II (Pol II) and accelerated decay of messenger RNA (mRNA) following transcription shutdown are linked by sharing the same sequence elements and mRNA elongation, processing and termination factors. This begs the question, how could one process have two opposite outcomes, making or degrading mRNA? An integrated "allosteric-GENEi-torpedo" model that could explain this paradox predicts participation of two novel factors: (1) An allosteric factor, regulated by a physiological repressor, binds to a unique sequence element of a gene near the site of cleavage and polyadenylation, poly(A) site, and acts on the homologous site on the nascent transcript to cause its cleavage. The conformational changes of this factor determine the fate of nascent RNA, either to get cleaved and processed to mature mRNA for directing protein synthesis, or not to get cleaved and become template for double-stranded (ds) RNA synthesis. (2) A general transcription termination factor, recruited by transcribing Pol II at the poly(A) site, allostrically alters and induces Pol II to switch template from DNA to nascent RNA several hundred nucleotides downstream of the poly(A) site. The template switch disengages Pol II from DNA and effectively terminates transcription. The Pol II with newly acquired RNA-dependent RNA polymerase activity retraces its path, back along the nascent RNA, so generating dsRNA. The extent to which it can retrace this path is determined by the factors influencing the cleavage of the pre-mRNA at the site of polyA addition. If cleavage and polyadenylation occur, the retracing is cut short, the 3' RNA is degraded by an exonuclease and the polymerase is liberated to reinitiate transcription. If the cleavage is inhibited, then a full-length dsRNA can be produced. This can then be subject to cleavage by "Dicer", which generates fragments of approximately 22bp that guide degradation of the cognate mRNA via the RNA interference (RNAi) pathway. This model complements the current "allosteric-torpedo" model of transcription termination, and could explain the apparent paradox of the divergent results of a common biological process.

The RNA tether from the poly(A) signal to the polymerase mediates coupling of transcription to cleavage and polyadenylation

We have investigated the mechanism by which transcription accelerates cleavage and polyadenylation in vitro. By using a coupled transcription-processing system, we show that rapid and efficient 3' end processing occurs in the absence of crowding agents like polyvinyl alcohol. The continuity of the RNA from the poly(A) signal down to the polymerase is critical to this processing. If this tether is cut with DNA oligonucleotides and RNaseH during transcription, the efficiency of processing is drastically reduced. The polymerase is known to be an integral part of the cleavage and polyadenylation apparatus. RNA polymerase II pull-down and immobilized template experiments suggest that the role of the tether is to hold the poly(A) signal close to the polymerase during the early stages of processing complex assembly until the complex is sufficiently mature to remain stably associated with the polymerase on its own.

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.

RNA polymerase II-dependent positional effects on mRNA 3' end processing in the adenovirus major late transcription unit

During the early phase of adenovirus infection, the promoter-proximal L1 poly(A) site in the major late transcription unit is used preferentially despite the fact that the distal L3 poly(A) site is stronger (i.e. it competes better for processing factors and is cleaved at a faster rate, in vitro). Previous work had established that this was due at least in part to the stable binding of the processing factor, cleavage and polyadenylation specificity factor, to the L1 poly(A) site as mediated by specific regulatory sequences. It is now demonstrated that in addition, the L1 poly(A) site has a positional advantage because of its 5' location in the transcription unit. We also show that preferential processing of a particular poly(A) site in a complex transcription unit is dependent on RNA polymerase II. Our results are consistent with recent reports demonstrating that the processing factors cleavage and polyadenylation specificity factor and cleavage stimulatory factor are associated with the RNA polymerase II holoenzyme; thus, processing at a weak poly(A) site like L1 can be enhanced by virtue of its being the first site to be transcribed.

Control of nuclear export of hnRNP A1

mRNA export is mediated by RNA-binding proteins which shuttle between the nucleus and cytoplasm. Using an in vitro unidirectional export assay, we observe that the shuttling mRNA-binding protein, hnRNP A1, is exported only extremely slowly unless incubations are supplemented with snRNA-specific oligonucleotides which inhibit splicing. In vivo microinjection experiments support this conclusion. Like many examples of nucleocytoplasmic transport, export of hnRNP A1 requires energy and is sensitive to the presence of wheat germ agglutinin. It does not, however, require supplementation with cytoplasmic proteins. Although the exportin, Crm1, is needed for export of several varieties of RNA, both the in vitro assay and in vivo assays show that it is not required for export of hnRNP A1. In vitro and in vivo studies also show that inhibition of transcription allows continued shuttling of hnRNP A1 and in fact accelerates its export. Judging from the stimulatory effects of targeted destruction of snRNAs, this is likely to reflect completion of the covalent maturation of the RNAs with which hnRNP A1 associates. These observations therefore provide a simple explanation of why multiple RNA-binding proteins relocate to the cytoplasm upon inhibition of transcription in vivo.

The polyadenylation factor CstF-64 regulates alternative processing of IgM heavy chain pre-mRNA during B cell differentiation

The switch from membrane-bound to secreted-form IgM that occurs during differentiation of B lymphocytes has long been known to involve regulated processing of the heavy chain pre-mRNA. Here, we show that accumulation of one subunit of an essential polyadenylation factor (CstF-64) is specifically repressed in mouse primary B cells and that overexpression of CstF-64 is sufficient to switch heavy chain expression from membrane-bound (microm) to secreted form (micros). We further show that CstF-64 is limiting for formation of intact CstF, that CstF has a higher affinity for the microm poly(A) site than for the micros site, and that the microm site is stronger in a reconstituted in vitro processing reaction. Our results indicate that CstF-64 plays a key role in regulating IgM heavy chain expression during B cell differentiation.

Regulated adenovirus mRNA 3'-end formation in a coupled in vitro transcription-processing system

The adenovirus major late transcription unit encodes five poly(A) sites whose use during infection is regulated. Early in the infection, the 5'-most site, L1, is used preferentially, whereas late in infection, all sites are used equivalently. Previous in vivo experiments indicated that regulatory sequences flank the AAUAAA and GU-rich elements of the L1 poly(A) site. We have developed an in vitro coupled transcription-processing system for studying the function of these regulatory sequences in HeLa cell nuclear extracts. The in vitro analysis using this system shows that predominant use of the L1 poly(A) site, as mediated by the upstream regulatory sequence, is independent of transcription. Furthermore, the reaction conditions are favorable to both 3'-end processing and splicing, making this system generally useful for the study of posttranscriptional processes.

The human 64-kDa polyadenylylation factor contains a ribonucleoprotein-type RNA binding domain and unusual auxiliary motifs

Cleavage stimulation factor is one of the multiple factors required for 3'-end cleavage of mammalian pre-mRNAs. We have shown previously that this factor is composed of three subunits with estimated molecular masses of 77, 64, and 50 kDa and that the 64-kDa subunit can be UV-crosslinked to RNA in a polyadenylylation signal (AAUAAA)-dependent manner. We have now isolated cDNAs encoding the 64-kDa subunit of human cleavage stimulation factor. The 64-kDa subunit contains a ribonucleoprotein-type RNA binding domain in the N-terminal region and a repeat structure in the C-terminal region in which a pentapeptide sequence (consensus MEARA/G) is repeated 12 times and the formation of a long alpha-helix stabilized by salt bridges is predicted. An approximately 270-amino acid segment surrounding this repeat structure is highly enriched in proline and glycine residues (approximately 20% for each). When cloned 64-kDa subunit was expressed in Escherichia coli, an N-terminal fragment containing the RNA binding domain bound to RNAs in a polyadenylylation-signal-independent manner, suggesting that the RNA binding domain is directly involved in the binding of the 64-kDa subunit to pre-mRNAs.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

A nuclear micrococcal-sensitive, ATP-dependent exoribonuclease degrades uncapped but not capped RNA substrates

We have developed an assay for an exoribonuclease present in HeLa cell nuclear extracts that degrades capped but not uncapped RNA substrates, and used it to partially purify and characterize such an activity. Capped and uncapped transcripts of different sizes (37-317 nt) were incubated with fractionated nuclear extracts, and in all cases the capped RNAs were stable while their uncapped counterparts were completely degraded. No changes in activity were detected when cap analogs were included in reaction mixtures, suggesting that the stability of capped RNAs was not due to a cap binding protein. The exoribonuclease was shown to be specific for RNA, and to function processively with either substrates containing 5'-hydroxyl or 5'-phosphorylated ends. The products were predominantly 5'-mononucleotides, and no detectable intermediates were observed at any reaction time points. Sedimentation analysis suggests that the native size of the nuclease is 7.4S or approximately 150 kDa. Interestingly, a nucleoside triphosphate was found to be necessary for specific and complete degradation of the uncapped RNAs. Finally, micrococcal nuclease (MN) pretreatment of the partially purified enzyme inhibited its activity. As several controls indicated that this was not due to non-specific effects of MN, this finding suggests that the exoribonuclease contains an essential RNA component.

Elements involved in an in vitro block to transcription elongation at the end of the L1 mRNA family of adenovirus 2

Using the 3' end of the L1 mRNA family of adenovirus 2 (Ad2) as a model system, we investigated transcription elongation following a poly(A) signal in a cell-free system. The results show that RNA polymerase II can halt transcription elongation at a T-rich stretch in the non-coding DNA strand 20 nucleotides downstream of the poly(A) signal. The block to transcription elongation is enhanced when Sarkosyl is included in the elongation reaction. Deletion studies narrowed the region which directs the elongation block at the T-rich stretch, to an upstream fragment of 53 nucleotides that is very dA-rich and also contains a functional poly(A) signal. The deletion studies and analysis by site-directed mutagenesis indicate that in the present system, RNA secondary structure, the stretch of T's and the poly(A) signal are not the dominant elements responsible for the elongation block. The block to transcription elongation at the T-rich stretch was also shown to be 5 times more effective in an uninfected extract than in an Ad2 infected extract, which is reminiscent of the in vivo situation and is consistent with the suggestion that a trans-acting factor is involved in modulating the elongation block at the T-rich stretch.

Sequences upstream of AAUAAA influence poly(A) site selection in a complex transcription unit

The adenovirus major late transcription unit (MLTU) encodes five colinear mRNA families, L1 through L5, each distinguished by a unique poly(A) site. Site selection is regulated during the course of infection, predominating early at the L1 site and late at the L2 through L5 sites. Two general mechanisms can be invoked to explain predominant usage of the L1 site early in infection. MLTU site selection may proceed in a first-come, first-serve manner whereby the L1 site is used most frequently because it is closest to the promoter. Alternatively, specific sequences flanking the L1 site may control predominant L1 site usage in a position-independent manner. To distinguish between these mechanisms, we constructed deletions in the L1 flanking sequences and inserted the mutated sites into either simple transcription units or mini-MLTUs encoding two poly(A) sites. The pattern of site selection for each construct was then quantitated by S1 nuclease analysis after transfection into 293 cells. The results indicated that L1 sequences upstream of AAUAAA define a novel selector element that can cause predominant L1 site usage at either position of a tandem transcription unit. The element did not significantly affect the stability or nucleocytoplasmic transport of L1 transcripts and was not required for efficient 3'-end processing in simple transcription units. Predominant L1 site usage required physical linkage of the processing signals and was independent of the major late promoter.

Sequences upstream of AAUAAA influence poly(A) site selection in a complex transcription unit

The adenovirus major late transcription unit (MLTU) encodes five colinear mRNA families, L1 through L5, each distinguished by a unique poly(A) site. Site selection is regulated during the course of infection, predominating early at the L1 site and late at the L2 through L5 sites. Two general mechanisms can be invoked to explain predominant usage of the L1 site early in infection. MLTU site selection may proceed in a first-come, first-serve manner whereby the L1 site is used most frequently because it is closest to the promoter. Alternatively, specific sequences flanking the L1 site may control predominant L1 site usage in a position-independent manner. To distinguish between these mechanisms, we constructed deletions in the L1 flanking sequences and inserted the mutated sites into either simple transcription units or mini-MLTUs encoding two poly(A) sites. The pattern of site selection for each construct was then quantitated by S1 nuclease analysis after transfection into 293 cells. The results indicated that L1 sequences upstream of AAUAAA define a novel selector element that can cause predominant L1 site usage at either position of a tandem transcription unit. The element did not significantly affect the stability or nucleocytoplasmic transport of L1 transcripts and was not required for efficient 3'-end processing in simple transcription units. Predominant L1 site usage required physical linkage of the processing signals and was independent of the major late promoter.

Transcriptional termination between bovine papillomavirus type 1 (BPV-1) early and late polyadenylation sites blocks late transcription in BPV-1-transformed cells

Bovine papillomavirus type 1 (BPV-1) is a small DNA tumor virus which induces fibropapillomas in cattle and transforms rodent cells in culture. Transcripts are derived from a single strand of the circular viral genome, which has multiple promoters and two polyadenylation sites. In the transformed cell, the first (early) polyadenylation site is utilized exclusively and, therefore, only the early region is expressed. Transcription of the late genes, which requires use of the second (late) polyadenylation site, is seen only in the fully differentiated keratinocytes of the fibropapilloma. In this study, nascent RNA chain analysis of BPV-1-transformed C127 cells was used to demonstrate that at least 90% of the RNA polymerases which transcribe past the early polyadenylation site terminate transcription within the late region before reaching the late polyadenylation site. Therefore, transcription termination is at least partially responsible for the absence of late transcription in the BPV-1-transformed cell and is likely to be an important mechanism for regulation of papillomavirus late transcription during keratinocyte differentiation.

Multiple factors are required for poly(A) addition to a mRNA 3' end

Polyadenylation of pre-mRNAs in the nucleus involves a specific endonucleolytic cleavage, followed by the addition of approximately 200 adenylic acid residues. We have assayed HeLa nuclear extracts for the activity that catalyzes the poly(A) addition reaction. The authenticity of the in vitro assay was indicated by the observation that the poly(A) tract added in vitro is approximately 200 nucleotides in length. We have fractionated nuclear extracts in order to define components involved in specific poly(A) addition. No single fraction from DEAE-Sephacel chromatography of a HeLa nuclear extract possessed the specific poly(A) addition activity. However, if the various fractions were recombined, activity was restored, indicating the presence of multiple components. Further fractionation revealed the presence of at least two factors necessary for the poly(A) addition reaction. The reconstituted system retains the characteristics and specificity seen in the crude extract. Additional purification of one of the factors strongly suggests it to be a previously characterized poly(A) polymerase which, when assayed in the absence of the other factor, can add AMP to an RNA terminus but without specificity. Thus, the other component of the reaction may provide specificity to the process. In contrast to the 3' cleavage reaction, the poly(A) addition machinery does not possess an essential RNA component, as assayed by micrococcal nuclease digestion, nor do anti-Sm sera inhibit the reaction. Thus, the total process of formation of a polyadenylated mRNA 3' end is complex and requires the concerted action of distinct nuclear components.

A functional mRNA polyadenylation signal is required for transcription termination by RNA polymerase II

Polyadenylation of pre-mRNAs requires the conserved hexanucleotide AAUAAA, as well as sequences located downstream from the poly(A) addition site. The role of these sequences in the production of functional mRNAs was studied by analyzing a series of mutants containing deletions or substitutions in the SV40 early region poly(A) site. As expected, both a previously defined GU-rich downstream element and an AAUAAA sequence were required for efficient usage of the wild-type poly(A) addition site. However, when either of these elements was deleted, greatly increased levels of SV40-specific RNA were detected in the nuclei of transfected cells. Evidence is presented that this accumulation of RNA resulted from a failure of transcription termination, leading to multiple rounds of transcription of the circular templates. We conclude that the sequences required for efficient cleavage/polyadenylation of the SV40 early pre-mRNA also constitute an important element of an RNA polymerase II termination signal. A model proposing a mechanism by which the act of pre-mRNA 3' end formation is signaled to the elongating RNA polymerase, resulting in termination, is presented.

Analysis of adenovirus type 2 L1 RNA 3'-end formation in vivo and in vitro

Downstream sequence requirements for efficient cleavage and polyadenylation at the adenovirus type 2 L1 poly(A) site were determined in vivo in 293 cells and in vitro by using RNA precursors in HeLa cell nuclear extracts. The two cleavage sites used were found to differ in sensitivity to 3'-end deletion in vivo and in vitro.

Separation and characterization of a poly(A) polymerase and a cleavage/specificity factor required for pre-mRNA polyadenylation

To study the mechanism and factors required to form the 3' ends of polyadenylated mRNAs, we have fractionated HeLa cell nuclear extracts carrying out the normally coupled cleavage and polyadenylation reactions. Each reaction is catalyzed by a distinct, separable activity. The partially purified cleavage enzyme (at least 360,000 MW) retained the specificity displayed in nuclear extracts, since substitutions in the AAUAAA signal sequence inhibited cleavage. In contrast, the fractionated poly(A) polymerase (300,000 MW) lost all specificity. When fractions containing the cleavage and polyadenylation activities were mixed, the efficiency and specificity of the polyadenylation reaction were restored. Interestingly, the cleavage activity by itself functioned well on only one of four precursor RNAs tested. However, when mixed with the poly(A) polymerase-containing fraction, the cleavage activity processed the four precursors with comparable efficiencies.

Requirements for accurate and efficient mRNA 3' end cleavage and polyadenylation of a simian virus 40 early pre-RNA in vitro

Using a pre-RNA containing the simian virus 40 early introns and poly(A) addition site, we investigated several possible requirements for accurate and efficient mRNA 3' end cleavage and polyadenylation in a HeLa cell nuclear extract. Splicing and 3' end formation occurred under the same conditions but did not appear to be coupled in any way in vitro. Like splicing, 3' end cleavage and polyadenylation each required Mg2+, although spermidine could substitute in the cleavage reaction. Additionally, cleavage of this pre-RNA, but not others, was totally blocked by EDTA, indicating that structural features of pre-RNA may affect the ionic requirements of 3' end formation. The ATP analog 3' dATP inhibited both cleavage and polyadenylation even in the presence of ATP, possibly reflecting the coupled nature of these activities. A 5' cap structure appears not to be required for mRNA 3' end processing in vitro because neither the presence or absence of a 5' cap on the pre-RNA nor the addition of cap analogs to reaction mixtures had any effect on the efficiency of 3' end processing. Micrococcal nuclease pretreatment of the nuclear extract inhibited cleavage and polyadenylation. However, restoration of activity was achieved by addition of purified Escherichia coli RNA, suggesting that the inhibition caused by such a nuclease treatment was due to a general requirement for mass of RNA rather than to destruction of a particular nucleic acid-containing component such as a small nuclear ribonucleoprotein.

Requirements for accurate and efficient mRNA 3' end cleavage and polyadenylation of a simian virus 40 early pre-RNA in vitro

Using a pre-RNA containing the simian virus 40 early introns and poly(A) addition site, we investigated several possible requirements for accurate and efficient mRNA 3' end cleavage and polyadenylation in a HeLa cell nuclear extract. Splicing and 3' end formation occurred under the same conditions but did not appear to be coupled in any way in vitro. Like splicing, 3' end cleavage and polyadenylation each required Mg2+, although spermidine could substitute in the cleavage reaction. Additionally, cleavage of this pre-RNA, but not others, was totally blocked by EDTA, indicating that structural features of pre-RNA may affect the ionic requirements of 3' end formation. The ATP analog 3' dATP inhibited both cleavage and polyadenylation even in the presence of ATP, possibly reflecting the coupled nature of these activities. A 5' cap structure appears not to be required for mRNA 3' end processing in vitro because neither the presence or absence of a 5' cap on the pre-RNA nor the addition of cap analogs to reaction mixtures had any effect on the efficiency of 3' end processing. Micrococcal nuclease pretreatment of the nuclear extract inhibited cleavage and polyadenylation. However, restoration of activity was achieved by addition of purified Escherichia coli RNA, suggesting that the inhibition caused by such a nuclease treatment was due to a general requirement for mass of RNA rather than to destruction of a particular nucleic acid-containing component such as a small nuclear ribonucleoprotein.

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.

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.

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.

Accurate cleavage and polyadenylation of exogenous RNA substrate

Purified precursor RNA containing the L3 polyadenylation site of late adenovirus 2 mRNA is accurately cleaved and polyadenylated when incubated with nuclear extract from HeLa cells. The reaction is very efficient; 75% of the precursor is correctly processed. Cleavage is rapidly followed by polymerization of an initial poly(A) tract of approximately 130 nucleotides. Additional adenosine residues are added during further incubation. In the presence of the ATP analog alpha-beta-methylene-adenosine 5' triphosphate, the precursor RNA is cleaved but not polyadenylated, suggesting that processing is not coupled to the synthesis of the initial poly(A) tract. In the absence of free Mg2+, a small RNA of approximately 46 nucleotides is stabilized against degradation. Fingerprint analysis suggests this RNA is produced by endonucleolytic cleavage at the L3 site. Like the in vitro splicing reaction, the in vitro polyadenylation reaction is inhibited by adding antiserum against the small nuclear ribonucleoprotein particle containing U1 RNA.

Two integrated partial repeats of simian virus 40 together code for a super-T antigen

We determined that the coding sequence for a 100-kilodalton super-T antigen found in Simian virus 40 mouse transformants spanned two separate partial repeats of the viral genome. The downstream repeat contained a complete Simian virus 40 large-T-antigen gene, whereas the upstream repeat was a truncated copy of the same gene. When the repeats were separated by subcloning, the capacity to code for the super-T antigen was lost. A small insertion or deletion in the origin-control region which preceded the second repeat could also destroy the ability to code for the 100-kilodalton protein. Our data suggest that differential splicing between parts of two gene copies was responsible for the additional molecular weight of this super-T antigen.

RNA sequence containing hexanucleotide AAUAAA directs efficient mRNA polyadenylation in vitro

To determine whether a specific nucleotide sequence is required to direct polyadenylation of a simian virus 40 early pre-mRNA in a soluble HeLa whole-cell lysate, we constructed a series of rearranged and deleted DNA templates, transcribed them in vitro, and determined whether the resultant RNAs could be polyadenylated when incubated in whole-cell lysate. When a 237-base-pair DNA fragment encoding the 3' end of the simian virus 40 early pre-mRNA was transferred to recombinant plasmids encoding RNAs that were not substrates for polyadenylation, the resultant RNAs could now be polyadenylated efficiently. In one case, the chimeric RNA was polyadenylated even more efficiently than was the original simian virus 40 early transcript. Analysis of the RNAs produced from the deletion mutant templates revealed that only RNAs containing at least one copy of the AAUAAA sequence situated near the 3' end and implicated in 3'-end formation and polyadenylation in vivo could be polyadenylated in vitro. Surprisingly, this sequence directed polyadenylation of pre-mRNAs not only when near the RNA 3' end, i.e., 50 nucleotides or less away, but also when the 3' end was situated over 400 nucleotides downstream. Thus, our results show that a polyadenylic acid polymerase activity in HeLa lysates can recognize a specific nucleotide sequence in pre-mRNA and then, in the absence of the nucleolytic cleavage that presumably occurs in vivo, locate the RNA 3' end and use it as a primer for polyadenylic acid synthesis.

Two integrated partial repeats of simian virus 40 together code for a super-T antigen

We determined that the coding sequence for a 100-kilodalton super-T antigen found in Simian virus 40 mouse transformants spanned two separate partial repeats of the viral genome. The downstream repeat contained a complete Simian virus 40 large-T-antigen gene, whereas the upstream repeat was a truncated copy of the same gene. When the repeats were separated by subcloning, the capacity to code for the super-T antigen was lost. A small insertion or deletion in the origin-control region which preceded the second repeat could also destroy the ability to code for the 100-kilodalton protein. Our data suggest that differential splicing between parts of two gene copies was responsible for the additional molecular weight of this super-T antigen.

Specific modulation of the transcription of cloned avian vitellogenin II gene by estradiol-receptor complex in vitro

Avian vitellogenin-cauliflower mosaic virus hybrid gene is effectively transcribed in vitro in the homologous embryonic liver nuclei system. The transcription of the hybrid gene is modulated by the addition of an estradiol-receptor preparation that has been shown to bind selectively to an upstream region of cloned vitellogenin gene. Stimulation of the transcription of cloned vitellogenin hybrid gene by estradiol receptor is alpha-amanitin sensitive, hormone dependent, and promoter specific. Simian virus 40 and Escherichia coli promoters are not stimulated by the estradiol-receptor complex. The endogenous silent vitellogenin II gene (wild type) present in the nuclei is not turned on by the addition of estradiol-receptor complex. Deletion or inversion of the DNA sequence where the estradiol-receptor complex binds results in the complete suppression of the in vitro stimulation of transcription by estradiol receptor. Correct initiation of the transcription was demonstrated by primer extension studies of the newly synthesized RNA.

RNA sequence containing hexanucleotide AAUAAA directs efficient mRNA polyadenylation in vitro

To determine whether a specific nucleotide sequence is required to direct polyadenylation of a simian virus 40 early pre-mRNA in a soluble HeLa whole-cell lysate, we constructed a series of rearranged and deleted DNA templates, transcribed them in vitro, and determined whether the resultant RNAs could be polyadenylated when incubated in whole-cell lysate. When a 237-base-pair DNA fragment encoding the 3' end of the simian virus 40 early pre-mRNA was transferred to recombinant plasmids encoding RNAs that were not substrates for polyadenylation, the resultant RNAs could now be polyadenylated efficiently. In one case, the chimeric RNA was polyadenylated even more efficiently than was the original simian virus 40 early transcript. Analysis of the RNAs produced from the deletion mutant templates revealed that only RNAs containing at least one copy of the AAUAAA sequence situated near the 3' end and implicated in 3'-end formation and polyadenylation in vivo could be polyadenylated in vitro. Surprisingly, this sequence directed polyadenylation of pre-mRNAs not only when near the RNA 3' end, i.e., 50 nucleotides or less away, but also when the 3' end was situated over 400 nucleotides downstream. Thus, our results show that a polyadenylic acid polymerase activity in HeLa lysates can recognize a specific nucleotide sequence in pre-mRNA and then, in the absence of the nucleolytic cleavage that presumably occurs in vivo, locate the RNA 3' end and use it as a primer for polyadenylic acid synthesis.

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.

Thyrotropin controls transcription of the thyroglobulin gene

The availability of rat thyroglobulin cDNA clones was exploited to study the regulation of thyroglobulin gene transcription by thyrotropin (TSH). Groups of rats were subjected to treatments leading to reduction or increase in the rat serum TSH (rTSH) levels. Thyroid gland nuclei were isolated, incubated in vitro in the presence of 32P-labeled uridine triphosphate, and thyroglobulin transcripts were quantitated by hybridization to immobilized rat thyroglobulin cDNA clones. Transcription of the thyroglobulin gene was found to be very active in thyroid nuclei from control animals. It represented about 10% of total RNA polymerase II activity. Chronic hyperstimulation of the thyroid glands with endogenous rTSH was achieved in rats treated with the goitrogen propylthiouracil. No significant increase of thyroglobulin gene transcription could be measured in thyroid nuclei from these animals. On the contrary, a dramatic decrease in thyroglobulin gene transcription was observed in those animals in which endogenous rTSH levels had been suppressed by hypophysectomy or by the administration of triiodothyronine. Injection of exogenous bovine TSH in such animals readily restored transcriptional activity of the gene. Our results identify transcription as an important regulatory step involved in TSH action. They suggest that normal TSH levels induce close to maximal expression of the thyroglobulin gene but that continuous presence of TSH is required in order to maintain the gene in an activated state.

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.

High Specificity of the cDNA-RNase Assay to Detect Accurate SplicingIn Vitro

e previously developed a splicing assay (Keohavong et al., 1982) that we designated as a cDNA-RNase assay to analyze the ligation reaction between exons of premessenger RNA during in vivo or in vitro splicing. It was important to determine the specificity of this splicing assay, since the accuracy of in vitro splicing must always be demonstrated clearly. To do this, we constructed DNA probes derived from adenovirus E1A cDNA carrying deletions or insertions of 2-6 bases. After hybridizing them to the wild-type mRNA, the ability of single-strand-specific RNases to detect small mismatches of the RNA-DNA hybrids was examined. The demonstration that an imprecision in the splicing reaction of as little as 2 nucleotides can be detected with an efficiency of 99% indicates the high specificity of the splicing assay and its usefulness for the verification of accurate splicing in in vitro systems.

Splicing pathways of SV40 mRNAs in X. laevis oocytes differ in their requirements for snRNPs

To examine the role of small nuclear ribonucleoproteins (snRNPs) in mRNA splicing, we have injected SV40 DNA, in the presence or absence of anti-Sm or anti-(U1)RNP antibodies, into the nucleus of X. laevis oocytes, and analyzed the viral specific RNAs and proteins that were synthesized. In the absence of antibodies, the majority of the viral mRNAs were spliced, giving rise to transcripts and proteins analogous to those found in infected monkey cells. However, the relative efficiencies with which the various splice sites were utilized were different in the two cell types. When sera from systemic lupus erythematosus (SLE) patients containing anti-Sm or anti-(U1)RNP antibodies were coinjected with the viral DNA, splicing of L-strand-specific (late) mRNA was dramatically inhibited. Cleavage at both 5' and 3' splice sites was blocked, leading to an accumulation of unspliced primary transcripts. Neither the total amount of late RNA synthesized nor the formation of mature polyadenylated late mRNA 3' ends was affected. These results indicate that U1 snRNPs play a crucial role in mRNA splicing in vivo. Unexpectedly, the effects of the sera on E-strand-specific (early) viral mRNA splicing were different. All anti-Sm or -(U1)RNP sera tested had no detectable effect on the splicing of the mRNA coding for the small tumor antigen. A subset of these sera, however, inhibited large tumor antigen mRNA splicing. On the basis of these data it is suggested that different pre-mRNAs, or even different splice sites within the same pre-mRNA, have dissimilar interactions with snRNP particles in the splicing reaction.

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.

Base-specific ribonucleases potentially involved in heterogeneous nuclear RNA processing and poly(A) metabolism

Polyadenylation and splicing of heterogeneous nuclear RNA, two crucial steps in mRNA processing, are apparently enzymatically mediated processes. This contribution summarizes the properties and the presumed functions of the known poly(A) catabolic enzymes (endoribonuclease IV and V, 2',3'- exoribonuclease ) as well as those of the pyrimidine-specific endoribonucleases associated with snRNP -hnRNP complexes (endoribonuclease VII, acidic pI 4.1 endoribonuclease and poly(U)-specific U1 snRNP -nuclease).

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.

Formation of the 3' end of histone mRNA by post-transcriptional processing

The specific 3' termini of a number of eukaryotic mRNAs have been shown to be generated by the post-transcriptional processing of primary transcripts or pre-mRNAs. The sequence AAUAAA, present in the 3' region of nearly all eukaryotic mRNAs, appears to be involved in the cleavage and subsequent polyadenylation of the primary transcript. An exception to this general rule is the case of the histone mRNAs, which lack the AAUAAA sequence and are not normally polyadenylated. Histone mRNAs do, however, contain a highly conserved 23 base pair sequence at their 3' termini, which is required for correct 3' end formation. The similarity between this conserved sequence, which can be drawn as a hairpin loop, and bacterial transcription terminators has led several investigators to suggest that the specific 3' end of histone mRNA is formed by termination of transcription. So far, however, experimental results have not been presented which make it possible to distinguish between a post-transcriptional processing or a transcription termination mechanism for the formation of histone mRNA 3' termini. We have investigated this issue by synthesizing in vitro unprocessed histone pre-mRNAs that extend past the normal 3' terminus. These in vitro synthesized pre-mRNAS were injected into frog oocyte nuclei to study their fate. The results demonstrate that correct 3' ends of chicken histone H2B mRNAs can be formed by RNA processing of longer synthetic pre-mRNAs.

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.

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.