Lack of an effect of the efficiency of RNA 3'-end formation on the efficiency of removal of either the final or the penultimate intron in intact cells

An interaction between U2AF 65 and CF I(m) links the splicing and 3' end processing machineries

The protein factor U2 snRNP Auxiliary Factor (U2AF) 65 is an essential component required for splicing and involved in the coupling of splicing and 3' end processing of vertebrate pre-mRNAs. Here we have addressed the mechanisms by which U2AF 65 stimulates pre-mRNA 3' end processing. We identify an arginine/serine-rich region of U2AF 65 that mediates an interaction with an RS-like alternating charge domain of the 59 kDa subunit of the human cleavage factor I (CF I(m)), an essential 3' processing factor that functions at an early step in the recognition of the 3' end processing signal. Tethered functional analysis shows that the U2AF 65/CF I(m) 59 interaction stimulates in vitro 3' end cleavage and polyadenylation. These results therefore uncover a direct role of the U2AF 65/CF I(m) 59 interaction in the functional coordination of splicing and 3' end processing.

The 3'-end-processing factor CPSF is required for the splicing of single-intron pre-mRNAs in vivo

We describe a new approach to elucidate the role of 3'-end processing in pre-mRNA splicing in vivo using the influenza virus NS1A protein. The effector domain of the NS1A protein, which inhibits the function of the CPSF and PABII factors of the cellular 3'-end-processing machinery, is sufficient for the inhibition of not only 3'-end formation but also the splicing of single-intron pre-mRNAs in vivo. We demonstrate that inhibition of the splicing of single-intron pre-mRNAs results from inhibition of 3'-end processing, thereby establishing that 3'-end processing is required for the splicing of a 3' terminal intron in vivo. Because the NS1A protein causes a global suppression of 3'-end processing in trans, we avoid the ambiguities caused by the activation of cryptic poly(A) sites that occurs when mutations are introduced into the AAUAAA sequence in the pre-mRNA. In addition, this strategy enabled us to establish that the function of a particular 3'-end-processing factor, namely CPSF, is required for the splicing of single-intron pre-mRNAs in vivo: splicing is inhibited only when the effector domain of the NS1A protein binds and inhibits the function of the 30-kDa CPSF protein in 3'-end formation. In contrast, the 3'-end processing factor PABII is not required for splicing. We discuss the implications of these results for cellular and influenza viral mRNA splicing.

Mammalian heat shock p70 and histone H4 transcripts, which derive from naturally intronless genes, are immune to nonsense-mediated decay

Nonsense-mediated decay (NMD), also called mRNA surveillance, is an evolutionarily conserved pathway that degrades mRNAs that prematurely terminate translation. To date, the pathway in mammalian cells has been shown to depend on the presence of a cis-acting destabilizing element that usually consists of an exon-exon junction generated by the process of pre-mRNA splicing. Whether or not mRNAs that derive from naturally intronless genes, that is, mRNAs not formed by the process of splicing, are also subject to NMD has yet to be investigated. The possibility of NMD is certainly reasonable considering that mRNAs of Saccharomyces cerevisiae are subject to NMD even though most derive from naturally intronless genes. In fact, mRNAs of S. cerevisiae generally harbor a loosely defined splicing-independent destabilizing element that has been proposed to function in NMD analogously to the spliced exon-exon junction of mammalian mRNAs. Here, we demonstrate that nonsense codons introduced into naturally intronless genes encoding mouse heat shock protein 70 or human histone H4 fail to elicit NMD. Failure is most likely because each mRNA lacks a cis-acting destabilizing element, because insertion of a spliceable intron a sufficient distance downstream of a nonsense codon within either gene is sufficient to elicit NMD.

Nominal growth hormone pulses in otherwise normal masculine plasma profiles induce intron retention of overexpressed hepatic CYP2C11 with associated nuclear splicing deficiency

Restoration of circulating masculine GH profiles at minipulse amplitudes (i.e. approximately 10% of normal) to hypophysectomized male rats and neonatal administration of monosodium glutamate (MSG), producing a similar plasma GH profile, both result in an overexpression (approximately 200-300%) of CYP2C11 messenger RNA (mRNA), the predominant hepatic cytochrome P450 (CYP) drug-metabolizing enzyme in adult male rats. Coincident with the severalfold elevation in transcript level is a modest 10-30% overexpression of CYP2C11 protein and its catalytic activities. Using hepatic tissue from adult, neonatally MSG-treated rats, we have cloned a variant species of CYP2C11 mRNA containing all of the essential elements of a full-length complementary DNA, including initiating codon, termination codon, and polyadenylase tail. In addition, the transcript contains a 742-bp intervening sequence (identical to the complete terminal intron) between the last and penultimate exons, and an intron-specific oligo probe for Northern blotting demonstrates the presence of the variant transcript in liver of MSG-treated rats. Associated with the overexpression and intron retention of the transcript is a 50% reduction in the nuclear splicing capacity of the liver for model precursor CYP2C11 mRNA. It is proposed that this splicing defect may be a consequence of the mini-GH pulses (secreted in otherwise normal masculine plasma profiles) signaling abnormal processing of precursor CYP2C11 mRNA to produce a substantial portion of intron retained, nontranslatable transcript.

The carboxyl terminus of vertebrate poly(A) polymerase interacts with U2AF 65 to couple 3'-end processing and splicing

Although it has been established that the processing factors involved in pre-mRNA splicing and 3'-end formation can influence each other positively, the molecular basis of this coupling interaction was not known. Stimulation of pre-mRNA splicing by an adjacent cis-linked cleavage and polyadenylation site in HeLa cell nuclear extract is shown to occur at an early step in splicing, the binding of U2AF 65 to the pyrimidine tract of the intron 3' splice site. The carboxyl terminus of poly(A) polymerase (PAP) previously has been implicated indirectly in the coupling process. We demonstrate that a fusion protein containing the 20 carboxy-terminal amino acids of PAP, when tethered downstream of an intron, increases splicing efficiency and, like the entire 3'-end formation machinery, stimulates U2AF 65 binding to the intron. The carboxy-terminal domain of PAP makes a direct and specific interaction with residues 17-47 of U2AF 65, implicating this interaction in the coupling of splicing and 3'-end formation.

The carboxyl terminus of vertebrate poly(A) polymerase interacts with U2AF 65 to couple 3′-end processing and splicing

Although it has been established that the processing factors involved in pre-mRNA splicing and 3′-end formation can influence each other positively, the molecular basis of this coupling interaction was not known. Stimulation of pre-mRNA splicing by an adjacentcis-linked cleavage and polyadenylation site in HeLa cell nuclear extract is shown to occur at an early step in splicing, the binding of U2AF 65 to the pyrimidine tract of the intron 3′ splice site. The carboxyl terminus of poly(A) polymerase (PAP) previously has been implicated indirectly in the coupling process. We demonstrate that a fusion protein containing the 20 carboxy-terminal amino acids of PAP, when tethered downstream of an intron, increases splicing efficiency and, like the entire 3′-end formation machinery, stimulates U2AF 65 binding to the intron. The carboxy-terminal domain of PAP makes a direct and specific interaction with residues 17–47 of U2AF 65, implicating this interaction in the coupling of splicing and 3′-end formation.

Effect of differential polyadenylation and cell growth phase on dihydrofolate reductase mRNA stability

We have constructed tetracycline-responsive dhfr minigenes and transferred them to a Chinese hamster ovary cell DHFR-deficient deletion mutant to obtained cells in which dhfr transcription can be repressed by tetracycline (tet-off). DHFR mRNA half-life measured after the repression of transcription by tetracycline in these transfectants is about 1.5 h, which is significantly shorter than previously reported. In addition, we observed that DHFR mRNA is less stable in serum-starved cells than in exponentially growing cells. Given that the dhfr gene contains multiple polyadenylation sites, we analyzed the role of polyadenylation site usage on the stability of the resultant mRNA molecules. We found that DHFR mRNA is more stable when a strong polyadenylation site is used. Finally, we have observed that the relative lengths of the poly(A) tails for the different DHFR mRNA species correlated with their relative stability in growing versus resting cells.

How a circadian clock adapts to seasonal decreases in temperature and day length

We show that a thermosensitive splicing event in the 3' untranslated region of the mRNA from the period (per) gene plays an important role in how a circadian clock in Drosophila adapts to seasonally cold days (low temperatures and short day lengths). The enhanced splicing of this intron at low temperatures advances the steady state phases of the per mRNA and protein cycles, events that significantly contribute to the preferential daytime activity of flies on cold days. Because the accumulation of PER is also dependent on the photosensitive TIMELESS (TIM) protein, long photoperiods partially counteract the cold-induced advances in the oscillatory mechanism by delaying the daily increases in the levels of TIM. Our findings also indicate that there is a temperature-dependent switch in the molecular logic governing cycles in per mRNA levels.

Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis

Formation of mRNA 3' ends in eukaryotes requires the interaction of transacting factors with cis-acting signal elements on the RNA precursor by two distinct mechanisms, one for the cleavage of most replication-dependent histone transcripts and the other for cleavage and polyadenylation of the majority of eukaryotic mRNAs. Most of the basic factors have now been identified, as well as some of the key protein-protein and RNA-protein interactions. This processing can be regulated by changing the levels or activity of basic factors or by using activators and repressors, many of which are components of the splicing machinery. These regulatory mechanisms act during differentiation, progression through the cell cycle, or viral infections. Recent findings suggest that the association of cleavage/polyadenylation factors with the transcriptional complex via the carboxyl-terminal domain of the RNA polymerase II (Pol II) large subunit is the means by which the cell restricts polyadenylation to Pol II transcripts. The processing of 3' ends is also important for transcription termination downstream of cleavage sites and for assembly of an export-competent mRNA. The progress of the last few years points to a remarkable coordination and cooperativity in the steps leading to the appearance of translatable mRNA in the cytoplasm.

Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis

Formation of mRNA 3' ends in eukaryotes requires the interaction of transacting factors with cis-acting signal elements on the RNA precursor by two distinct mechanisms, one for the cleavage of most replication-dependent histone transcripts and the other for cleavage and polyadenylation of the majority of eukaryotic mRNAs. Most of the basic factors have now been identified, as well as some of the key protein-protein and RNA-protein interactions. This processing can be regulated by changing the levels or activity of basic factors or by using activators and repressors, many of which are components of the splicing machinery. These regulatory mechanisms act during differentiation, progression through the cell cycle, or viral infections. Recent findings suggest that the association of cleavage/polyadenylation factors with the transcriptional complex via the carboxyl-terminal domain of the RNA polymerase II (Pol II) large subunit is the means by which the cell restricts polyadenylation to Pol II transcripts. The processing of 3' ends is also important for transcription termination downstream of cleavage sites and for assembly of an export-competent mRNA. The progress of the last few years points to a remarkable coordination and cooperativity in the steps leading to the appearance of translatable mRNA in the cytoplasm.

Identification of two cis-acting elements that independently regulate the length of poly(A) on Xenopus albumin pre-mRNA

Unlike most eukaryotic mRNAs studied to date, Xenopus serum albumin mRNA has a short (17-residue), discrete poly(A) tail. We recently reported that this short poly(A) tail results from regulation of the length of poly(A) on albumin pre-mRNA. The purpose of the present study was to locate the cis-acting element responsible for this, the poly(A)-limiting element or PLE. An albumin minigene consisting of albumin cDNA joined in exon 13 to the 3' end of the albumin gene produced mRNA with <20 nt poly(A) when transfected into mouse fibroblasts. This result indicates both that cis-acting sequences that regulate poly(A) length are within this construct, and that nuclear regulation of poly(A) length is conserved between vertebrates. Poly(A) length regulation was retained after replacing the terminal 53 bp and 3' flanking region of the albumin gene with a synthetic polyadenylation element (SPA). Conversely, fusing albumin gene sequence spanning the terminal 53 bp of the albumin gene and 3' flanking sequence onto the human beta-globin gene yielded globin mRNA with a 200-residue poly(A)tail. These data indicate that the PLE resides upstream of the sequence elements involved in albumin pre-mRNA 3' processing. Poly(A) length regulation was restored upon fusing a segment bearing albumin intron 14, exon 15, and 3' flanking sequence onto the beta-globin gene. We demonstrate that exon 15 contains two PLEs that can act independently to regulate the length of poly(A).

Efficient 3'-end formation of human beta-globin mRNA in vivo requires sequences within the last intron but occurs independently of the splicing reaction

The second intron (betaIVS-II) of the human beta-globin gene is essential for the accumulation of stable cytoplasmic mRNA and is implicated in promoting efficient 3'-end formation. This report presents quantitative comparisons between betaIVS-II mutants at physiological levels of expression from within a natural chromatin context in vivo which further defines it's function. In marked contrast to a beta-globin gene lacking a second intron, two mutants defective in splicing (small size or a splice donor mutation), still undergo essentially normal levels of 3'-end formation and in the absence of exon skipping. Therefore, 3' cleavage of beta-globin transcripts requires the presence of betaIVS-II sequences, but not the splicing reaction. The placement of betaIVS-II in the IVS-I position did not reduce the efficiency of 3' cleavage indicating that the distance between the necessary element(s) in this intron and the polyadenylation recognition site is not a crucial factor. Subsequent placement of betaIVS-I in the intron II position, reduced the efficiency of 3'-end formation to only 16% of normal. A direct replacement of intron II by the heterologous introns betaIVS-I or alpha-globin IVS-II, only partially substitute (16 and 30% respectively) for betaIVS-II. Hybrid introns show that efficient 3'-end formation is strongly enhanced by the presence of the terminal 60 nt of betaIVS-II. These data imply that the last intervening sequence of multiple intron containing genes is a principal determinant of the efficiency of 3'-end formation and may act as a post-transcriptional regulatory step in gene expression.

Splicing factors associate with nuclear HCMV-IE transcripts after transcriptional activation of the gene, but dissociate upon transcription inhibition: evidence for a dynamic organization of splicing factors

Before being transported to the cytoplasm, intron-containing pre-mRNAs have to be spliced somewhere in the cell nucleus. Efficient splicing requires an ordered assembly of splicing factors onto the pre-mRNAs. To accomplish this, intron containing genes may be preferentially localized at nuclear sites enriched for splicing factors or alternatively, splicing factors may circulate throughout the nucleus and have the ability to associate with randomly positioned nascent transcripts. Combined detection of HCMV-IE mRNA/DNA and splicing factors in rat 9G cells that can be induced for IE gene expression shows that IE genes are not associated with speckled regions enriched for splicing factors when transcriptionally inactive, but ‘attract’ splicing factors when transcriptionally activated. This process proved reversible after transcription inhibition. IE transcripts appeared to be retained near the transcription site in track-like domains by splicing factors associated with them until splicing has been completed. Double-hybridization experiments revealed that a substantial part of the accumulated transcripts contain a poly(A) tail suggesting that most, if not all, IE transcripts are polyadenylated at the site of transcription. These results indicate that RNA processing may occur independent of the position of the gene in the cell nucleus relative to speckle domains.

Regulated nuclear polyadenylation of Xenopus albumin pre-mRNA

Cytoplasmic regulation of the length of poly(A) on mRNA is a well-characterized process involved in translational control during development. In contrast, there is no direct in vivo evidence for regulation of the length of poly(A) added during nuclear pre-mRNA processing in somatic cells. We previously reported that Xenopus serum albumin [Schoenberg et al. (1989) Mol. Endocrinol. 3, 805-815] and transferrin [Pastori et al. (1992) J. Steroid Biochem. Mol. Biol. 42, 649-657], mRNA have exceptionally short poly(A) tails ranging from 12 to 17 residues, whereas vitellogenin mRNA has long poly(A). An RT-PCR protocol was adapted to determine the length of poly(A) added onto pre-mRNA, defined here as that species bearing the terminal intron. Using this assay we show that vitellogenin pre-mRNA has the same long poly(A) tail as mature vitellogenin mRNA. In contrast, albumin pre-mRNA has the same short poly(A) as found on fully-processed albumin mRNA. These results indicate that the short poly(A) tail on albumin mRNA results from regulation of poly(A) addition during nuclear 3' processing.

3' Processing and termination of mouse histone transcripts synthesized in vitro by RNA polymerase II

The highly expressed mouse histone H2a-614 gene is located 800 nt 5' of the histone H3-614 gene. There is a 140 nt sequence located 500 nt from the end of the H2-614 mRNA which has been defined as a transcription termination site for RNA polymerase II. We established an in vitro transcription system in which both 3' end processing and transcription termination occur. A template containing the adenovirus major late promoter, a portion of the histone H2a-614 coding region, its 3' processing signal, followed by the transcription termination site was transcribed in a nuclear extract prepared from mouse myeloma cells. Some of the transcripts synthesized in the extract were cleaved at the histone processing site in a reaction which was dependent both on the hairpin binding factor and the U7 snRNP. The efficiency of histone 3' end formation was similar both on synthetic transcripts and transcripts synthesized by RNA polymerase II. Defined transcripts, which were not processed and which mapped to the transcription termination site, were released from the template, suggesting that they were formed by transcription termination. Termination in vitro was dependent on a functional histone processing signal.

A nuclear cap-binding complex facilitates association of U1 snRNP with the cap-proximal 5' splice site

The mechanism by which intron-containing RNAs are recognized by the splicing machinery is only partly understood. A nuclear cap-binding complex (CBC), which specifically recognizes the monomethyl guanosine cap structure carried by RNA polymerase II transcripts, has previously been shown to play a role in pre-mRNA splicing. Using a combination of splicing complex and psoralen cross-linking analysis we demonstrate that CBC is required for efficient recognition of the 5' splice site by U1 snRNP during formation of E (early) complex on a pre-mRNA containing a single intron. However, in a pre-mRNA containing two introns, CBC is not required for splicing of the cap distal intron. In this case, the presence of an intact polypyrimidine tract in the cap-proximal intron renders splicing of the cap-distal intron independent of CBC. These results support models in which the splice sites in a pre-mRNA are originally recognized by interactions spanning exons. The defects in splicing and U1 snRNP binding caused by CBC depletion can be specifically reversed by recombinant CBC. In summary, efficient recognition of the cap-proximal 5' splice site by U1 snRNP is facilitated by CBC in what may be one of the earliest steps in pre-mRNA recognition. Data in Colot et al. (this issue) indicate that this function of CBC is conserved in humans and yeast.

Evidence that the decay of nucleus-associated nonsense mRNA for human triosephosphate isomerase involves nonsense codon recognition after splicing

For most of the mammalian mRNAs that have been shown to be reduced in abundance by a nonsense or a frameshift mutation that generates a nonsense codon, reduction takes place while the mRNA is nucleus-associated rather than after the mRNA has been exported to the cytoplasm (reviewed in Maquat LE, 1995, RNA 1:453-465). A variety of mechanisms have been put forth to explain how a nonsense codon could affect the abundance of nuclear mRNA. Some mechanisms have implicated nonsense codon recognition in the nucleus prior to splicing. Among the best-studied nonsense transcripts that manifest nonsense-mediated alterations in nucleus-associated metabolism are those that derive from human alleles for the glycolytic enzyme triosephosphate isomerase (TPI). Nonsense codons within TPI transcripts have been shown to reduce the half-life of completely spliced TPI (mRNA that co-purifies with nuclei (Belgrader P et al., 1994, Mol Cell Biol 14:8219-8228). However, whether or not nonsense codon recognition within TPI transcripts takes place prior to or after splicing remained unresolved. To address this issue, codons that span two exons, i.e., are disrupted by an intron prior to pre-mRNA splicing, were converted to nonsense. If nonsense codon recognition were to precede splicing, then the disrupting intron would be expected to preclude nonsense codon recognition by preventing the physical juxtapositioning of the codon nucleotides. In the absence of nonsense codon recognition, there would be no nonsense-mediated reduction in TPI mRNA abundance. The results of northern (RNA) blot hybridization demonstrated that the two nonsense codons of this type that were studied reduced the level of total, nuclear and cytoplasmic TPI mRNA to an average of 12% of normal, consistent with each nonsense codon being competent to mediate nuclear mRNA degradation. The possibility that the nonsense codons reduced TPI mRNA abundance by altering TPI mRNA abundance or splicing was eliminated by using RT-PCR to demonstrate that the level of each intron within pre-mRNA was essentially unaffected and cDNA sequencing to demonstrate that splice site choice was unaltered. Furthermore, missense codons that harbored some of the nonsense codon changes were found to have little effect on mRNA abundance. These findings, plus the previous finding that a suppressor tRNA abrogates the decay of TPI mRNA brought about by a nonsense codon residing within a single exon (Belgrader P, Cheng J, Maquat LE, 1993, Proc Natl Acad Sci USA 90:482-486), argue strongly that nonsense codon recognition in the nonsense-mediated decay of TPI mRNA takes place after splicing.