Alternative branch points are selected during splicing of a yeast pre-mRNA in mammalian and yeast extracts

Splicing regulation at the second catalytic step by Sex-lethal involves 3' splice site recognition by SPF45

The Drosophila protein Sex-lethal (SXL) promotes skipping of exon 3 from its own pre-mRNA. An unusual sequence arrangement of two AG dinucleotides and an intervening polypyrimidine (Py)-tract at the 3' end of intron 2 is important for Sxl autoregulation. Here we show that U2AF interacts with the Py-tract and downstream AG, whereas the spliceosomal protein SPF45 interacts with the upstream AG and activates it for the second catalytic step of the splicing reaction. SPF45 represents a new class of second step factors, and its interaction with SXL blocks splicing at the second step. These results are in contrast with other known mechanisms of splicing regulation, which target early events of spliceosome assembly. A similar role for SPF45 is demonstrated in the activation of a cryptic 3' ss generated by a mutation that causes human beta-thalassemia.

Crystal structure of a model branchpoint-U2 snRNA duplex containing bulged adenosines

Bulged nucleotides play a variety of important roles in RNA structure and function, frequently forming tertiary interactions and sometimes even participating in RNA catalysis. In pre-mRNA splicing, the U2 snRNA base pairs with the intron branchpoint sequence (BPS) to form a short RNA duplex that contains a bulged adenosine that ultimately serves as the nucleophile that attacks the 5' splice site. We have determined a 2.18-A resolution crystal structure of a self-complementary RNA designed to mimic the highly conserved yeast (Saccharomyces cerevisiae) branchpoint sequence (5'-UACUAACGUAGUA with the BPS italicized and the branchsite adenosine underlined) base paired with its complementary sequence from U2 snRNA. The structure shows a nearly ideal A-form helix from which two unpaired adenosines flip out. Although the adenosine adjacent to the branchsite adenosine is the one bulged out in the structure described here, either of these adenosines can serve as the nucleophile in mammalian but not in yeast pre-mRNA splicing. In addition, the packing of the bulged RNA helices within the crystal reveals a novel RNA tertiary interaction in which three RNA helices interact through bulged adenosines in the absence of any divalent metal ions.

Identification of a plant serine-arginine-rich protein similar to the mammalian splicing factor SF2/ASF

We show that the higher plant Arabidopsis thaliana has a serine-arginine-rich (SR) protein family whose members contain a phosphoepitope shared by the animal SR family of splicing factors. In addition, we report the cloning and characterization of a cDNA encoding a higher-plant SR protein from Arabidopsis, SR1, which has striking sequence and structural homology to the human splicing factor SF2/ASF. Similar to SF2/ASF, the plant SR1 protein promotes splice site switching in mammalian nuclear extracts. A novel feature of the Arabidopsis SR protein is a C-terminal domain containing a high concentration of proline, serine, and lysine residues (PSK domain), a composition reminiscent of histones. This domain includes a putative phosphorylation site for the mitotic kinase cyclin/p34cdc2.

Small sequence insertions within the branch point region dictate alternative sites of lariat formation in a yeast intron

The problem of intron recognition in S. cerevisiae appears to be in part solved by the strong conservation of intron encoded splicing signals, in particular the 5' GUAUGU and the branch point UACUAAC which interact via base pairing with the RNA components of U1 and U2 snRNPs respectively. Nevertheless, the mere presence of such signals is insufficient for splicing to occur. In the S. cerevisiae ACT1 intron, a silent UACUAAC-like sequence (UACUAAG) is located 7 nucleotides upstream of the canonical branch point signal. In order to investigate whether other factors, in addition to the U2-UACUAAC base-pair interactions, affect branch point selection in yeast, we created a cis-competition assay by converting the UACUAAG to a strong branch point signal (UACUAAC). If simply having a canonical UACUAAC sequence were sufficient for lariat formation, a 1:1 ratio in usage of the two signals should have been observed. In this double branch point intron, however, the downstream UACUAAC is utilized preferentially (4:1). Results obtained from the analyses of numerous sequence variants flanking the two UACUAAC sequences, demonstrate that non-conserved sequences in the branch point region are able to define lariat formation. Consequently, we conclude that U2 base-pairing is not the only requirement determining branch point selection in yeast, and local structure in the vicinity of the branch point could play a critical role in its recognition.

PRP38 encodes a yeast protein required for pre-mRNA splicing and maintenance of stable U6 small nuclear RNA levels

An essential pre-mRNA splicing factor, the product of the PRP38 gene, has been genetically identified in a screen of temperature-sensitive mutants of Saccharomyces cerevisiae. Shifting temperature-sensitive prp38 cultures from 23 to 37 degrees C prevents the first cleavage-ligation event in the excision of introns from mRNA precursors. In vitro splicing inactivation and complementation studies suggest that the PRP38-encoded factor functions, at least in part, after stable splicing complex formation. The PRP38 locus contains a 726-bp open reading frame coding for an acidic 28-kDa polypeptide (PRP38). While PRP38 lacks obvious structural similarity to previously defined splicing factors, heat inactivation of PRP38, PRP19, or any of the known U6 (or U4/U6) small nuclear ribonucleoprotein-associating proteins (i.e., PRP3, PRP4, PRP6, and PRP24) leads to a common, unexpected consequence: intracellular U6 small nuclear RNA (snRNA) levels decrease as splicing activity is lost. Curiously, U4 snRNA, normally extensively base paired with U6 snRNA, persists in the virtual absence of U6 snRNA.

PRP38 encodes a yeast protein required for pre-mRNA splicing and maintenance of stable U6 small nuclear RNA levels

An essential pre-mRNA splicing factor, the product of the PRP38 gene, has been genetically identified in a screen of temperature-sensitive mutants of Saccharomyces cerevisiae. Shifting temperature-sensitive prp38 cultures from 23 to 37 degrees C prevents the first cleavage-ligation event in the excision of introns from mRNA precursors. In vitro splicing inactivation and complementation studies suggest that the PRP38-encoded factor functions, at least in part, after stable splicing complex formation. The PRP38 locus contains a 726-bp open reading frame coding for an acidic 28-kDa polypeptide (PRP38). While PRP38 lacks obvious structural similarity to previously defined splicing factors, heat inactivation of PRP38, PRP19, or any of the known U6 (or U4/U6) small nuclear ribonucleoprotein-associating proteins (i.e., PRP3, PRP4, PRP6, and PRP24) leads to a common, unexpected consequence: intracellular U6 small nuclear RNA (snRNA) levels decrease as splicing activity is lost. Curiously, U4 snRNA, normally extensively base paired with U6 snRNA, persists in the virtual absence of U6 snRNA.

The xylanase introns from Cryptococcus albidus are accurately spliced in transgenic tobacco plants

The xylanase gene from Cryptococcus albidus contains seven introns. Genomic and cDNA clones under the control of the CaMV 35S promoter were transferred into tobacco plants using Agrobacterium-mediated cell transformation. The genes were transcribed and the mRNAs were amplified by the polymerase chain reaction using primers on each side of the intron region. About 90% of the amplification products from plants transformed with the genomic clone corresponded to the size of the pre-mRNA (1.2 kb) and 10% represented the spliced product (0.85 kb). The 0.85 kb fragment was cloned and sequenced and the result indicated that the introns from the xylanase gene were accurately spliced by the plant cells.

Limited functional equivalence of phylogenetic variation in small nuclear RNA: yeast U2 RNA with altered branchpoint complementarity inhibits splicing and produces a dominant lethal phenotype

U2 is a highly conserved small nuclear RNA essential for pre-mRNA splicing in mammals and yeast and for trans-splicing in trypanosomes. To test the function of variant U2 RNA structures from different organisms, we conducted phylogenetic exchanges of U2 domains. Replacing nucleotides 1-120 of yeast U2 with the corresponding region of human U2 generates a U2 RNA that is correctly folded and functions in yeast. In contrast, replacement of the branchpoint interaction region of yeast U2 with the corresponding region from trypanosome is dominant lethal. Using a GAL-U2 promoter fusion, we show that the dominant phenotype can be made conditional and that the accumulation of mutant U2 is followed rapidly by inhibition of nuclear pre-mRNA splicing. The results suggest that U2 small nuclear ribonucleoprotein particles normally participate in stable complexes with a limiting splicing factor prior to formation of U2-intron branchpoint base pairs.

Exon as well as intron sequences are cis-regulating elements for the mutually exclusive alternative splicing of the beta tropomyosin gene

The beta tropomyosin gene contains two internal exons which are spliced in a mutually exclusive manner. Exon 6B is specifically included in the mature transcripts expressed in skeletal muscle or cultured myotubes, while exon 6A is a myoblast- or smooth muscle-specific exon. The intron between them, which is never spliced in normal conditions, contains two characteristic features: first, the unusual location of the branch point at position -105 from the acceptor, and second, the presence of a very long pyrimidine stretch upstream of the skeletal muscle exon. In this study we designed a number of sequence modifications to investigate the role of these two elements and of a computer-predicted secondary structure in the mutually exclusive splicing of the two exons. We found that mutations in the skeletal exon as well as in the upstream intron could change in vivo the tissue-specific pattern as well as the mutually exclusive character of the two exons. Our results suggest that the unusual position of the branch point does not prevent the utilization of exon 6B in myoblasts and that the region around the acceptor site of exon 6B and the polypyrimidine tract have an important role in this control. Last, we discuss the possible implications of secondary structures.

Exon as well as intron sequences are cis-regulating elements for the mutually exclusive alternative splicing of the beta tropomyosin gene

The beta tropomyosin gene contains two internal exons which are spliced in a mutually exclusive manner. Exon 6B is specifically included in the mature transcripts expressed in skeletal muscle or cultured myotubes, while exon 6A is a myoblast- or smooth muscle-specific exon. The intron between them, which is never spliced in normal conditions, contains two characteristic features: first, the unusual location of the branch point at position -105 from the acceptor, and second, the presence of a very long pyrimidine stretch upstream of the skeletal muscle exon. In this study we designed a number of sequence modifications to investigate the role of these two elements and of a computer-predicted secondary structure in the mutually exclusive splicing of the two exons. We found that mutations in the skeletal exon as well as in the upstream intron could change in vivo the tissue-specific pattern as well as the mutually exclusive character of the two exons. Our results suggest that the unusual position of the branch point does not prevent the utilization of exon 6B in myoblasts and that the region around the acceptor site of exon 6B and the polypyrimidine tract have an important role in this control. Last, we discuss the possible implications of secondary structures.

Nuclear pre-mRNA introns: analysis and comparison of intron sequences from Tetrahymena thermophila and other eukaryotes

We have sequenced 14 introns from the ciliate Tetrahymena thermophila and include these in an analysis of the 27 intron sequences available from seven T. thermophila protein-encoding genes. Consensus 5' and 3' splice junctions were determined and found to resemble the junctions of other nuclear pre-mRNA introns. Unique features are noted and discussed. Overall the introns have a mean A + T content of 85% (21% higher than neighbouring exons) with smaller introns tending towards a higher A + T content. Approximately half of the introns are less than 100 bp. Introns from other organisms (approximately 30 of each) were also examined. The introns of Dictyostelium discoideum, Caenorhabditis elegans and Drosophila melanogaster, like those of T. thermophila, have a much higher mean A + T content than their neighbouring exons (greater than 20%). Introns from plants, Neurospora crassa and Schizosaccharomyces pombe also have a significantly higher A + T content (10%-20%). Since a high A + T content is required for intron splicing in plants (58), the elevated A + T content in the introns of these other organisms may also be functionally significant. The introns of yeast (Saccharomyces cerevisiae) and mammals (humans) appear to lack this trait and thus in some aspects may be atypical. The polypyrimidine tract, so distinctive of vertebrate introns, is not a trait of the introns in the non-vertebrate organisms examined in this study.

Correct splicing of modified introns of a Rhizopus proteinase gene in Saccharomyces cerevisiae

The intron of the Rhizopus aspartic proteinase gene (RNAP-I) was modified by in vitro mutagenesis and examined for its splicing efficiency in Saccharomyces cerevisiae. The wild-type intron of the RNAP-I gene was not spliced at all in spite of its structural similarity to introns of S. cerevisiae. The primary transcript of the RNAP-I gene was converted to correctly translatable mRNA only when the complete consensus sequence of S. cerevisiae introns (i.e. 5'-GTATGT-----TACTAAC-----TAG-3') was introduced into its intron, although the efficiency of splicing was low. It is also shown that transformants carrying the RNAP-I gene with the complete consensus sequence of S. cerevisiae introns produce active RNAP-I protein.

Interplay between U2 snRNP and 3' splice factor(s) for branch point selection on human beta-globin pre-mRNA

We investigated the interaction of U2 snRNP with the branch-3' splice site region of three human beta-globin pre-mRNAs carrying nearly complete (BamHI RNA), 24 nt (Avall RNA) and 14 nt (Accl RNA) of exon 2. All supported splicing, but mRNAs yields were respectively 2 and 10 times lower for Avall and Accl RNAs than for BamHI. Analysis of RNase T1-resistant fragments immunoprecipitated by an anti-(U2)RNP antibody at early times of the splicing reaction showed that the protection encompasses both the branch point region and the end of the intron in BamHI and Avall, but essentially only the branch point in Accl RNAs. Later on, this protection becomes less detectable in BamHI, is reinforced in Avall and remains poorly detectable in Accl RNAs. Similar experiments performed at late times with an anti-Sm antibody recognizing all snRNPs showed that the end of the intron is protected in all but BamHI RNAs. These results support the conclusion that U2 snRNP binds to a fully efficient precursor (BamHI RNA) through another factor(s) recognizing the 3' splice site (U5 snRNP and the so-called U2AF protein are likely candidates). Either the absence of an initial contact between U2 snRNP and the factor(s) recognizing the end of the intron (Accl RNA) or the unability of this ternary complex to undergo a conformational change (Avall RNA) could render these severely truncated precursors poor substrates. These different situations have consequences on the branch point selection itself. BamHI and Avall RNAs use three functional branch points at early times, the usual A residue at -37 and two U residues at -17 and -22. Accl RNA uses only one branch point at -37. Later on, all three branch points are used at the same rate in Avall, while the usual one prevails in BamHI RNAs.

Mammalian U2 snRNP has a sequence-specific RNA-binding activity

The RNA branch formed during pre-mRNA splicing occurs at a wide variety of sequences (branch sites) in different mammalian pre-mRNAs. U2 small nuclear ribonucleoprotein (snRNP) binds to the pre-mRNA branch site following the interaction of a protein, U2AF, with the 3' splice site/polypyrimidine tract. Here we show that despite the variability of mammalian branch sites, U2 snRNP has a sequence-specific RNA-binding activity. Thus, RNA branch formation is regulated by two sequence-specific interactions: U2AF with the 3' splice site/polypyrimidine tract, and U2 snRNP with the branch site. The affinity of the branch site for U2 snRNP affects the efficiency of spliceosome assembly and splicing.

Inhibition of eukaryotic translation by nucleoside 5'-monophosphate analogues of mRNA 5'-cap: changes in N7 substituent affect analogue activity

Nucleotide cap analogues of 7-methylguanosine 5'-monophosphate (m7GMP) were synthesized in which the 7-methyl moiety was replaced with 7-ethyl (e7), 7-propyl (p7), 7-isopropyl (ip7), 7-butyl (b7), 7-isobutyl (ib7), 7-cyclopentyl (cp7), 7-(carboxymethyl) (cm7), 7-benzyl (bn7), 7-(2-phenylethyl) [7-(2-PhEt)], and 7-(1-phenylethyl) [7-(1-PhEt)]. These derivatives were assayed as competitive inhibitors of capped mRNA translation in reticulocyte lysate. We observed that N7 alkyl and alicyclic substituents larger than ethyl significantly decreased the inhibitory activity of these cap analogues presumably by decreasing their affinity for cap binding proteins, which participate in the initiation of translation. This result defined a maximum size for this class of N7 substituents in the nucleotide binding domain of cap binding proteins. Like m7GMP, the N7-substituted GMP derivatives synthesized in this study were found to be predominantly in the anti conformation as determined by proton NMR analyses. However, bn7GMP and 7-(2-PhEt)GMP, which have aromatic N7 substituents, were more effective than m7GMP as competitive inhibitors of translation. The increased affinity of bn7GMP for cap binding proteins was further examined by synthesis of beta-globin mRNA containing 5'-bn7G, 5'-m7G, or 5'-e7G cap structures. These modified mRNAs were tested as translation templates. Messenger RNA capped with bn7G was observed to increase the translation activity of the template 1.8-fold relative to that of its m7G-capped mRNA counterpart. By contrast, e7G-capped mRNA was 25% less active than m7G-capped mRNA.2+V photo-cross-linking of m7G-capped mRNA to cap binding proteins

The 5' splice site: phylogenetic evolution and variable geometry of association with U1RNA

The 5' splice site sequences of 3294 introns from various organisms (1-672) were analyzed in order to determine the rules governing evolution of this sequence, which may shed light on the mechanism of cleavage at the exon-intron junction. The data indicate that, currently, in all organisms, a common sequence 1GUAAG6U and its derivatives are used as well as an additional sequence and its derivatives, which differ in metazoa (G/1GUgAG6U), lower eucaryotes (1GUAxG6U) and higher plants (AG/1GU3A). They all partly resemble the prototype sequence AG/1GUAAG6U whose 8 contigous nucleotides are complementary to the nucleotides 4-11 of U1RNA, which are perfectly conserved in the course of phylogenetic evolution. Detailed examination of the data shows that U1RNA can recognize different parts of 5' splice sites. As a rule, either prototype nucleotides at position -2 and -1 or at positions 4, 5 or 6 or at positions 3-4 are dispensable provided that the stability of the U1RNA-5' splice site hybrid is conserved. On the basis of frequency of sequences, the optimal size of the hybridizable region is 5-7 nucleotides. Thus, the cleavage at the exon-intron junction seems to imply, first, that the 5' splice site is recognized by U1RNA according to a "variable geometry" program; second, that the precise cleavage site is determined by the conserved sequence of U1RNA since it occurs exactly opposite to the junction between nucleotides C9 and C10 of U1RNA. The variable geometry of the U1RNA-5' splice site association provides flexibility to the system and allows diversification in the course of phylogenetic evolution.

Nuclear pre-mRNA processing in plants: distinct modes of 3'-splice-site selection in plants and animals

The report that human growth hormone pre-mRNA is not processed in transgenic plant tissues (A. Barta, K. Sommergruber, D. Thompson, K. Hartmuth, M.A. Matzke, and A.J.M. Matzke, Plant Mol. Biol. 6:347-357, 1986) has suggested that differences in mRNA splicing processes exist between plants and animals. To gain more information about the specificity of plant pre-mRNA processing, we have compared the splicing of the soybean leghemoglobin pre-mRNA with that of the human beta-globin pre-mRNA in transfected plant (Orychophragmus violaceus and Nicotiana tabacum) protoplasts and mammalian (HeLa) cells. Of the three introns of leghemoglobin pre-mRNA, only intron 2 was correctly and efficiently processed in HeLa cells. The 5' splice sites of the remaining two introns were faithfully recognized, but correct processing of the 3' sites took place only rarely (intron 1) or not at all (intron 3); cryptic 3' splice sites were used instead. While the first intron in human beta-globin pre-mRNA was not spliced in transfected plant protoplasts, intron 2 processing occurred at a low level, indicating that some mammalian introns can be recognized by the plant intron-splicing machinery. However, excision of intron 2 proved to be incorrect, involving the authentic 5' splice site and a cryptic 3' splice site. Our results indicate that the mechanism of 3'-splice-site selection during intron excision differs between plants and animals. This conclusion is supported by analysis of the 3'-splice-site consensus sequences in animal and plant introns which revealed that polypyrimidine tracts, characteristic of animal introns, are not present in plant pre-mRNAs. It is proposed that an elevated AU content of plant introns is important for their processing.

Plant intron sequences: evidence for distinct groups of introns

In vivo and in vitro RNA splicing experiments have demonstrated that the intron splicing machineries are not interchangeable in all organisms. These differences have prevented the efficient in vivo expression of monocot genes containing introns in dicot plants and the in vitro excision of some plant introns in HeLa cell in vitro splicing extracts. We have analyzed plant introns for sequence differences which potentially account for the functional splicing differences. Three classes of plant introns can be differentiated by the purine or pyrimidine-richness of sequences upstream from the 3' splice site. The frequency of these three types of introns in monocots and dicots varies significantly. The degree of variability in the 5' and 3' intron boundaries is evaluated for each of these classes in monocots and dicots. The 5' splice site consensus sequences developed for the monocot and dicot introns differ in their ability to base pair with conserved nucleotides present at the 5' end of many U1 snRNAs.

Accurate and efficient pre-mRNA splicing in Drosophila cell-free extracts

Synthetic mRNA precursors from the Drosophila fushi tarazu (ftz) gene were shown to be accurately and efficiently spliced in Drosophila nuclear extracts derived from Kc tissue culture cells or 0- to 12-hr embryos. Splicing the ftz pre-mRNA requires ATP and low levels of Mg2+. The reaction proceeds with a lag of 20-30 min prior to appearance of spliced mRNA and appears to proceed in two steps. The first step is cleavage at the 5' splice site to generate a 5' exon (E1) fragment and an intron-3' exon (IVS-E2) species. The second step involves cleavage at the 3' splice site, ligation of the two exons (E1-E2), and intron (IVS) release. The excised intron (IVS) and intron-3' exon (IVS-E2) exhibit anomalous electrophoretic mobility, suggesting that they contain branched structures. Nuclease analysis using two-dimensional thin-layer chromatography indicates that both the IVS and IVS-E2 species possess branched trinucleotides in which a guanosine residue at the 5' end of the intron is linked in a 2'-5' phosphodiester bond to the 2' hydroxyl group of an adenosine residue in the intron. The site of branchpoint formation was localized by debranching the Drosophila lariat with mammalian (HeLa) cell debranching enzyme and by P1 and T2 nuclease analysis. These findings indicate that nuclear extracts derived from Drosophila cultured cells or embryos can accurately splice mRNA precursors and that the reaction mechanism is the same as has been observed in yeast and mammalian cells. This system provides an initial step toward the biochemical analysis of developmentally regulated pre-mRNA splicing events in Drosophila.

Nuclear pre-mRNA processing in plants: distinct modes of 3'-splice-site selection in plants and animals

The report that human growth hormone pre-mRNA is not processed in transgenic plant tissues (A. Barta, K. Sommergruber, D. Thompson, K. Hartmuth, M.A. Matzke, and A.J.M. Matzke, Plant Mol. Biol. 6:347-357, 1986) has suggested that differences in mRNA splicing processes exist between plants and animals. To gain more information about the specificity of plant pre-mRNA processing, we have compared the splicing of the soybean leghemoglobin pre-mRNA with that of the human beta-globin pre-mRNA in transfected plant (Orychophragmus violaceus and Nicotiana tabacum) protoplasts and mammalian (HeLa) cells. Of the three introns of leghemoglobin pre-mRNA, only intron 2 was correctly and efficiently processed in HeLa cells. The 5' splice sites of the remaining two introns were faithfully recognized, but correct processing of the 3' sites took place only rarely (intron 1) or not at all (intron 3); cryptic 3' splice sites were used instead. While the first intron in human beta-globin pre-mRNA was not spliced in transfected plant protoplasts, intron 2 processing occurred at a low level, indicating that some mammalian introns can be recognized by the plant intron-splicing machinery. However, excision of intron 2 proved to be incorrect, involving the authentic 5' splice site and a cryptic 3' splice site. Our results indicate that the mechanism of 3'-splice-site selection during intron excision differs between plants and animals. This conclusion is supported by analysis of the 3'-splice-site consensus sequences in animal and plant introns which revealed that polypyrimidine tracts, characteristic of animal introns, are not present in plant pre-mRNAs. It is proposed that an elevated AU content of plant introns is important for their processing.

A chemical modification/interference study of yeast pre-mRNA spliceosome assembly and splicing

A chemical modification/interference assay was used to determine the yeast pre-mRNA sequence requirements for in vitro spliceosome assembly and splicing. Modifications of any of the nucleotides within the 5' splice site and branch point (TACTAAC box) consensus sequences as well as less conserved intron and exon positions were found to inhibit assembly and/or splicing. The interference pattern of the 5' splice site and TACTAAC box lesions increased as spliceosome assembly proceeded (complex III----complex I----complex II) and as splicing proceeded, suggesting that these sequence elements play multiple roles in the assembly of yeast spliceosomes and in the removal of intervening sequences. Furthermore, modification (or mutation) of a TACTAAC-like sequence upstream of the branch point was found to inhibit the rate of spliceosome assembly, implying a possible role for degenerate branch point sequences in modulating the efficiency of spliceosome assembly.

A new natural hGH variant--17.5 kd--produced by alternative splicing. An additional consensus sequence which might play a role in branchpoint selection

From a human pituitary cDNA library, we have cloned 3 distinct human growth hormone (hGH) cDNAs, coding respectively for the 22 K hGH, the 20 K variant, and a yet unknown 17.5 K variant. S1 mapping analysis using human pituitary RNA confirms the existence of at least four distinct hGH mRNAs originating from alternative acceptor sites at the second intron of the primary transcript. We have analysed the hGH gene sequence to explain the high frequency of alternative splicings which occur only at this location. In this study we propose CTTGNNPyPyPy as an additional consensus sequence guiding the selection of the branched nucleotide.

A novel role for the 3' region of introns in pre-mRNA splicing of Saccharomyces cerevisiae

To investigate the importance of sequences between the yeast (Saccharomyces cerevisiae) branch point (TACTAAC box) and 3' splice site (AG), we generated a series of pre-mRNA substrates that differed in the length of RNA retained on the 3' side of the TACTAAC box. These pre-mRNAs were compared as substrates for the first step of in vitro splicing (5' cleavage and lariat formation) and in vitro spliceosome assembly (complex formation) in a whole-cell yeast extract. The results indicate that for rp51A pre-mRNA at least 29 nucleotides of RNA on the 3' side of the TACTAAC box are required for 5' cleavage and lariat formation, as smaller substrates fail to manifest any detectable cleavage or ligation events. Analysis of splicing complex assembly indicates that these smaller substrates undergo efficient yet incomplete complex formation; they are blocked at a late stage of spliceosome assembly, the complex I to complex II transition (Pikielny et al. 1986), a result which suggests that the failure to form lariats is due to a specific assembly defect. The lariat formation block (and assembly defect) can be relieved by the addition of ribohomopolymer "tails" to the 3' end of the shortened rp51A pre-mRNAs, and similar results were obtained with shortened actin pre-mRNAs. The results of this study indicate that this region of the pre-mRNA serves a specific function late in in vitro spliceosome assembly.

Effects on mRNA splicing of mutations in the 3' region of the Saccharomyces cerevisiae actin intron

Point mutations, deletions, and a sequence context change were introduced at positions 3' to the internal conserved TACTAAC sequence of the Saccharomyces cerevisiae actin intron. In vivo analysis of yeast mRNA splicing suggests that, in contrast to the importance of the polypyrimidine tract in metazoan introns, specific sequences in this region are not required for efficient excision of a yeast intron. However, a double point mutation near the 3' junction (GG/AC) does severely inhibit splicing. Although this mutagenesis of the 3' junction, as well as deletion of most nucleotides between the TACTAAC and the 3' junction, caused only a slight accumulation of primary transcript, the observed accumulation of lariat intermediate by these mutants demonstrates the significance of this region for a step(s) in the splicing process after lariat formation.

The role of small nuclear ribonucleoprotein particles in pre-mRNA splicing

A small set of distinctive short RNA molecules are found in the nuclei of all higher eukaryotic cells and yeast, in protein complexes known as 'small nuclear ribonucleoprotein particles', or snRNPs. Recent work has confirmed early suggestions that these particles form part of the machinery by which primary RNA transcripts are processed to their mature, functional form. In particular, snRNPs have been shown to be an integral part of the 'spliceosome', a multi-component complex involved in the removal of intron sequences from the coding regions of messenger RNA precursors.

Effects on mRNA splicing of mutations in the 3' region of the Saccharomyces cerevisiae actin intron

Point mutations, deletions, and a sequence context change were introduced at positions 3' to the internal conserved TACTAAC sequence of the Saccharomyces cerevisiae actin intron. In vivo analysis of yeast mRNA splicing suggests that, in contrast to the importance of the polypyrimidine tract in metazoan introns, specific sequences in this region are not required for efficient excision of a yeast intron. However, a double point mutation near the 3' junction (GG/AC) does severely inhibit splicing. Although this mutagenesis of the 3' junction, as well as deletion of most nucleotides between the TACTAAC and the 3' junction, caused only a slight accumulation of primary transcript, the observed accumulation of lariat intermediate by these mutants demonstrates the significance of this region for a step(s) in the splicing process after lariat formation.

Electrophoresis of ribonucleoproteins reveals an ordered assembly pathway of yeast splicing complexes

Three splicing complexes formed with a yeast pre-messenger RNA during in vitro splicing can be resolved by non-denaturing gel electrophoresis after incubation in the presence of non-specific competitor RNA. The time course of the appearance of these complexes and their composition suggest that they represent an ordered pathway of splicing complex assembly.

In vitro processing of a plant pre-mRNA in a HeLa cell nuclear extract

In order to determine whether there is a general difference in the splicing mechanism of animal and plant pre-mRNAs, we cloned part of the gene for the small subunit of the ribulose 1,5-bisphosphate carboxylase containing both introns into the SP64 vector. RNA was synthesized with SP6 polymerase and used as substrate for in vitro processing in a HeLa cell nuclear splicing extract. Analyses of the processed RNA demonstrate that both introns of the plant pre-mRNA are efficiently removed in an ordered fashion yielding a faithfully ligated mRNA. Two branch points were identified for intron A and three for intron B. The branched nucleotides are adenosine residues in all cases and are located within a distance from the 3' splice site found to be crucial for lariat formation in animal pre-mRNAs. The implications of these results are discussed in light of our previous observation, that a functional pre-mRNA of the human growth hormone gene was not processed in plant tissue in vivo.

RNA splicing and intron turnover are greatly diminished by a mutant yeast branch point

Two mutant genes, both of which contain an A----C transversion at the absolutely conserved branch point of the yeast "TACTAAC box" (TACTAAC----TACTACC), were constructed and introduced into yeast cells. Splicing and gene expression are almost completely eliminated by this mutation, but a low level (approximately equal to 0.1%) of proper splicing is detectable. Branch point mapping indicates that the mutant branch is formed at the normal location--i.e., to cytidine rather than adenosine. The mutant branch is also a very poor substrate for the HeLa cell debranching enzyme. Although splicing of the mutant transcripts is very poor, the cells contain a high level of mutant intron because these excised introns are remarkably stable. The results imply that the normal branch point is important not only for branch formation and splicing but also for intron turnover.