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

Specificity of RNA maturation pathways: RNAs transcribed by RNA polymerase III are not substrates for splicing or polyadenylation

To analyze the specificity of RNA processing reactions, we constructed hybrid genes containing RNA polymerase III promoters fused to sequences that are normally transcribed by polymerase II and assessed their transcripts following transfection into human 293 cells. Transcripts derived from these chimeric constructs were analyzed by using a combined RNase H and S1 nuclease assay to test whether RNAs containing consensus 5' and 3' splicing signals could be efficiently spliced in intact cells, even though they were transcribed by RNA polymerase III. We found that polymerase III-derived RNAs are not substrates for splicing. Similarly, we were not able to detect poly(A)+ RNAs derived from genes that contained a polymerase III promoter linked to sequences that were necessary and sufficient to direct 3'-end cleavage and polyadenylation when transcribed by RNA polymerase II. Our findings are consistent with the view that in vivo splicing and polyadenylation pathways are obligatorily coupled to transcription by RNA polymerase II.

Small RNAs of the silkworm, Bombyx mori as revealed by in vitro capping and in vitro transcription

1. We characterized several small RNAs in various tissues and strains of the silkworm, Bombyx mori by the in vitro capping and in vitro transcription. 2. Three subspecies of 7SL RNA, which is believed to be involved in protein secretion, were detected in the commercial strains. Structural differences among the three molecules were due to the nucleotide substitution at two positions or more. 3. A very AU-rich RNA, which is about 500 bases long, was always present in any tissue of Bombyx mori while 55 base RNA was only observed in a substantial amount in the fat body and culture cells. 4. These small RNAs were also observed among the in vitro transcripts of total Bombyx DNA in the cell-free extracts from the silkgland and fat body.

Information transfer in biological systems: targeting of proteins to specific organelles or to the extracellular environment (secretion)

Orderliness is the salient characteristic of living systems. Cells are intolerant of disorder. They express this by rapidly eliminating or degrading out-of-place molecules. When cells are broken apart and their constituent organelles separated and analysed, the same types of macromolecules are always associated with the same subcellular structures. One finds, for example, the same proteins in mitochondria time after time, and these differ from the sets of proteins found in nuclei, secretory granules, or plasma membranes. The information necessary to target each protein to its appropriate intracellular destination is determined primarily by the gene for that protein. Encoded within the DNA structure of genes are signals that specify where each protein molecule belongs. Thus, it is the transfer of information from one macromolecule to another that maintains the integrity and orderliness of living cells.

The c-myc gene encodes superimposed RNA polymerase II and III promoters

The first exon of the c-myc gene has unusual properties that suggest some further role in gene regulation. It encodes a large, evolutionarily conserved leader exon that is transcribed more frequently than the remaining exons of the c-myc gene. In what follows, we provide a possible explanation for these observations. We find that the major promoter of the c-myc gene is bifunctional; that is, it supports transcription by RNA polymerases II and III (pol II and III). Both enzymes initiate in vitro transcription from the major c-myc initiation site (P2), but pol III is completely blocked near the 3' end of the first exon while pol II, though partially blocked, transcribes through this region. These superimposed transcriptional activities suggest a potential regulatory mechanism by which one polymerase system could influence the activity of another.

Identification of a yeast snRNP protein and detection of snRNP-snRNP interactions

The RNA8 gene of Saccharomyces cerevisiae encodes an unusually large (260 kd) protein required for pre-mRNA splicing. Immunological procedures have been used to demonstrate that the RNA8 protein is in stable association with the small nuclear RNAs snR7L and snR7S, which are also known to be required for splicing and which are present in spliceosomal complexes. RNA8 is also involved in an ATP-dependent association with two other small nuclear RNAs, snR14 and snR6. It is proposed that this represents an ATP-dependent interaction between small nuclear ribonucleoprotein particles that precedes their entry into the spliceosome.

The telomere terminal transferase of Tetrahymena is a ribonucleoprotein enzyme with two kinds of primer specificity

We have analyzed the de novo telomere synthesis catalyzed by the enzyme telomere terminal transferase (telomerase) from Tetrahymena. Oligonucleotides representing the G-rich strand of telomeric sequences from five different organisms specifically primed the addition of TTGGGG repeats in vitro, suggesting that primer recognition may involve a DNA structure unique to these oligonucleotides. The sequence at the 3' end of the oligonucleotide primer specified the first nucleotide added in the reaction. Furthermore, the telomerase was shown to be a ribonucleoprotein complex whose RNA and protein components were both essential for activity. After extensive purification of the enzyme by a series of five different chromatographic steps, a few small low abundance RNAs copurified with the activity.

The human U1-70K snRNP protein: cDNA cloning, chromosomal localization, expression, alternative splicing and RNA-binding

We have isolated and sequenced cDNA clones encoding the human U1-70K snRNP protein, and have mapped this locus (U1AP1) to human chromosome 19. The gene produces two size classes of RNA, a major 1.7-kb RNA and a minor 3.9-kb RNA. The 1.7-kb species appears to be the functional mRNA; the role of the 3.9-kb RNA, which extends further in the 5' direction, is unclear. The actual size of the hU1-70K protein is probably 52 kd, rather than 70 kd. The protein contains three regions similar to known nucleic acid-binding proteins, and it binds RNA in an in vitro assay. Comparison of the cDNA sequences indicates that there are multiple subclasses of mRNA that arise by alternative pre-mRNA splicing of at least four alternative exon segments. This suggests that multiple forms of the hU1-70K protein may exist, possibly with different functions in vivo.

Controlled turnover and 3' trimming of the trans splicing precursor of Trypanosoma brucei

The maturation of mRNAs in Trypanosoma brucei involves a novel step, in which a short capped sequence is spliced in trans onto the 5' end of nascent mRNAs from a 140-nucleotide precursor. This precursor is called the mini-exon-derived RNA or medRNA. We have used drugs and ultraviolet irradiation as inhibitors to probe the synthesis and processing of medRNA in vivo. Inhibition of RNA synthesis by chloroquine shows that the half-life of medRNA is about 4 minutes. Despite this high turnover, only limited accumulation of medRNA could be achieved following a block in the synthesis of high molecular weight splice acceptor substrates by UV irradiation. This implies that there is a constraint on the steady-state levels of medRNA and that excess medRNA is degraded in the cell. A 3' shortened version of medRNA accumulates upon a block in normal medRNA processing by UV irradiation or upon treatment of the cells with actinomycin D or novobiocin but was shown not to participate in trans splicing, making it a likely candidate for an in vivo degradation intermediate.

Identification of the human U7 snRNP as one of several factors involved in the 3' end maturation of histone premessenger RNA's

In eukaryotic cells, the conversion of gene transcripts into messenger RNA's involves multiple factors, including the highly abundant small nuclear ribonucleoprotein (snRNP) complexes that mediate the splicing reaction. Separable factors are also required for the 3' end processing of histone pre-mRNA's. The two conserved signals flanking the 3' cleavage site are recognized by discrete components present in active HeLa cell extracts: the upstream stem loop associates with a nuclease-insensitive factor, while binding to the downstream element is mediated by a component having the properties of a snRNP. The sequence of the RNA moiety of the low abundance human U7 snRNP suggests how the relatively degenerate downstream element of mammalian pre-mRNA's could be recognized by RNA base-pairing.

Self-splicing of group II introns in vitro: lariat formation and 3' splice site selection in mutant RNAs

Deletion or substitution of the branch A residue in group II intron bl1 significantly reduces splicing activity; yet, residual exon ligation is correct, and lariats have their branch points at the normal distance from the 3' end of the intron. Mutations in the sequence facing the branch point also allow residual lariat formation; however, free 3' exons are generated with false 5' termini, all of which are within a UCACA consensus sequence located upstream or downstream of the normal 3' splice site. These results indicate that both the conserved 3' splice site APy and the spatial arrangements in stem 6 are crucial for correct 3' splice site selection.

Structure and conformation of the branch core triribonucleotide containing 2'-5' and 3'-5' phosphodiester linkages (A 2'p5'G 3'p5'C) i solution, essential for yeast mRNA splicing, deduced from 1H-NMR

The non-exchangeable 1H-NMR signals of the branch core trinucleotide of the lariat branch site (A2'p5'G3'p5'C, 1) and its derivatives 2 and 3 are completely assigned using one- and two-dimensional NMR techniques including NOE, COSY, NOESY, 1H-1H INADEQUATE and 2D-J-resolved spectroscopy. From the vicinal coupling constants in the individual ribose rings, NOE data and T1 measurements, the following properties of the trimers are deduced. (i) The unique stacking behavior of the trimers is S2'N3'N, and the sugar rings exist predominantly in the N-conformation (3'-endo-2'-exo). (ii) The sugar-base orientations appear to be anti. (iii) The branched trimers exist in solution as single-stranded right-handed conformations resembling A-RNA with stacking between the adenine and guanine residues in aqueous solution at 21 degrees C and pH 7.2. (iv) The calculated values for the torsion angles epsilon t and gamma+ for the trimers are 201-203 degrees and 71-86%, respectively, while the percent beta t values are higher for the guanine (87-92%) than the cytosine residues (73-77%). The computer generated depiction of the triribonucleotide 1 is also shown. These subtle structural features may act as recognition signals for this critical lariat branch site which is essential for the second step in yeast mRNA splicing.

Sequence of the bifunctional ade1 gene in the purine biosynthetic pathway of the fission yeast Schizosaccharomyces pombe

The ade1 gene of the fission yeast Schizosaccharomyces pombe encodes a bifunctional polypeptide with glycinamide ribotide synthetase (GARSase) and aminoimidazole ribotide synthetase (AIRSase) enzyme activities. These enzyme activities carry out the 2nd and 5th steps, respectively, of the purine synthetic pathway. We report the cloning of the ade1 gene on a 4.4 kb Sau3A insert in the yeast shuttle vector pWH5. Integration of this genomic insert at or near the ade1 locus and its ability to complement, by transformation, three different types of ade1 mutants proved that it contains the ade1 chromosomal gene. Analysis of the nucleotide sequence of this insert revealed the presence of an uninterrupted open reading frame of 2,367 pb. This sequence, and the predicted 789 amino acid sequence encoded, both show a high degree of homology with the functionally equivalent ade5,7 gene sequence of Saccharomyces cerevisiae (approx. 60% overall in both cases) and Gart gene sequences of Drosophila melanogaster. The size of the ade1 RNA transcript is about 2.7 kb.

Heat-labile regulatory factor is required for 3' processing of histone precursor mRNAs

In addition to Sm antigen-type small nuclear ribonucleoprotein particle(s) [snRNP(s)], at least one more factor is involved in the in vitro 3' processing of histone precursor mRNAs (pre-mRNAs) in a HeLa cell nuclear extract. This factor can be completely inactivated by mild heat treatment but is resistant to digestion by micrococcal nuclease and is not immunoprecipitated by antisera of the Sm serotype. Both snRNP (the presumed human homologue of the U7 snRNP of the sea urchin) and the heat-labile factor described above show closely similar properties when fractionated on DEAE, heparin, and Mono Q columns. Fractions, after extensive purification, still contain both heat-labile factor and snRNP activity. When analyzed by gel filtration, the heat-labile component distributes bimodally, the smaller component possessing an apparent molecular weight on the order of 40,000, and the larger, of ca. 300,000.

Introns increase gene expression in cultured maize cells

Using electroporation-mediated gene transfer, the gene encoding the Slow (S) migrating polypeptide of the maize (Zea mays L.) alcohol dehydrogenase-1 (Adh1) enzyme has been introduced stably and transiently into maize cells containing an endogenous Fast (F) ADH1 electromorph. In stable transformants an 11.5-kb fragment was sufficient to program normal S expression relative to the endogenous F allele. In transient assays, Adh1-S gene constructs lacking the 9 Adh1-S intervening sequences (introns) were expressed at levels 50- to 100-fold less than the intact gene; the presence of intron 1 alone restored levels of gene expression to those found with the intact gene. The last two introns also stimulate Adh1-S expression, but the level is threefold below that of the intact gene. The expression of a chimeric chloramphenicol acetyltransferase (CAT) gene utilizing the 5' promoter and 3' polyadenylation regions of the Adh1 gene was increased 100-fold by the addition of sequences containing the Adh1 intron 1. The Adh1 intron 1 sequences did not stimulate CAT expression when located outside the transcribed region. When located within the transcribed region, the Adh1 intron 1 region efficiently stimulated CAT expression only when located between the promoter and the CAT coding region. A construct containing the Adh1 intron 1 fragment produced 40-fold more mRNA than a construct containing an equivalent cDNA fragment. Both the Adh1 intron 1 and the intron from a second maize gene, Bronze1, stimulated expression from other promoters (cauliflower mosaic virus 35S and nopaline synthase) and of other coding regions (luciferase and neomycin phosphotransferase II) as well. These results indicated that introns increase both Adh1 and chimeric gene expression in maize and the optimal location for such an intron is near the 5' end of the mRNA.

Reconstitution of the U1 small nuclear ribonucleoprotein particle

Although the U1 small nuclear ribonucleoprotein particle (snRNP) was the first mRNA-splicing cofactor to be identified, the manner in which it functions in splicing is not precisely understood. Among the information required to understand how U1 snRNP participates in splicing, it will be necessary to know its structure. Here we describe the in vitro reconstitution of a particle that possesses the properties of native U1 snRNP. 32P-labeled U1 RNA was transcribed from an SP6 promoter-human U1 gene clone and incubated in a HeLa S100 fraction. A U1 particle formed which displayed the same sedimentation coefficient (approximately 10S) and buoyant density (1.40 g/cm3) as native U1 snRNP. The latter value reflects the ability to withstand isopycnic banding in Cs2SO4 without prior fixation, a property shared by native U1 snRNP. The reconstituted U1 particle reacted with both the Sm and RNP monoclonal antibodies, showing that these two classes of snRNP proteins were present. Moreover, the reconstituted U1 snRNP particle was found to display the characteristic Mg2+ switch of nuclease sensitivity previously described for native U1 snRNP: an open, nuclease-sensitive conformation at a low Mg2+ concentration (3 mM) and a more compact, nuclease-resistant organization at a higher concentration (15 mM). The majority of the U1 RNA in the reconstituted particle did not contain hypermethylated caps, pseudouridine, or ribose 2-O-methylation, showing that these enigmatic posttranscriptional modifications are not essential for reconstitution of the U1 snRNP particle. The extreme 3' end (18 nucleotides) of U1 RNA was required for reconstitution, but loop II (nucleotides 64 to 77) was not. Interestingly, the 5' end (15 nucleotides) of U1 RNA that recognizes pre-mRNA 5' splice sites was not required for U1 snRNP reconstruction.

In-vivo secondary structure analysis of the small nuclear RNA U1 using psoralen cross-linking

Intramolecular base-pairing interactions have been probed in the small nuclear RNA U1 in vivo. HeLa cells were treated with the psoralen derivative aminomethyltrioxsalen, and cross-linking was carried out by irradiating the intact cells with light of 365 nm wavelength. Cross-linking resulted in a discrete shift in electrophoretic mobility of approximately 65 to 70% of the U1. This intramolecularly cross-linked U1 RNA, termed XU1, was purified and shown to co-migrate with uncross-linked U1 upon photo-reversal of psoralen cross-links with light of 254 nm wavelength. XU1 was also generated by the in-vitro cross-linking of deproteinized U1, suggesting that the secondary structure of U1 RNA in solution is similar to that of U1 ribonucleoprotein in the cell. A sequencing analysis was developed, based on partial enzymatic and alkaline cleavage of psoralen-treated RNA, to identify the position of psoralen cross-links and to distinguish between psoralen monoadducts and diadducts (cross-links). Sequencing of 3' and 5' end-labeled XU1 provided direct evidence for the presence of a unique intramolecular cross-link in XU1, located on uridine 116 (U116). This result is consistent with several secondary-structure models for U1 in which U116 is located in a base-paired stem. The proximity of uridine 96 (U96) to U116 on the opposite side of the base-paired stem suggested that U116 was cross-linked to U96. An additional U1 species having an electrophoretic mobility between those of U1 and XU1 was also generated by psoralen treatment. Analysis of this U1 species, termed U1M, revealed a psoralen monoadduct on U96. Further longwave (365 nm) irradiation of purified U1M resulted in its conversion to XU1 by completion of the U96-U116 cross-link. This suggested that cross-linking at the U96-U116 site occurred as a two-step process in which the psoralen first reacted with U96 and then with U116. Sequencing analysis also identified a psoralen monoadduct on uridine 45 (U45) of XU1. Efficient psoralen-adduct formation, which resulted in cross-linking at the U96-U116 site and monoaddition on U45, suggests that these regions are relatively accessible in the native U1 small nuclear ribonucleoprotein particle in vivo.

Specificity of RNA maturation pathways: RNAs transcribed by RNA polymerase III are not substrates for splicing or polyadenylation

To analyze the specificity of RNA processing reactions, we constructed hybrid genes containing RNA polymerase III promoters fused to sequences that are normally transcribed by polymerase II and assessed their transcripts following transfection into human 293 cells. Transcripts derived from these chimeric constructs were analyzed by using a combined RNase H and S1 nuclease assay to test whether RNAs containing consensus 5' and 3' splicing signals could be efficiently spliced in intact cells, even though they were transcribed by RNA polymerase III. We found that polymerase III-derived RNAs are not substrates for splicing. Similarly, we were not able to detect poly(A)+ RNAs derived from genes that contained a polymerase III promoter linked to sequences that were necessary and sufficient to direct 3'-end cleavage and polyadenylation when transcribed by RNA polymerase II. Our findings are consistent with the view that in vivo splicing and polyadenylation pathways are obligatorily coupled to transcription by RNA polymerase II.

Periodicities in introns

The sequence information for the splicing process of introns is found in the consensus sequences at the two splice sites. For long introns, of 300 or more nucleotides, the middle regions may provide additional specificity for splicing which can be investigated by defining an adequate quantitative parameter. This methodology permits to retrieve the coding periodicity in the viral and mitochondrial introns and to identify with a statistical significance, a surprising alternating purine-pyrimidine base sequence -i.e. a modulo 2 periodicity- in the eukaryotic introns, and particularly in the vertebrate introns. This alternating structure suggests that the vertebrate introns do not have the genetic information to code for proteins, they carry structural and regulatory functions.

Saccharomyces cerevisiae has a U1-like small nuclear RNA with unexpected properties

Previous experiments indicated that only a small subset of the approximately equal to 24 small nuclear RNAs (snRNAs) in Saccharomyces cerevisiae have binding sites for the Sm antigen, a hallmark of metazoan small nuclear ribonucleoproteins (snRNPs) involved in pre-messenger RNA splicing. Antibodies from human serum to Sm proteins were used to show that four snRNAs (snR7, snR14, snR19, and snR20) can be immunoprecipitated from yeast extracts. Three of these four, snR7, snR14, and snR20, have been shown to be analogs of mammalian U5, U4, and U2, respectively. Several regions of significant homology to U1 (164 nucleotides) have now been found in cloned and sequenced snR19 (568 nucleotides). These include ten out of ten matches to the 5' end of U1, the site known to interact with the 5' splice site of mammalian introns. Surprisingly, the precise conservation of this sequence precludes perfect complementarity between snR19 and the invariant yeast 5' junction (GTATGT), which differs from the mammalian consensus at the fourth position (GTPuAGT).

Only two of the four sites of interaction with nuclear factors within the Xenopus U2 gene promoter are necessary for efficient transcription

An analysis, performed by DNase I footprinting, of the interactions between factors present in Molt-4 nuclear extracts and a Xenopus U2 snRNA gene promoter is presented. Four distinct regions of sequence-specific DNA-factor interaction are found. Two of these correspond to the previously identified proximal and distal sequence elements (PSE and DSE) of the promoter. Both of these elements are important in U2 transcription, indicating a functional role for the observed interactions. The other two sites of interaction correspond to a sequence element conserved in many, but not all, vertebrate U snRNA gene promoters (the MSE) and to a region adjacent to the site of transcription initiation (the "cap site"). Site-directed mutants of these latter two elements are constructed which no longer bind nuclear factors. Transcriptional analysis in Xenopus oocytes reveals that these mutants are transcribed as efficiently as wild-type U2. Other possible roles for the two factors are discussed.

An essential snRNA from S. cerevisiae has properties predicted for U4, including interaction with a U6-like snRNA

Three yeast snRNAs (snR20, snR7, and snR14) have been implicated in pre-mRNA splicing. snR20 and snR7 contain domains of homology to U2 and U5, respectively, and each is required for viability. These RNAs are found associated with the spliceosome, as is snR14. We show here that snR14 is also an essential gene product. Sequence analysis reveals that, like snR7 and snR20, snR14 contains a consensus binding site for the Sm antigen, a feature common to all mammalian snRNAs involved in splicing. Moreover, snR14 exhibits several blocks of sequence and structural homology to U4, which in metazoans is found in association with U6. Native gel electrophoresis demonstrates that snR14 is in fact base-paired with another yeast snRNA, designated snR6, which has primary sequence homology to U6. We conclude that snR14 is the yeast analog of U4.

S. cerevisiae U1 RNA is large and has limited primary sequence homology to metazoan U1 snRNA

We have cloned and sequenced the yeast SNR19 gene and show here that snR19 is the yeast homolog of metazoan U1 snRNA. sn R19 is 569 nucleotides long, strikingly larger than its metazoan counterpart. The two molecules resemble each other closely in the predicted secondary structure of their first 50 nucleotides. Primary sequence homology is restricted to some of their single-stranded regions, including 11 consecutive nucleotides at the 5' end of the two molecules, the region that interacts with pre-mRNA 5' splice junctions. snR19 is spliceosome-associated and required for in vitro pre-mRNA splicing. We also note that 8 sequences in snR19 have extensive complementarity to snR20, the large yeast U2 RNA, suggesting that yeast U1 may interact with yeast U2 by base-pairing.

Sequence dependent conformation and local geometry of the conserved branch site sequence element d(TpApCpTpApApC), essential for yeast mRNA splicing, deduced from high resolution 1H-NMR

The conserved sequence element and branch site splice signal d(TpApCpTpApApC) has been synthesized by a solid phase procedure. All the non-exchangeable protons have been assigned using a combination of one-dimensional and two-dimensional 1H-NMR analytical procedures. On the basis of the low NOE intensities in the 1D-NOE and NOESY experiments, the heptamer exists in solution as a random coil. The deoxyribose rings towards the 5' terminus exist predominantly in the S form (2'-endo-3'-exo) while residues on or adjacent to the 2' branch site in the eventual lariat structure [A(6) of TACTAAC] show more N-character (3'endo-2'-exo). In addition unique propeller twisting at contiguous AT base pairs in the consensus 5'-splice site occurs in the region in which there is partial complementarity with the branch splice signal TACTAAC. These subtle structural features, if carried over to the corresponding RNA, may have significance either as a recognition signals or for stereochemical reasons in the formation of the lariat intermediate in the maturation process of mRNA.

Structure and conformation of the duplex consensus 5'-splice site d[(CpApGpGpTpApApGpT).(ApCpTpTpApCpCpTpG)] deduced from high field 1H-NMR of the non-exchangeable and imino protons

The complementary consensus donor exon intron junction d(ApCpTpTpApCpCpTpG) has been synthesized by a solid phase procedure. The non-exchangeable proton assignments were obtained using one- and two-dimensional NMR techniques including NOE, COSY, NOESY and 1H-1H-INADEQUATE. The non self-complementary nonamer exists as a random coil form in aqueous buffer at 21 degrees C as evidenced by the temperature variable 1H-NMR and NOE measurements. The nonamer was annealed to the primary consensus donor junction d(CpApGpGpTpApApGpT) and confirmation of complete annealing was obtained by detection and assignment of base pair imino protons in D2O/H2O mixtures. Application of one- and two-dimensional NMR techniques permitted the complete assignment of all the non-exchangeable protons in the duplex nonamer. These data, together with determination of vicinal coupling constants in the individual deoxyribose moieties, permits the following conclusions on the structure and conformation of the consensus donor junction: (i) it exists in aqueous solution in a conformation that belongs to the B family (ii) the sugar-base orientations are anti (iii) the deoxyribose units exist predominantly in the S conformation (2'-endo-3'-exo) (iv) the contiguous A.T base pairs d[T(5)-A(6)-A(7)].d[T(12)-T(13)-A(14)], two positions removed downstream from the splice site (5'-CAG decreases GTAAGT-3'), are uniquely propeller twisted. The propeller twisting occurs in the region in which there is partial complementarity with the branch site splice signal TACTAAC. The cross-correlation rates were used to derive the interproton distances between adjacent AH2 protons of 4.00 A in the T(5)-A(6).T(13)-A(14) step and of 3.87 A in the A(6)-A(7).T(12)-T(13) step. This structural and conformational feature if carried over into the primary RNA transcripts may serve as a recognition signal for this critical site in the genome.

Distance analysis helps to establish characteristic motifs in intron sequences

Computer-assisted sequence analysis was applied to detect the most apparent nonrandom sequence motifs in eukaryotic introns. We describe in detail a method, which we call distance analysis, that we applied to the extensive study of 405 eukaryotic intron sequences. We observed very strong two-base periodicities for almost all tetranucleotides that are tandem repeats of nonhomopolymeric dinucleotides (the exception was GCGC and CGCG). We also observed, by using a fixed-point alignment method, that these periodic sequence motifs belong to large clusters of dinucleotides repeated tandemly as many as 15-35 times, which corresponds to the cluster lengths of 30-70 bases. We did not observe two-base periodicity of tetranucleotides in the collections of either 262 spliced eukaryotic exons or 107 bacterial genes. Instead, these sequences displayed strong three-base periodicity of some other tetranucleotides. These findings suggest that introns and exons display distinct sequence properties that can be used for mapping purposes.

A trans-acting suppressor restores splicing of a yeast intron with a branch point mutation

Splicing of introns from Saccharomyces cerevisiae pre-mRNA requires the conserved sequence TACTAAC; the 3'-most A residue is utilized as the site of branch formation. We showed previously that the transcript from an actin-HIS4 gene fusion containing the mutation TACTAAC to TACTACC (designated C259) is spliced inefficiently, thereby preventing growth on the histidine precursor histidinol. By selecting for growth on histidinol, we have identified a mutant in which the splicing of the C259 transcript is increased fourfold; splicing of other mutated introns is not significantly improved. The mutant locus encodes a trans-acting suppressor. A single mutation, rna16-1, is sufficient for suppression; however, suppression is maximized in heterozygous diploids containing both rna16-1 and the wild-type allele RNA16. In addition, wild-type pre-mRNAs (and lariat intermediates) accumulate in rna16-1 cells. We propose that the RNA16 locus encodes a component of the splicing machinery.

The chemistry of self-splicing RNA and RNA enzymes

Proteins are not the only catalysts of cellular reactions; there is a growing list of RNA molecules that catalyze RNA cleavage and joining reactions. The chemical mechanisms of RNA-catalyzed reactions are discussed with emphasis on the self-splicing ribosomal RNA precursor of Tetrahymena and the enzymatic activities of its intervening sequence RNA. Wherever appropriate, catalysis by RNA is compared to catalysis by protein enzymes.

An essential yeast snRNA with a U5-like domain is required for splicing in vivo

Yeast contains at least 24 snRNAs, many of which are dispensable for viability. We recently demonstrated that a small subset of these RNAs has a functional binding site for the Sm antigen, a hallmark of metazoan snRNAs involved in mRNA processing. Here we show that one of these snRNAs, snR7, is required for growth. To determine the biochemical basis of lethality in cells lacking snR7, we engineered the conditional synthesis of snR7 by fusing the snRNA coding sequences to the yeast GAL1 control region. Cells depleted for the SNR7 gene product by growth on glucose for five generations show marked accumulation of unspliced mRNA precursors from the four intron-containing genes tested. In some cases, intron-exon 2 lariats also accumulate. We have identified a 70 nucleotide domain within snR7 with limited sequence-specific but striking structural homology to the mammalian snRNA U5. We conclude that mRNA splicing in yeast requires the function of a U5-like snRNA.

Recognition of the TACTAAC box during mRNA splicing in yeast involves base pairing to the U2-like snRNA

The U2 snRNP binds to the site of branch formation during splicing of mammalian pre-mRNA in vitro. In Saccharomyces cerevisiae the branch site is within the so-called TACTAAC box (UACUAAC box), an absolutely conserved intron sequence required for splicing. Based on the identification and sequence of a U2 analogue in yeast, a specific base pairing interaction between the UACUAAC box and a highly conserved region of this snRNA can be proposed. To test this hypothesis, we have taken advantage of two mutations constructed previously in the UACUAAC box of an actin-HIS4 fusion. These mutant strains were transformed with stable plasmids bearing U2-like snRNAs into which changes predicted to restore base pairing had been introduced. Allele-specific suppression of biological and biochemical phenotypes was observed in both cases. Recognition of the UACUAAC box thus relies, at least in part, on Watson-Crick base pairing with the yeast U2 analogue.