Compilation of small nuclear RNA sequences

An alternative-exon database and its statistical analysis

We compiled a comprehensive database of alternative exons from the literature and analyzed them statistically. Most alternative exons are cassette exons and are expressed in more than two tissues. Of all exons whose expression was reported to be specific for a certain tissue, the majority were expressed in the brain. Whereas the length of constitutive exons follows a normal distribution, the distribution of alternative exons is skewed toward smaller ones. Furthermore, alternative-exon splice sites deviate more from the consensus: their 3' splice sites are characterized by a higher purine content in the polypyrimidine stretch, and their 5' splice sites deviate from the consensus sequence mostly at the +4 and +5 positions. Furthermore, for exons expressed in a single tissue, adenosine is more frequently used at the -3 position of the 3' splice site. In addition to the known AC-rich and purine-rich exonic sequence elements, sequence comparison using a Gibbs algorithm identified several motifs in exons surrounded by weak splice sites and in tissue-specific exons. Together, these data indicate a combinatorial effect of weak splice sites, atypical nucleotide usage at certain positions, and functional enhancers as an important contribution to alternative-exon regulation.

An unusual chemical reactivity of Sm site adenosines strongly correlates with proper assembly of core U snRNP particles

The small nuclear ribonucleoprotein particles (snRNP) U1, U2, U4, and U5 contain a common set of eight Sm proteins that bind to the conserved single-stranded 5'-PuAU3-6GPu-3' (Sm binding site) region of their constituent U snRNA (small nuclear RNA), forming the Sm core RNP. Using native and in vitro reconstituted U1 snRNPs, accessibility of the RNA within the Sm core RNP to chemical structure probes was analyzed. Hydroxyl radical footprinting of in vitro reconstituted U1 snRNP demonstrated that riboses within a large continuous RNA region, including the Sm binding site, were protected. This protection was dependent on the binding of the Sm proteins. In contrast with the riboses, the phosphate groups within the Sm core site were accessible to modifying reagents. The invariant adenosine residue at the 5' end, as well as an adenosine two nucleotides downstream of the Sm binding site, showed an unexpected reactivity with dimethyl sulfate. This novel reactivity could be attributed to N7-methylation of the adenosine and was not observed in naked RNA, indicating that it is an intrinsic property of the RNA- protein interactions within the Sm core RNP. Further, this reactivity was observed concomitantly with formation of the Sm subcore intermediate during Sm core RNP assembly. As the Sm subcore can be viewed as the commitment complex in this assembly pathway, these results suggest that the peculiar reactivity of the Sm site adenosine bases may be diagnostic for proper assembly of the Sm core RNP. Consistent with this idea, a strong correlation was found between the unusual N7-A methylation sensitivity of the Sm core RNP and its ability to be imported into the nucleus of Xenopus laevis oocytes.

Clustering of pseudouridine residues around the peptidyltransferase center of yeast cytoplasmic and mitochondrial ribosomes

Analysis of the high molecular weight RNAs of the larger ribosomal subunit of Saccharomyces cerevisiae cytoplasm and mitochondria by a new method [Bakin, A., & Ofengand, J. (1993) Biochemistry 32, 9754-9762] has for the first time located all of the pseudouridine residues present in these two RNAs. Thirty pseudouridines were found in the cytoplasmic RNA, and one was found in the mitochondrial RNA. The 30 cytoplasmic RNA pseudouridines were clustered in three regions of the RNA known to be at or near the peptidyltransferase center. The single pseudouridine in yeast mitochondrial rRNA at position 2819 was also located at the peptidyltransferase center. The localization of pseudouridines at or near the peptidyltransferase center in both cytoplasmic and mitochondrial ribosomes implies a functional role for pseudouridine in peptide bond formation. A correlation was shown to exist between the locations of the pseudouridines determined in this work and the positions of the methylated nucleotides (both 2'-OCH3 and base-methylated) determined previously by others. In addition, this work has tentatively identified the locations of two previously unknown ribothymidine residues, at positions 955 and 2920 in the cytoplasmic rRNA.

Ribonucleoprotein particle assembly and modification of U2 small nuclear RNA containing 5-fluorouridine

An in vitro assembly/modification system was used to study the effect of 5-fluorouridine (5-FU) incorporation on the biosynthesis of the U2 small nuclear ribonucleoprotein particle (U2 snRNP). Labeled U2 RNAs were transcribed in vitro with 5-fluoro-UTP either partially supplementing or completely replacing UTP during synthesis. The resulting U2 RNAs have levels of 5-fluorouridine that range from 0 to 100% of the uridine content. When incubated in reactions containing extracts from HeLa cells, these 5-FU U2 RNAs are assembled into RNPs that are recognized by anti-Sm monoclonal antibody even when there is a complete replacement of uridine with 5-FU. However, when the in vitro assembled U2 snRNPs are subjected to buoyant density gradient centrifugation, the particles that contain 100% 5-FU are not resistant to salt dissociation. When the in vitro assembled U2 snRNPs were analyzed by velocity sedimentation gradient centrifugation, 5-FU incorporation correlated with a shift in the sedimentation rate of the particles. With 100% 5-FU incorporation, the peak of radioactivity shifted to approximately 15 S (control U2 RNA was at approximately 12 S). This peak from 5-FU U2 snRNPs was not resistant to dissociation on cesium sulfate gradients. The amount of pseudouridine (psi) found in the RNA from snRNP assembled in vitro on control and 5-FU-containing U2 RNAs was determined, and even at very low levels of 5-FU incorporation (5% replacement), the formation of psi was severely inhibited (36% of control). At higher levels of 5-FU incorporation, there was essentially no psi formed.

Mutational analysis of the yeast U2 snRNA suggests a structural similarity to the catalytic core of group I introns

We have used an in vitro reconstitution system to determine the effects of a large number of mutations in the highly conserved 5' terminal domain of the yeast U2 snRNA on pre-mRNA splicing. Whereas many mutations have little or no functional consequence, base substitutions in two regions were found to have drastic effects on pre-mRNA splicing. A previously unrecognized function for the U2 snRNA in the second step of splicing was found by alteration of the absolutely conserved sequence AGA upstream of the branch point recognition sequence. The effects of these mutations suggest the formation of a structure involving the U2 snRNA similar to the guanosine-binding site found in the catalytic core of group I introns.

Cloning of the cDNA for U1 small nuclear ribonucleoprotein particle 70K protein from Arabidopsis thaliana

We cloned and sequenced a plant cDNA that encodes U1 small nuclear ribonucleoprotein (snRNP) 70K protein. The plant U1 snRNP 70K protein cDNA is not full length and lacks the coding region for 68 amino acids in the amino-terminal region as compared to human U1 snRNP 70K protein. Comparison of the deduced amino acid sequence of the plant U1 snRNP 70K protein with the amino acid sequence of animal and yeast U1 snRNP 70K protein showed a high degree of homology. The plant U1 snRNP 70K protein is more closely related to the human counter part than to the yeast 70K protein. The carboxy-terminal half is less well conserved but, like the vertebrate 70K proteins, is rich in charged amino acids. Northern analysis with the RNA isolated from different parts of the plant indicates that the snRNP 70K gene is expressed in all of the parts tested. Southern blotting of genomic DNA using the cDNA indicates that the U1 snRNP 70K protein is coded by a single gene.

Mutations at the 3' splice site can be suppressed by compensatory base changes in U1 snRNA in fission yeast

U1 snRNA is an essential splicing factor known to base pair with 5' splice sites of premessenger RNAs. We demonstrate that pairing between the universally conserved CU just downstream from the 5' junction interaction region and the 3' splice site AG contributes to efficient splicing of Schizosaccharomyces pombe introns that typify the AG-dependent class described in mammals. Strains carrying mutations in the 3' AG of an artificial intron accumulate linear precursor, indicative of a first step block. Lariat formation is partially restored in these mutants by compensatory changes in nucleotides C7 and U8 of U1 snRNA. Consistent with a general role in fission yeast splicing, mutations at C7 are lethal, while U8 mutants are growth impaired and accumulate linear, unspliced precursor to U6 snRNA. U1 RNA-mediated recognition of the 3' splice site may have origins in analogous intramolecular interactions in an ancestral self-splicing RNA.

Properties of pseudouridine N1 imino protons located in the major groove of an A-form RNA duplex

The exchangeable N1 imino protons of two pseudouridine (psi) bases located at adjacent internal positions within an undecamer RNA duplex (5'AUAC psi psi ACCUG/3'UAUGAAUGGUC) can report on the environment of the major groove of an A-form double-stranded nucleic acid. The psi N1 imino protons of these residues (which are not involved in interstrand Watson-Crick hydrogen bonding) are protected from chemical exchange with the solvent water and thus are observable in the proton NMR spectrum in H2O (1). These protons will exchange readily at increased pH values or upon thermal denaturation of the duplex. The longitudinal (T1) relaxation times of the psi N1 imino protons in 100 mM NaCl or in 10 mM MgCl2 and 100 mM NaCl are approximately two-fold faster than those of the psi N3 imino protons which are involved in Watson-Crick base pairing. With the addition of spermidine, the psi N1 imino protons become readily exchangeable at a temperature some 20 degrees C below the melting temperature of the duplex.

Properties of a U1/mRNA 5' splice site duplex containing pseudouridine as measured by thermodynamic and NMR methods

Three RNA undecamers, 5'AUAC psi psi ACCUG (psi = pseudouridine), 5'AUACUUACCUG, and their complementary 11-mer 5'CAGGUAAGUAU, have been chemically synthesized by phosphite triester chemistry on a controlled-pore glass (CPG) support. The two duplexes formed with these molecules, 5'AUAC psi psi ACCUG/5'CAGGUAAGUAU and 5'AUACUUACCUG/5'CAGGUAAGUAU, represent the 5' end of human U1 snRNA paired to the mRNA consensus 5' splice site. In one undecamer, pseudouridines are incorporated at those positions corresponding to the native in vivo U1 snRNA, while the other (control) undecamer contains only uridine. Surprisingly, the NMR data show that the extra imino proton of the pseudouridines, which is found in the major groove and is presumably not hydrogen bonded, is clearly visible in the imino proton NMR spectrum at pH 6. This result suggests that the structure of the RNA restricts access of solvent to the major groove, slowing the exchange of the pseudouridine NH1 imino proton. A comparison of the thermodynamic properties of the two duplexes show that the free energy of duplex formation is unchanged by the substitution of pseudouridine for uridine.

Evolutionary origin of the U6 small nuclear RNA intron

U6 is the most conserved of the five small nuclear RNAs known to participate in pre-mRNA splicing. In the fission yeast Schizosaccharomyces pombe, the single-copy gene encoding this RNA is itself interrupted by an intron (T. Tani and Y. Ohshima, Nature (London) 337:87-90, 1989). Here we report analysis of the U6 genes from all four Schizosaccharomyces species, revealing that each is interrupted at an identical position by a homologous intron; in other groups, including ascomycete and basidiomycete fungi, as well as more distantly related organisms, the U6 gene is colinear with the RNA. The most parsimonious interpretation of our data is that the ancestral U6 gene did not contain an intron, but rather, it was acquired via a single relatively recent insertional event.

Evolutionary origin of the U6 small nuclear RNA intron

U6 is the most conserved of the five small nuclear RNAs known to participate in pre-mRNA splicing. In the fission yeast Schizosaccharomyces pombe, the single-copy gene encoding this RNA is itself interrupted by an intron (T. Tani and Y. Ohshima, Nature (London) 337:87-90, 1989). Here we report analysis of the U6 genes from all four Schizosaccharomyces species, revealing that each is interrupted at an identical position by a homologous intron; in other groups, including ascomycete and basidiomycete fungi, as well as more distantly related organisms, the U6 gene is colinear with the RNA. The most parsimonious interpretation of our data is that the ancestral U6 gene did not contain an intron, but rather, it was acquired via a single relatively recent insertional event.