Trimethylguanosine Nucleoside Inhibits Cross-Linking Between Snurportin 1 and m3G-CAPPED U1 snRNA

Macromolecular nuclear import is an energy-and signal-dependent process. The best characterized type of nuclear import consists of proteins carrying the classical NLS that is mediated by the heterodimeric receptor importin α/β. Spliceosomal snRNPs U1, U2, U4, and U5 nuclear import depend both on the 5’ terminal m₃G (trimethylguanosine) cap structure of the U snRNA and the Sm core domain. Snurportin 1 recognizes the m₃G-cap structure of m₃G-capped U snRNPs. In this report, we show how a synthesized trimethylguanosine nucleoside affects the binding of Snurportin 1 to m₃G-capped U1 snRNA in a UV-cross-linking assay. The data indicated that TMG nucleoside is an essential component required in the recognition by Snurportin 1, thus suggesting that interaction of Snurportin 1 with U1 snRNA is not strictly dependent on the presence of the whole cap structure, but rather on the presence of the TMG nucleoside structure. These results indicate that the free nucleoside TMG could be a candidate to be an inhibitor of the interaction between Snurportin 1 and U snRNAs. We also show the behavior of free TMG nucleoside in in vitro U snRNPs nuclear import.     

Drosophila melanogaster U1 snRNA genes

We have isolated and characterized a recombinant which contains a Drosophila melanogaster U1 small nuclear RNA (snRNA) gene colinear with the published snRNA sequence. Southern hybridizations of the fly genomic DNA, using as probe a plasmid containing only the coding region of the gene, shows that the fly contains at most three or four genes and very few related sequences for the small nuclear U1 RNA. These genes were localized by in situ hybridization at different chromosomal loci and show no spatial relationship to the U2 snRNA genes.     

Snurportin1, an m3G-cap-specific nuclear import receptor with a novel domain structure.

The nuclear import of the spliceosomal snRNPs U1, U2, U4 and U5, is dependent on the presence of a complex nuclear localization signal (NLS). The latter is composed of the 5'-2,2,7-terminal trimethylguanosine (m3G) cap structure of the U snRNA and the Sm core domain. Here, we describe the isolation and cDNA cloning of a 45 kDa protein, termed snurportin1, which interacts specifically with m3G-cap but not m7G-cap structures. Snurportin1 enhances the m3G-capdependent nuclear import of U snRNPs in both Xenopus laevis oocytes and digitonin-permeabilized HeLa cells, demonstrating that it functions as an snRNP-specific nuclear import receptor. Interestingly, solely the m3G-cap and not the Sm core NLS appears to be recognized by snurportin1, indicating that at least two distinct import receptors interact with the complex snRNP NLS. Snurportin1 represents a novel nuclear import receptor which contains an N-terminal importin beta binding (IBB) domain, essential for function, and a C-terminal m3G-cap-binding region with no structural similarity to the arm repeat domain of importin alpha.     

U2 and U1 snRNA gene loci associate with coiled bodies

The coiled bodies are nuclear structures rich in a variety of nuclear and nucleolar components including snRNAs. We have investigated the possibility that coiled bodies may associate with snRNA genes and report here that there is a high degree of association between U2 and U1 genes with a subset of coiled bodies. As investigated in human HeLa cells grown in monolayer culture, about 75% of the nuclei had at least one U2 gene associated with a coiled body, and 45% had at least one U1 locus associated. In another suspension-grown HeLa cell strain, 92% of cells showed association of one or more U2 genes with coiled bodies. In contrast to the U2 and U1 gene associations, a locus closely linked to the U2 gene cluster appeared associated with a coiled body only in 10% of cells. Associated snRNA gene signals were repeatedly positioned at the edge of the coiled body. Thus, this association was highly nonrandom and spatically precise. Our analysis revealed a much higher frequency of association for closely spaced “doublet” U2 gene signals, with over 80% of paired signals associated as opposed to 35% for single U2 signals. This finding, coupled with the fact that not all genes were associated in all cells, suggested the possibility of a cell-cycle-dependent, possibly S-phase, association. However, an analysis of S- and non-S-phase cells using BrdU incorporation or cell synchronization did not indicate an increased level of association in S-phase. These and other results suggested that a substantial fraction of paired U2 signals represented association of U2 genes on homologous chromosomes rather than only replicated DNA. Furthermore, triple lable analysis showed that in a significant fraction of cells U1 and U2 genes were both associated with the same coiled body. U1 and U2 genes were closely paired in approximately 20% of cells, over 60% of which were associated with a readily identifiable coiled body. This finding raises the possibility that multiple genes of a particular class may be in association with each coiled body. Thus, the coiled body may be a dynamic structure which transiently interacts with or is formed by one or more specific genetic loci, possibly carrying out some function related to their expression. © 1995 Wiley-Liss, Inc.     

The yeast homologue of U3 snRNA.

snR17, one of the most abundant capped small nuclear RNAs of Saccharomyces cerevisiae, is equivalent to U3 snRNA of other eukaryotes. It is 328 nucleotides in length, 1.5 times as long as other U3 RNAs, but shares significant homology both in nucleotide sequence and in predicted secondary structure. Human scleroderma antiserum specific to nucleolar U3 RNP can enrich snR17 from sonicated yeast nuclear extracts. Unlike other yeast snRNAs which are encoded by single copy genes, snR17 is encoded by two genetically unlinked genes: SNR17A and SNR17B. The RNA snR17A is more abundant than snR17B. Deleting one or other of the genes has no obvious phenotypic effect, except that the steady-state level of snR17B is increased in snr17a- strains. Haploid strains with both genes deleted are inviable, therefore yeast U3 is essential.     

Characterization of the U3 and U6 snRNA genes from wheat: U3 snRNA genes in monocot plants are transcribed by RNa polymerase III

We have demonstrated recently that the genes encoding the U3 small nuclear RNA (snRNA) in dicot plants are transcribed by RNA polymerase III (pol III), and not RNA polymerase II (pol II) as in all other organisms studied to date. The U3 gene was the first example of a gene transcribed by different polymerases in different organisms. Based on phylogenetic arguments we proposed that a polymerase specificity change of the U3 snRNA gene promoter occurred during plant evolution. To map such an event we are examining the U3 gene polymerase specificity in other plant species. We report here the characterization of a U3 gene from wheat, a monocot plant. This gene contains the conserved promoter elements, USE and TATA, in a pol III-specific spacing seen also in a wheat U6 snRNA gene characterized in this report. Both the U3 and the U6 genes possess typical pol III termination signals but lack the cis element, responsible for 3-end formation, found in all plant pol II-specific snRNA genes. In addition, expression of the U3 gene in transfected maize protoplasts is less sensitive to -amanitin than a pol II-transcribed U2 gene. Based on these data we conclude that the wheat U3 gene is transcribed by pol III. This observation suggests that the postulated RNA polymerase specificity switch of the U3 gene took place prior to the divergence of angiosperm plants into monocots and dicots.     

Mutation in the U2 snRNA influences exon interactions of U5 snRNA loop 1 during pre-mRNA splicing

The U2 and U6 snRNAs contribute to the catalysis of intron removal while U5 snRNA loop 1 holds the exons for ligation during pre-mRNA splicing. It is unclear how different exons are positioned precisely with U5 loop 1. Here, we investigate the role of U2 and U6 in positioning the exons with U5 loop 1. Reconstitution in vitro of spliceosomes with mutations in U2 allows U5-pre-mRNA interactions before the first step of splicing. However, insertion in U2 helix Ia disrupts U5-exon interactions with the intron lariat-3' exon splicing intermediate. Conversely, U6 helix Ia insertions prevent U5-pre-mRNA interactions before the first step of splicing. In vivo, synthetic lethal interactions have been identified between U2 insertion and U5 loop 1 insertion mutants. Additionally, analysis of U2 insertion mutants in vivo reveals that they influence the efficiency, but not the accuracy of splicing. Our data suggest that U2 aligns the exons with U5 loop 1 for ligation during the second step of pre-mRNA splicing.     

Evidence for a relationship between the Bombyx mori middle repetitive Bm1 sequence family and U1 snRNA

Several genomic library equivalents of Bombyx mori were constructed in the EMBL-4 lambda derivative. The genomic bank was screened with purified Bombyx mori U1 RNA and twenty positive clones for the U1 gene were isolated. Three U1-related sequences were subcloned and sequenced. Two of the sequences are U1 pseudogenes while a third sequence represents a member of the Bm1 family of repetitive elements of B.mori with significant sequence similarity to U1 small nuclear RNA. The U1-related Bm1 element exhibits 82% sequence similarity with the Bm1 consensus sequence and, under less stringent computer comparison parameters, 60% similarity with a composite B.mori/Drosophila melanogaster U1 gene. The Bm1 family consensus sequence exhibits 53% sequence similarity with the composite U1 gene. The two pseudogenes possess highly conserved sequences with the B.mori U1 gene only for the first 101 nucleotides. These findings are indicative of at least two different categories of U1-related sequences in B.mori, one with a possible evolutionary relationship to the Bm1 family of repetitive elements and the other representing characteristic processed pseudogenes with retroposon mode of dispersion and target selection for the TTTA hotspot. In addition, the U1-related Bm1 element may demonstrate for the first time that a family of retroposons is ultimately derived from a U snRNA.This article is dedicated in memory of Ms. Deborah Lampert who helped so much in the preparation of this paper.     

Nucleotide sequence determination and secondary structure of Xenopus U3 snRNA

Using a combination of RNA sequencing and construction of cDNA clones followed by DNA sequencing, we have determined the primary nucleotide sequence of U3 snRNA in Xenopus laevis and Xenopus borealis. This molecule has a length of 219 nucleotides. Alignment of the Xenopus sequences with U3 snRNA sequences from other organisms reveals three evolutionarily conserved blocks. We have probed the secondary structure of U3 snRNA in intact Xenopus laevis nuclei using single-strand specific chemical reagents; primer extension was used to map the positions of chemical modification. The three blocks of conserved sequences fall within single-stranded regions, and are therefore accessible for interaction with other molecules. Models of U3 snRNA function are discussed in light of these data.