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.     

Plant small nuclear RNAs. V. U4 RNA is present in broad bean plants in the form of sequence variants and is base-paired with U6 RNA.

U4 RNA, which is known to play an indispensable role in pre-mRNA splicing, is present in plant nuclei, has a canonical m3 2,2,7 G cap at its 5' end and is associated with U6 RNA in snRNP particles. It occurs in broad bean in the form of a number of sequence variants. Two of these were sequenced: U4A RNA is 154 and U4B RNA is 152 nucleotides long. Sequence similarity of broad bean U4B RNA is 94 per cent to broad bean U4A RNA, 65 per cent to rat U4A RNA, 61 per cent to Drosophila U4A RNA and 50 per cent to snR14, the U4 RNA equivalent of the yeast Saccharomyces cerevisiae. Sequence conservation is much more pronounced in the 5' half of the molecule than in its 3' half. The secondary structure of both variants of broad bean U4 RNA perfectly fits with that of all other U4 RNAs sequenced so far. Nucleotide changes between broad bean U4A and U4B RNAs are restricted to molecular regions that affect the thermodynamic stability of these molecules. A model is proposed for the base pairing interaction of broad bean U4 RNA with broad bean U6 RNA. This is the first report on the structure of a plant U4 RNA.     

U2 small nuclear RNA is remarkably conserved between Schizosaccharomyces pombe and mammals.

We report the molecular cloning and sequencing of the most abundant trimethylguanosine-capped small nuclear RNA from the fission yeast Schizosaccharomyces pombe, a highly conserved homolog of mammalian U2 small nuclear RNA. This RNA is 186 nucleotides in length, just 2 nucleotides shorter than its human counterpart; this is in contrast to Saccharomyces cerevisiae U2, which is 1,175 nucleotides long. Moreover, the secondary structure of Schizosaccharomyces pombe U2 is virtually identical to that of mammalian U2, including the 3' half of the RNA, which shows limited primary sequence identity. Northern (RNA) blot analysis revealed that the size of this RNA is conserved not only in fission yeasts but in many organisms, including other ascomycetes.     

Mutations in an essential U2 small nuclear RNA structure cause cold-sensitive U2 small nuclear ribonucleoprotein function by favoring competing alternative U2 RNA structures.

Mutations in stem-loop IIa of yeast U2 RNA cause cold-sensitive growth and cold-sensitive U2 small nuclear ribonucleoprotein function in vitro. Cold-sensitive U2 small nuclear RNA adopts an alternative conformation that occludes the loop and disrupts the stem but does so at both restrictive and permissive temperatures. To determine whether alternative U2 RNA structure causes the defects, we tested second-site mutations in U2 predicted to disrupt the alternative conformation. We find that such mutations efficiently suppress the cold-sensitive phenotypes and partially restore correct U2 RNA folding. A genetic search for additional suppressors of cold sensitivity revealed two unexpected mutations in the base of an adjacent stem-loop. Direct probing of RNA structure in vivo indicates that the suppressors of cold sensitivity act to improve the stability of the essential stem relative to competing alternative structures by disrupting the alternative structures. We suggest that many of the numerous cold-sensitive mutations in a variety of RNAs and RNA-binding proteins could be a result of changes in the stability of a functional RNA conformation relative to a competing structure. The presence of an evolutionarily conserved U2 sequence positioned to form an alternative structure argues that this region of U2 is dynamic during the assembly or function of the U2 small nuclear ribonucleoprotein.     

A fragile site in the human U2 small nuclear RNA gene cluster is revealed by adenovirus type 12 infection.

Using in situ hybridization, we found that the U2 small nuclear RNA gene cluster mapped very close to and was frequently disrupted by the gaps and breaks induced specifically in the human 17q21-q22 region by highly oncogenic adenovirus type 12 (Ad12). Restriction mapping revealed no structural alterations in the U2 gene locus as a result of Ad12 infection. Likewise, no Ad12-induced alterations in U2 RNA levels were detected. We estimate that the maximum size of the region specifically disrupted by this virus was less than 350 to 700 kilobases. A comparison of these data with similar data regarding biochemically induced fragile sites was made.     

Human DNA sequences complementary to the small nuclear RNA U2.

Clones containing sequences complementary to the small nuclear RNA U2 were isolated from a human DNA library (1). Three clones, designated U2/4, U2/6 and U2/7 were purified and characterized by restriction enzyme cleavage, hybridization and heteroduplex analysis. Hybridization showed that the three clones each contained one single region which is complementary to U2 RNA. Restriction enzyme cleavage revealed furthermore that the inserted fragments in the three recombinants are different. Heteroduplex analysis identified a 240-380 bp long duplex region in each heteroduplex which includes sequences complementary to U2 RNA. Heteroduplexes between clones U2/4 and U2/7 as well as between U2/4 and U2/6 revealed two additional approximately 200 bp long homologies. The remainder of the inserts were found to lack measurable sequence homology. Two fragments from clone U2/4 were subcloned in the pBR322 vector and the subclones were used to determine the nucleotide sequence of a region in clone U2/4 which is complementary to U2 RNA. A comparison between the established sequence and the sequence for rat U2 RNA (2) reveals several discrepancies.     

Architecture of the U5 small nuclear RNA.

We have used comparative sequence analysis and deletion analysis to examine the secondary structure of the U5 small nuclear RNA (snRNA), an essential component of the pre-mRNA splicing apparatus. The secondary structure of Saccharomyces cerevisiae U5 snRNA was studied in detail, while sequences from six other fungal species were included in the phylogenetic analysis. Our results indicate that fungal U5 snRNAs, like their counterparts from other taxa, can be folded into a secondary structure characterized by a highly conserved stem-loop (stem-loop 1) that is flanked by a moderately conserved internal loop (internal loop 1). In addition, several of the fungal U5 snRNAs include a novel stem-loop structure (ca. 30 nucleotides) that is adjacent to stem-loop 1. By deletion analysis of the S. cerevisiae snRNA, we have demonstrated that the minimal U5 snRNA that can complement the lethal phenotype of a U5 gene disruption consists of (i) stem-loop 1, (ii) internal loop 1, (iii) a stem-closing internal loop 1, and (iv) the conserved Sm protein binding site. Remarkably, all essential, U5-specific primary sequence elements are encoded by a 39-nucleotide domain consisting of stem-loop 1 and internal loop 1. This domain must, therefore, contain all U5-specific sequences that are essential for splicing activity, including binding sites for U5-specific proteins.     

Autoantibodies to ribonucleoprotein particles containing U2 small nuclear RNA.

Autoantibodies exclusively precipitating U1 and U2 small nuclear ribonucleoprotein (snRNP) particles [anti-(U1,U2)RNP] were detected in sera from four patients with autoimmune disorders. When tested by immunoblotting, these sera recognized up to four different protein antigens in purified mixtures of U1-U6 RNP particles. With purified antibody fractions eluted from individual antigen bands on nitrocellulose blots, each anti-(U1,U2)RNP serum precipitated U2 RNP by virtue of the recognition of a U2 RNP-specific B" antigen (mol. wt. 28 500). Antibodies to the U2 RNP-specific A' protein (mol. wt. 31 000) were found in only one serum. The B" antigen differs slightly in mol. wt. from the U1-U6 RNA-associated B/B' antigens and can be separated from this doublet by two-dimensional gel electrophoresis, due to its more acidic pI. In immunoprecipitation assays, the purified anti-B" antibody specificity also reacts with U1 RNPs which is due to cross-reactivity of the antibody with the U1 RNA-specific A protein, as demonstrated by immunoblotting using proteins from isolated U1 RNPs as antigenic material. Thus the A antigen not only bears unique antigenic sites for anti-A antibodies contained in anti-(U1)RNP sera, it also shares epitopes with the U2 RNP-specific B" antigen.     

Loop I of U1 small nuclear RNA is the only essential RNA sequence for binding of specific U1 small nuclear ribonucleoprotein particle proteins.

The binding of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins C, A, and 70K to U1 small nuclear RNA (snRNA) was analyzed. Assembly of U1 snRNAs from bean and soybean and a set of mutant Xenopus U1 snRNAs into U1 snRNPs in Xenopus egg extracts was studied. The ability to bind proteins was analyzed by immunoprecipitation with monospecific antibodies and by a protein-sequestering assay. The only sequence essential for binding of the U1-specific proteins was the conserved loop sequence in the 5' hairpin of U1. Further analysis suggested that protein C binds directly to the loop and that the assembly of proteins A and 70K into the RNP requires mainly protein-protein interactions. Protein C apparently recognizes a specific RNA sequence rather than a secondary structural element in the RNA.     

Structural analysis of gene loci for rat U1 small nuclear RNA.

Four phage clones which hybridize with U1 small nuclear RNA were obtained from a rat gene library. Two clones contain a presumed pseudogene. A third clone includes two gene candidates that are co-linear with the rat U1-RNA, 3.6kb apart and in the opposite orientation. The two genes are surrounded by identical sequences of 491bp upstream and 178bp downstream. The upstream sequences do not contain a TATA box, but share many block homologies with those for the human U1-RNA gene(1-3). A 101bp "identifier (ID) sequence", which was reported to be specifically expressed in rat brain (4), is inserted immediately after the shared sequence downstream of one of the genes. In the fourth clone, there are two putative pseudogenes, which have one or three nucleotide changes, 3kb apart and in the same orientation. Southern blot analysis of total rat DNA reveals about 50 U1-RNA genes/pseudogenes in the genome.