Pac1p, an RNase III homolog, is required for formation of the 3' end of U2 snRNA in Schizosaccharomyces pombe.

Like its homologs in higher eukaryotes, the U2 snRNA in Schizosaccharomyces pombe is transcribed by RNA polymerase II and is not polyadenylated. Instead, an RNA stem-loop structure located downstream of the U2 snRNA coding sequence and transcribed as part of a 3' extended precursor serves as a signal for 3'-end formation. We have identified three mutants that have temperature-sensitive defects in U2 snRNA 3'-end formation. In these mutants, the synthesis of the major snRNAs is also affected and unprocessed rRNA precursors accumulate at the restrictive temperature. Two of these mutants contain the same G-to-A transition within the pac1 gene, whereas the third contains a lesion outside the pac1 locus, indicating that at least two genes are involved. The pac1+ gene is codominant with the mutant allele and can rescue the temperature-sensitive phenotype and the defects in snRNA and rRNA synthesis, if overexpressed. In vitro, Pac1p, an RNase III homolog, can cleave a synthetic U2 precursor within the signal for 3'-end formation, generating a product that is a few nucleotides longer than mature U2 snRNA. In addition, U2 precursors are cleaved and trimmed to the mature size in extracts made from wild-type S. pombe cells. However, extracts made from pac1 mutant cells are unable to do so unless they are supplemented with purified recombinant Pac1p. Thus, the 3' end of S. pombe U2 snRNA is generated by a processing reaction that requires Pac1p and an additional component, and can be dissociated from transcription in vitro.

Myb-related fission yeast cdc5p is a component of a 40S snRNP-containing complex and is essential for pre-mRNA splicing.

Myb-related cdc5p is required for G(2)/M progression in the yeast Schizosaccharomyces pombe. We report here that all detectable cdc5p is stably associated with a multiprotein 40S complex. Immunoaffinity purification has allowed the identification of 10 cwf (complexed with cdc5p) proteins. Two (cwf6p and cwf10p) are members of the U5 snRNP; one (cwf9p) is a core snRNP protein. cwf8p is the apparent ortholog of the Saccharomyces cerevisiae splicing factor Prp19p. cwf1(+) is allelic to the prp5(+) gene defined by the S. pombe splicing mutant, prp5-1, and there is a strong negative genetic interaction between cdc5-120 and prp5-1. Five cwfs have not been recognized previously as important for either pre-mRNA splicing or cell cycle control. Further characterization of cwf1p, cwf2p, cwf3p, and cwf4p demonstrates that they are encoded by essential genes, cosediment with cdc5p at 40S, and coimmunoprecipitate with cdc5p. We further show that cdc5p associates with the U2, U5, and U6 snRNAs and that cells lacking cdc5(+) function are defective in pre-mRNA splicing. These data raise the possibility that the cdc5p complex is an intermediate in the assembly or disassembly of an active S. pombe spliceosome.

Cell-division-cycle defects associated with fission yeast pre-mRNA splicing mutants.

We have isolated six new pre-mRNA splicing mutants (prp) from a collection of temperature-sensitive (ts-) Schizosaccharomyces pombe strains. The prp mutants are defective in the splicing of both messenger RNA and U6 small nuclear RNA precursors. A single recessive mutation is responsible for both the ts- growth and the splicing phenotypes in each of the prp mutants. The six prp mutations are unlinked and fall into separate complementation groups. Two are allelic with the previously described prp3 and prp4 mutations; the remaining four define the new alleles prp5-1, prp6-1, prp7-1, and prp9-1. The six mutants exhibit three splicing phenotypes: accumulation of unspliced precursor at the restrictive but not at the permissive temperature; accumulation of unspliced precursor at both the permissive and restrictive temperatures; and accumulation of unspliced precursor, the intron-exon lariat intermediate, and the intron lariat final product. In addition to their aberrant splicing phenotypes, the prp5-1 and prp6-1 mutants express classical cell-division-cycle defects, while prp7-1 exhibits an unusual hyphal morphology. These results suggest a connection between pre-mRNA splicing and the control of cell division in fission yeast.

Substrate structure requirements of the Pac1 ribonuclease from Schizosaccharmyces pombe.

The Pac1 ribonuclease of Schizosaccharomyces pombe is a member of the RNase III family of double-strand-specific ribonucleases. To examine RNA structural features required for efficient cleavage by the Pac1 RNase, we tested a variety of double-stranded and hairpin RNAs as substrates for the enzyme. The Pac1 RNase required substrates that have a minimal helix length of about 20 base pairs. The enzyme cut both strands of the helix at sites separated by two base pairs. However, Pac1 was also able to make a single-stranded cleavage within an internal bulge of an authentic Escherichia coli substrate at the same site chosen by RNase III. Pac1 efficiently degraded the structurally complex adenovirus VA RNA(I), but was inactive against the short HIV-1 TAR RNA hairpin. These results indicate that the Pac1 RNase prefers straight, perfect helices, but it can tolerate internal bulges that do not distort the helix severely. Like its homologue from Saccharomyces cerevisiae, the Pac1 RNase cleaved at two in vivo RNA processing sites in a hairpin structure in the 3' external transcribed spacer of the S. pombe pre-rRNA, suggesting a role for the enzyme in rRNA maturation.

A connection between pre-mRNA splicing and the cell cycle in fission yeast: cdc28+ is allelic with prp8+ and encodes an RNA-dependent ATPase/helicase.

The fission-yeast gene cdc28+ was originally identified in a screen for temperature-sensitive mutants that exhibit a cell-division cycle arrest and was found to be required for mitosis. We undertook a study of this gene to understand more fully the general requirements for entry into mitosis. Cells carrying the conditional lethal cdc28-P8 mutation divide once and arrest in G2 after being shifted to the restrictive temperature. We cloned the cdc28+ gene by complementation of the temperature-sensitive growth arrest in cdc28-P8. DNA sequence analysis indicated that cdc28+ encodes a member of the DEAH-box family of putative RNA-dependent ATPases or helicases. The Cdc28 protein is most similar to the Prp2, Prp16, and Prp22 proteins from budding yeast, which are required for the splicing of mRNA precursors. Consistent with this similarity, the cdc28-P8 mutant accumulates unspliced precursors at the restrictive temperature. Independently, we isolated a temperature-sensitive pre-mRNA splicing mutant prp8-1 that exhibits a cell-cycle phenotype identical to that of cdc28-P8. We have shown that cdc28 and prp8 are allelic. These results suggest a connection between pre-mRNA splicing and progression through the cell cycle.

Purification and characterization of the Pac1 ribonuclease of Schizosaccharomyces pombe.

The pac1+ gene of the fission yeast Schizosaccharomyces pombe is essential for viability and its overexpression induces sterility and suppresses mutations in the pat1+ and snm1+ genes. The pac1+ gene encodes a protein that is structurally similar to RNase III from Escherichia coli, but its normal function is unknown. We report here the purification and characterization of the Pac1 protein after overexpression in E. coli. The purified protein is a highly active, double-strand-specific endoribonuclease that converts long double-stranded RNAs into short oligonucleotides and also cleaves a small hairpin RNA substrate. The Pac1 RNase is inhibited by a variety of double- and single-stranded polynucleotides, but polycytidylic acid greatly enhances activity and also promotes cleavage specificity. The Pac1 RNase produces 5'-phosphate termini and requires Mg2+; Mn2+ supports activity but causes a loss of cleavage specificity. Optimal activity was obtained at pH 8.5, at low ionic strength, in the presence of a reducing agent. The enzyme is relatively insensitive to N-ethylmaleimide but is strongly inhibited by ethidium bromide and vanadyl ribonucleoside complexes. The properties of the Pac1 RNase support the hypothesis that it is a eukaryotic homolog of RNase III.

Rescue of the fission yeast snRNA synthesis mutant snm1 by overexpression of the double-strand-specific Pac1 ribonuclease.

The Schizosaccharomyces pombe temperature-sensitive mutant snm1 maintains reduced steady-state quantities of the spliceosomal small nuclear RNAs (snRNAs) and the RNA subunit of the tRNA processing enzyme RNase P. We report here the isolation of the pac1+ gene as a multi-copy suppressor of snm1. The pac1+ gene was previously identified as a suppressor of the ran1 mutant and by its ability to cause sterility when overexpressed. The pac1+ gene encodes a double-strand-specific ribonuclease that is similar to RNase III, an RNA processing and turnover enzyme in Escherichia coli. To investigate the essential structural features of the Pac1 RNase, we altered the pac1+ gene by deletion and point mutation and tested the mutant constructs for their ability to complement the snm1 and ran1 mutants and to cause sterility. These experiments identified four essential amino acids in the Pac1 sequence: glycine 178, glutamic acid 251, and valines 346 and 347. These amino acids are conserved in all RNase III-like proteins. The glycine and glutamic acid residues were previously identified as essential for E. coli RNase III activity. The valines are conserved in an element found in a family of double-stranded RNA binding proteins. Our results support the hypothesis that the Pac1 RNase is an RNase III homolog and suggest a role for the Pac1 RNase in snRNA metabolism.

Schizosaccharomyces U6 genes have a sequence within their introns that matches the B box consensus of tRNA internal promoters.

The gene for the U6 small nuclear RNA (snRNA) in the fission yeast Schizosaccharomyces pombe is interrupted by an intron whose structure is similar to those found in messenger RNA precursors (pre-mRNAs) (1). This is the only known example of a split snRNA gene from any organism--animal, plant, or yeast. To address the uniqueness of the S. pombe U6 gene, we have investigated the structures of the U6 genes from five Schizosaccharomyces strains and three other fungi. A fragment of the U6 coding sequence was amplified from the genomic DNA of each strain by the polymerase chain reaction (PCR). The sizes of the PCR products indicated that all of the fission yeast strains possess intron-containing U6 genes; whereas, the U6 genes from the other fungi appeared to be uninterrupted. The sequences of the Schizosaccharomyces U6 gene fragments revealed that each had an intron of approximately 50 base pairs in precisely the same position. In addition to the splice sites and putative branch point regions, a sequence immediately upstream of the branch point consensus was found to be conserved in all of the Schizosaccharomyces U6 genes. This sequence matches the consensus for the B box of eukaryotic tRNA promoters. These results raise the interesting possibility that synthesis of U6 RNA in fission yeast might involve the use of internal promoter elements similar to those found in other genes transcribed by RNA polymerase III.

A mutation in a single gene of Schizosaccharomyces pombe affects the expression of several snRNAs and causes defects in RNA processing.

A bank of temperature sensitive (ts-) mutants of Schizosaccharomyces pombe was screened for snRNA expression mutants using an oligodeoxynucleotide that recognizes U2 RNA. One mutant with a novel phenotype was identified that has reduced steady-state levels of the spliceosomal snRNAs U1, U2, U4, U5 and U6. In addition, the mutant exhibits a temperature-dependent accumulation of aberrant U2 and U4 transcripts elongated at their 3' end. The steady-state concentration of the RNA component of RNase P is also reduced in the mutant, whereas the amount of U3 RNA, 7SL RNA, tRNA, rRNA and mRNA are the same as wild-type. Pre-mRNA, pre-tRNA and U6 RNA precursor processing are impaired in the mutant. Genetic analysis demonstrates that the snRNA defects are tightly linked to the ts- growth defect and are recessive. We have named this mutant snm1 to indicate a defect in snRNA maintenance. The data on snm1 suggest that a single trans-acting factor is essential for the maintenance of steady-state levels of several snRNAs and for proper 3' end formation of U2 and U4 RNAs.

Splicing of the U6 RNA precursor is impaired in fission yeast pre-mRNA splicing mutants.

U6 RNA is a member of a class of small abundant stable nuclear RNAs that are essential for splicing. In all species examined so far, the U6 RNA is a RNA polymerase III transcript. The U6 gene of the fission yeast Schizosaccharomyces pombe is unusual in that it is interrupted by an intron whose structure is similar to those found in pre-mRNAs. As part of our previous analysis of three S. pombe temperature sensitive pre-mRNA splicing mutants we examined their spliceosomal snRNA content. In contrast to the other snRNAs, the amount of U6 RNA is reduced at the restrictive temperature in all three of the mutants compared to the wild type. To investigate the cause of this reduction we have analyzed the efficiency of splicing of the U6 RNA precursor (U6 pre-RNA) in the pre-mRNA splicing mutants. At the restrictive temperature the ratio of unspliced U6 precursor to mature RNA is elevated in the mutants compared to the wild type grown under identical conditions, indicating a defect in U6 pre-RNA splicing. In this regard, the U6 RNA precursor behaves similarly to pre-mRNAs. Unspliced U6 pre-RNA was also detected in wild type cells under certain growth conditions.

Pre-mRNA splicing mutants of Schizosaccharomyces pombe.

A collection of temperature sensitive (ts-) mutants was prepared by chemical mutagenesis of a wild type Schizosaccharomyces pombe strain. To screen the ts- mutants for pre-mRNA splicing defects, an oligodeoxynucleotide that recognizes one of the introns of the beta-tubulin pre-mRNA was used as a probe in a Northern blot assay to detect accumulation of intron sequences. This screening procedure identified three pre-mRNA splicing mutants from 100 ts- strains. The three mutants are defective in an early step of the pre-mRNA splicing reaction; none accumulate intermediates. The precursors that accumulate at 37 degrees C are polyadenylated. Analysis of the splicing of another pre-mRNA showed that the mutations are not specific for beta-tubulin. The total RNA pattern in the three splicing mutants appears to be normal. In addition, the amounts of the spliceosomal snRNAs are not drastically changed compared to the wild type and splicing of pre-tRNAs is not blocked. Genetic analyses demonstrate that all three splicing mutations are tightly linked to the ts- growth defects and are recessive. Crosses among the mutants place them in three complementation groups. The mutants have been named prp1, prp2 and prp3.

Use of RNase H and primer extension to analyze RNA splicing.

A new method for the characterization of pre-mRNA splicing products is presented. In this method RNA molecules are hybridized to an oligodeoxynucleotide complementary to exon sequences upstream of a given 5' splice site, and the RNA strands of the resulting RNA:DNA hybrids are cleaved by RNase H. The cleaved RNAs are then subjected to primer extension using a 32P-labelled primer complementary to exon sequences downstream of an appropriate 3' splice site. Since the primer extension products all terminate at the site of RNase H cleavage, their lengths are indicative of the splice sites utilized. The method simplifies the study of the processing of complex pre-mRNAs by allowing the splicing events between any two exons to be analyzed. We have used this approach to characterize the RNAs generated by expression of the rat tropomyosin 1 (Tm 1) gene in various rat tissues and in cultured cells after transient transfection. The results demonstrate that this method is suitable for the analysis of alternative RNA processing in vivo.

Two spliceosomes can form simultaneously and independently on synthetic double-intron messenger RNA precursors.

We have investigated the formation of splicing complexes in vitro on mRNA precursors (pre-mRNAs) containing two introns. Sucrose gradient sedimentation analysis revealed that the double-intron substrate becomes associated with 60S structures, which are larger than the 50S splicing complexes we previously observed with single-intron pre-mRNA precursors. We have demonstrated that the 60S complex represents the assembly of two single splicing complexes on the individual introns by conversion of the 60S double splicing complexes into single 50S spliceosomes by oligodeoxynucleotide directed RNase H cleavage of the double-intron pre-mRNAs within the middle exon. In addition, we have observed by native gel electrophoresis a transient double 'pre-splicing' complex analogous to the 35S 'pre-splicing' complex previously found with single-intron pre-mRNAs. Our results indicate that splicing complexes can form independently and simultaneously on the individual introns of multi-intron pre-mRNAs and that the assembly of these multiple spliceosomes proceeds with the same stepwise pathway observed for single-intron RNAs.

Accurate in vitro splicing of two pre-mRNA plant introns in a HeLa cell nuclear extract.

Two plant introns along with flanking exon sequences have been isolated from an amylase gene of wheat and a legumin gene of pea and cloned behind the phage SP6 promoter. Pre-mRNAs produced by in vitro transcription with SP6 RNA polymerase were tested for their ability to be spliced in a HeLa cell nuclear extract. The plant introns were accurately spliced and the predicted splice junctions were used. Lariat RNAs were observed as both intermediates and final products during the splicing reaction. The branch points were mapped to adenosine residues lying within sequences that showed good homology to the animal branch point consensus. Consensus sequences for the 5' and 3' splice junctions and for putative branch point sequences of plants were derived from an analysis of 168 plant intron sequences.

Two RNA species co-purify with RNase P from the fission yeast Schizosaccharomyces pombe.

RNase P activity from Schizosaccharomyces pombe co-purifies with two RNA species. These RNAs are associated with enzyme activity as judged by titrated micrococcal nuclease inactivation experiments. The two RNAs, K1- and K2-RNA, are 285 and 270 nucleotides long, respectively. Both RNAs are transcribed from one gene, present in a single copy in the haploid genome. The primary and a secondary structure of K RNAs have been determined and compared with M1 RNA, their counterpart from Escherichia coli. Very limited sequence homology was observed, and this agrees with the finding that no cross-hybridization with M1 RNA can be detected in a Southern analysis with yeast genomic DNA. However, the secondary structures of K RNA and M1 RNA show the same basic organization and one conserved local motif, the sequence GUG--AGGPu in an exposed hairpin loop.

A single base change in the intron of a serine tRNA affects the rate of RNase P cleavage in vitro and suppressor activity in vivo in Saccharomyces cerevisiae.

Differences in the processing of dimeric tRNASer-tRNAMet precursors derived from the Schizosaccharomyces pombe sup9 wild-type and opal suppressor genes can be attributed to conformational alterations in the tRNASer anticodon/intron domain. A comparison of the patterns obtained upon transcription of the sup9+ (wild-type) and sup9-e (opal suppressor) genes in a coupled transcription/processing extract from Saccharomyces cerevisiae reveals that the latter exhibits a greatly reduced efficiency of 5'-end maturation and is susceptible to specific endonucleolytic cleavage(s) within the intron. Free energy calculations indicate that these effects coincide with a destabilization of the wild-type anticodon/intron stem and suggest that the predominant sup9-e conformer lacks secondary structure in this region. Evidence in support of this hypothesis was obtained by analyzing the processing of sup9+ and sup9-e precursors carrying the intron base substitution, G37:10, which destroys and restores, respectively, the base-pairing potential of the proposed secondary structure and comparing the strength and temperature sensitivity of sup9-e and sup9-e G37:10 suppression in vivo in S. cerevisiae. The data indicate that the anticodon/intron structure of tRNA precursors can influence the rate of RNase P cleavage in vitro and affect tRNA expression in vivo.

Stepwise assembly of a pre-mRNA splicing complex requires U-snRNPs and specific intron sequences.

We have investigated the early events of pre-mRNA splicing in vitro by sucrose gradient sedimentation analysis. Time course experiments revealed the assembly, in two steps, of a large (50S) pre-mRNA splicing complex, preceded by formation of two other complexes that sediment at approximately 22S and 35S. Pre-mRNA and the intermediates and products of the in vitro splicing reaction cosediment with the 50S complex, while only pre-mRNA is associated with the 22S and 35S complexes. No splicing is observed in the absence of a 50S complex. Formation of the 50S complex requires ATP, whereas formation of the 22S and 35S complexes does not. U-snRNPs are necessary for assembly of the 35S and the 50S complexes but not for assembly of the 22S complex. Analysis with mutant substrate RNAs demonstrated that a polypyrimidine stretch near the 3' splice site and an intact 5' splice site are absolutely required for splicing complex formation.

Specific incorporation of 5-fluorocytidine into Escherichia coli RNA.

RNAs isolated from Escherichia coli B grown in the presence of 5-fluorouracil have high levels of the analog replacing uridine and uridine-derived modified nucleosides. Cytidine has also been shown to be replaced in these RNAs by 5-fluorocytidine, a metabolic product of 5-fluorouracil, but to a considerably lesser extent. When 5-fluorocytidine is added to cultured of E. coli B little 5-fluorocytidine (0.20 mol%) is incorporated into cellular RNAs because of the active cytosine/cytidine deaminase activities. Addition of the cytidine deaminase inhibitor tetrahydrouridine (70 micrograms/ml) increases 5-fluorocytidine incorporation to about 3 mol% in tRNAs, but does not eliminate 5-fluorouridine incorporation. E. coli mutants lacking cytosine/cytidine deaminase activities are able to more than double the extent of 5-fluorocytidine incorporation into their transfer and ribosomal RNAs, replacing cytidine with no detectable 5-fluorouridine incorporation. Levels of 5-methyluridine, pseudouridine and dihydrouridine in tRNAs are not affected. These fluorocytidine-containing tRNAs show amino acid-accepting activities similar to control tRNAs. Fluorocytidine was found to be quite susceptible to deamination under alkaline conditions. Its conversion to primarily 5-fluorouridine follows pseudo-first-order reaction kinetics with a half-life of 10 h in 0.3 M KOH at 37 degrees C. This instability in alkali probably explains why 5-fluorocytidine was not found earlier in RNAs isolated from cells treated with 5-fluorouridine, since most early RNA hydrolyses were carried out in alkali. It may also explain the mild mutagenic properties observed in some systems following 5-fluorouridine treatment. Initial 19F-NMR measurements in fluorocytidine-containing tRNAs indicate that this modified tRNA may be useful in future structural studies of tRNAs and in probing tRNA-protein complexes.