Schizosaccharomyces pombe U4 small nuclear RNA closely resembles vertebrate U4 and is required for growth

Pof8 is a La-related protein and a constitutive component of telomerase in fission yeast

Telomerase reverse transcriptase (TERT) and the non-coding telomerase RNA subunit (TR) constitute the core of telomerase. Here we now report that the putative F-box protein Pof8 is also a constitutive component of active telomerase in fission yeast. Pof8 functions in a hierarchical assembly pathway by promoting the binding of the Lsm2-8 complex to telomerase RNA, which in turn promotes binding of the catalytic subunit. Loss of Pof8 reduces TER1 stability, causes a severe assembly defect, and results in critically short telomeres. Structure profile searches identified similarities between Pof8 and telomerase subunits from ciliated protozoa, making Pof8 next to TERT the most widely conserved telomerase subunits identified to date.

Pre-mRNA splicing in Schizosaccharomyces pombe: regulatory role of a kinase conserved from fission yeast to mammals

Most primary messenger RNA transcripts (pre-mRNAs) in eukaryotes contain intervening sequences that must be precisely removed to generate a functional mRNA. The excision of the intervening sequences, the introns, from a pre-mRNA and the concomitant joining of the flanking sequences, the exons, is called pre-mRNA splicing. Pre-mRNA splicing takes place in large ribonucleoprotein machinery, the spliceosome. Although the function and components of this machinery appear to be highly conserved between organisms, many distinct differences between budding yeast, Saccharomyces cerevisiae, and fission yeast, Schizosaccharomyces pombe, have been found, emphasizing their evolutionary distance. Most interestingly, fission yeast appears to reflect the more conservative evolutionary development regarding pre-mRNA splicing. Many spliceosomal components, including the five small nuclear RNAs, which most likely form the catalytic core of the spliceosome, show a higher degree of similarity with the components of the splicing machinery found in mammals. In addition, several regulatory components of the spliceosome detected in mammals are absent in Sac. cerevisiae, but present in Sch. pombe. Here, we review recent progress made in our understanding of the control of pre-mRNA splicing in Sch. pombe. The focus is on Prp4p kinase, first discovered in fission yeast and also present in mammals, but absent in Sac. cerevisiae. Results from both mammals and Sch. pombe suggest that Prp4p plays a key role in regulating pre-mRNA splicing and in connecting this process with the cell cycle.

Activated levels of rRNA synthesis in fission yeast are driven by an intergenic rDNA region positioned over 2500 nucleotides upstream of the initiation site

RNA polymerase I-catalyzed synthesis of the Schizosaccharomyces pombe approximately 37S pre-rRNAs was shown to be sensitive to regulatory sequences located several kilobases upstream of the initiation site for the rRNA gene. An in vitro transcription system for RNA polymerase I-catalyzed RNA synthesis was established that supports correct and activated transcription from templates bearing a full S. pombe rRNA gene promoter. A 780 bp region starting at -2560 significantly stimulates transcription of ac is-located rDNA promoter and competes with an rDNA promoter in trans, thus displaying some of the activities of rDNA transcriptional enhancers in vitro. Deletion of a 30 bp enhancer-homologous domain in this 780 bp far upstream region blocked its cis-stimulatory effect. The sequence of the S. pombe 3.5 kb intergenic spacer was determined and its organization differs from that of vertebrate, Drosophila, Acanthamoeba and plant intergenic rDNA spacers: it does not contain multiple, imperfect copies of the rRNA gene promoter nor repetitive elements of 140 bp, as are found in vertebrate rDNA enhancers.

The tandem repeat AGGGTAGGGT is, in the fission yeast, a proximal activation sequence and activates basal transcription mediated by the sequence TGTGACTG

Ribosomal protein (rp) genes in the fission yeast Schizosaccharomyces pombe display two highly conserved sequence elements in the promoter region. The molecular dissection of these promoters revealed that basal transcription is not based on a TATA element. The sequence which promotes basal transcription is the conserved sequence CAGTCACA or the inverted form TGTGACTG, called the homol D box. Upstream of the homol D box a tandem repeat AGGGTAGGGT or the inverted form ACCCTACCCT appears in some promoters, called homol E. This element functions in the proximal arrangement with homol D as an activation sequence. A compilation of homol D and homol E sequences identified in other S.pombe promoters revealed that several putative polymerase II and polymerase III promoters display a homol D box or the homol E/homol D arrangement.

Phylogenesis of fission yeasts. Contradictions surrounding the origin of a century old genus

The phylogenesis of fungi is controversial due to their simple morphology and poor fossilization. Traditional classification supported by morphological studies and physiological traits placed the fission yeasts in one group with ascomycetous yeasts. The rRNA sequence comparisons, however, revealed an enormous evolutionary gap between Saccharomyces and Schizosaccharomyces. As shown in this review, the protein sequences also show a large gap which is almost as large as that separating Schizosaccharomyces from higher animals. Since the two yeasts share features (both cytological and molecular) in common which are also characteristic of ascomycetous fungi, their separation must have taken place later than the sequence differences may suggest. Possible reasons for the paradox are discussed. The sequence data also suggest a slower evolutionary rate in the Schizosaccharomyces lineage than in the Saccharomyces branch. In the fission yeast lineage two ramifications can be supposed. First S. japonicus (Hasegawaea japonica) branched off, then S. octosporus (Octosporomyces octosporus) separated from S. pombe.

Mutational analysis of Schizosaccharomyces pombe U4 snRNA by plasmid exchange

We have developed a system for testing mutations by plasmid exchange in the fission yeast Schizosaccharomyces pombe. This system has been used to test the requirement for different regions of the small nuclear RNA U4 in S. pombe. Surprisingly, five of seven deletion and substitution mutations tested in different regions of U4 prevent the accumulation of the mutant RNA. Substitution of the U4 sequence in stem 1 of the U4/U6 interaction domain allows accumulation of the mutant U4, but does not support viability. Two sequences with homology to the Sm binding site are found in the 3' region of S. pombe U4; substitution of the 3' sequence of the two does not interfere with accumulation or function of U4, indicating that the 5' sequence is the functional Sm-binding site.

Thirty-three nucleotides of 5' flanking sequence including the 'TATA' box are necessary and sufficient for efficient U2 snRNA transcription in Schizosaccharomyces pombe

We have sequenced the 5' flanking region of the U2 gene and compared this with the 5' flanking sequences of other snRNA genes from Schizosaccharomyces pombe. This revealed no regions of clear homology 5' to a region surrounding the 'TATA' box at -32 to -29. Deletion analysis shows that a 5' flanking region extending to only -33 is sufficient for accurate and efficient transcription of U2 in Schizosaccharomyces pombe.

A phylogenetic study of U4 snRNA reveals the existence of an evolutionarily conserved secondary structure corresponding to 'free' U4 snRNA

The nucleotide sequence of Physarum polycephalum U4 snRNA*** was determined and compared to published U4 snRNA sequences. The primary structure of P polycephalum U4 snRNA is closer to that of plants and animals than to that of fungi. But, both fungi and P polycephalum U4 snRNAs are missing the 3' terminal hairpin and this may be a common feature of lower eucaryote U4 snRNAs. We found that the secondary structure model we previously proposed for 'free' U4 snRNA is compatible with the various U4 snRNA sequences published. The possibility to form this tetrahelix structure is preserved by several compensatory base substitutions and by compensatory nucleotide insertions and deletions. According to this finding, association between U4 and U6 snRNAs implies the disruption of 2 internal helical structures of U4 snRNA. One has a very low free energy, but the other, which represents one-half of the helical region of the 5' hairpin, requires 4 to 5 kcal to be open. The remaining part of the 5' hairpin is maintained in the U4/U6 complex and we observed the conservation, in all U4 snRNAs studied, of a U bulge residue at the limit between the helical region which has to be melted and that which is maintained. The 3' domain of U4 snRNA is less conserved in both size and primary structure than the 5' domain; its structure is also more compact in the RNA in solution. In this domain, only the Sm binding site and the presence of a bulge nucleotide in the hairpin on the 5' side of the Sm site are conserved throughout evolution.

Immunoprecipitation distinguishes non-overlapping groups of snRNPs in Schizosaccharomyces pombe

The large number of snRNAs in the fission yeast Schizosaccharomyces pombe can be divided into four non-overlapping groups by immunoprecipitation with antibodies directed against mammalian snRNP proteins. 1) Of the abundant snRNAs, anti-Sm sera precipitate only the spliceosomal snRNAs U1, U2, U4, U5 and U6. Surprisingly, three Sm-sera tested distinguish between U2, U4 and U5 and U1 from S.pombe; one precipitating only U1 and two precipitating U2, U4 and U5 but not U1. 2) A group of 11 moderately abundant snRNAs are not detectably precipitated by human anti-Sm sera, but are specifically precipitated by monoclonal antibody H57 specific for the human B/B' polypeptides. From Aspergillus nidulans this antibody also precipitates at least 12 snRNAs. 3) Anti-(U3)RNP sera do not precipitate the above snRNAs, but precipitate at least 6 further snRNAs, including the homologues of U3. Both the anti-(U3)RNP sera and H57 also efficiently precipitate a number of discrete non-capped RNAs. 4) A small number of additional snRNAs are not detectably precipitated by any anti-serum tested to date, further analysis may identify antisera specific for these snRNPs. Western blots of purified snRNP proteins were used to identify the S.pombe proteins responsible for these immunoprecipitations. Several Sm-sera decorate a 16.3kD protein which may be a D protein homologue, monoclonal H57 decorates a further protein of 16kD and an anti-(U3)RNP serum decorates the homologue of the 36kD U3-specific protein, fibrillarin.

U1 small nuclear RNA from Schizosaccharomyces pombe has unique and conserved features and is encoded by an essential single-copy gene

We have cloned, sequenced, and disrupted the gene encoding U1 small nuclear RNA (snRNA) in the fission yeast Schizosaccharomyces pombe. This RNA is close in size and exhibits a high degree of secondary structure homology to human U1 RNA. There exist two regions of extended primary sequence identity between S. pombe and human U1 RNAs; the first comprises nucleotides involved in hydrogen bonding to 5' splice junctions, and the second is a single-stranded region which, in the human snRNA, forms part of the A protein binding site. S. pombe U1 lacks two nucleotides just following the 5' cap structure which are present in all other U1 homologs examined to date, and the region which corresponds to the binding site for the human 70K protein (molecular weight of 55,000) is more divergent than in other organisms. A putative upstream transcription signal is conserved in sequence and location among all loci encoding spliceosomal snRNAs in S. pombe with the exception of U6. Disruption of the single-copy U1 gene, designated snu1, reveals that this RNA is indispensable for viability.

U1 small nuclear RNA from Schizosaccharomyces pombe has unique and conserved features and is encoded by an essential single-copy gene

We have cloned, sequenced, and disrupted the gene encoding U1 small nuclear RNA (snRNA) in the fission yeast Schizosaccharomyces pombe. This RNA is close in size and exhibits a high degree of secondary structure homology to human U1 RNA. There exist two regions of extended primary sequence identity between S. pombe and human U1 RNAs; the first comprises nucleotides involved in hydrogen bonding to 5' splice junctions, and the second is a single-stranded region which, in the human snRNA, forms part of the A protein binding site. S. pombe U1 lacks two nucleotides just following the 5' cap structure which are present in all other U1 homologs examined to date, and the region which corresponds to the binding site for the human 70K protein (molecular weight of 55,000) is more divergent than in other organisms. A putative upstream transcription signal is conserved in sequence and location among all loci encoding spliceosomal snRNAs in S. pombe with the exception of U6. Disruption of the single-copy U1 gene, designated snu1, reveals that this RNA is indispensable for viability.