Cloning of Schizosaccharomyces pombe genes encoding the U1, U2, U3 and U4 snRNAs

Schizosaccharomyces pombe contains a group of five relatively abundant small nuclear RNAs (snRNAs) which are immunoprecipitated by human autoimmune antibodies of Sm serotype. The S. pombe RNAs hybridise to probes specific for human U1, U2, U4, U5 and U6 and in each case are similar in size to the human species. A further group of snRNAs from S. pombe are precipitated by antibodies against U3 containing ribonucleoprotein; the most abundant of these species hybridises to a probe specific for human U3. We have cloned the genes encoding U1, U2, U3 and U4 from S. pombe, together with that encoding another abundant snRNA, previously designated SPU43. U2 and U4 are encoded by single-copy genes, while two genes encode U3. The latter are not clustered, since a chromosomal Southern transfer shows them to lie on different chromosomes.     

The sequence of U3 from Schizosaccharomyces pombe suggests structural divergence of this snRNA between metazoans and unicellular eukaryotes.

We have cloned and sequenced one of the two genes encoding a 255 nucleotide small nuclear RNA from the fission yeast Schizosaccharomyces pombe. Based on the presence of four regions of primary sequence conservation and a predicted secondary structure similar to that previously proposed for human U3, we conclude that this molecule is the fission yeast homologue of this mammalian snRNA. The 5' one-third of fission yeast U3 is, however, unable to form a single stable hairpin as proposed for this region of the human RNA, but rather folds into two stem-loop structures. By analogy to fission yeast U3, we propose revised secondary structures containing two hairpins for this portion of the U3-like snRNAs from Saccharomyces cerevisiae and Dictyostelium discoideum. Thus, our data suggest that the structure of U3 snRNA has diverged in lower and higher eukaryotes.     

Characterization of two genes encoding putative cysteine synthase required for cysteine biosynthesis in Schizosaccharomyces pombe

Cysteine synthase catalyzes the formation of cysteine from O-acetylserine, and is the key enzyme for de novo cysteine biosynthesis in Schizosaccharomyces pombe. An examination of the S. pombe database revealed that two gene products are predicted to encode proteins homologous to eukaryotic cysteine synthases. Disruption of one of these candidates, cys1a+ (SPBC36.04), caused an obvious cysteine auxotrophy, while disruption of cys1b+ (SPAC3A12.17c) had no effect on the growth phenotype. Furthermore, overexpression of cys1b+ did not complement the cysteine auxotrophic phenotype of cys1a mutant cells. These results indicated that cys1a+, not cys1b+, primarily functions in the biosynthesis of cysteine in S. pombe cells. We constructed a bacterial-S. pombe shuttle vector containing cys1a+ as a selective marker gene. The combination of the cysteine auxotroph and new vector could be useful for the expression of a heterologous protein.     

Comprehensive cloning of Schizosaccharomyces pombe genes encoding translation elongation factors

In the course of the Schizosaccharomyces pombe cDNA project, we succeeded in cloning all the genes encoding translation elongation factors EF-1α, EF-1β, EF-1γ, EF-2 and EF-3. With the exception of the EF-1γ gene, the nucleotide (nt) sequence of S. pombe elongation factors has not been previously reported. For EF-1α, we found three genes whose amino acid (aa) sequences are quite homologous each other (99.5%), but whose 3′ untranslated regions (UTRs) are completely different. Southern blot indicated that those three EF-1α genes are located at different loci. Northern analysis indicated that one of three EF-1α genes was inducible with UV-irradiation, while the level of expression for another of three EF-1α genes was repressed by UV and heat-shock (HS) treatments. The aa sequence predicted from the nt sequence of the S. pombe EF-1β cDNA clone covered almost all the coding sequence (CDS) of EF-1β except the first methionine which has 55.4% identity with that of S. cerevisiae. We also identified two copies of S. pombe EF-2 genes. Their aa sequences deduced from nt sequences are identical (100%), but they have different 3′ UTRs. The location of these two EF-2 genes in different loci was proved by Southern analysis. The S. pombe EF-3 cDNA clone encoded only a third of the CDS from the C-terminal and its deduced aa sequence has a 76% identity with those of other yeasts and fungi.     

The 5S RNA genes of Schizosaccharomyces pombe.

The genomic arrangement and sequences of S. pombe 5S RNA genes are reported here. The 5S gene sequences appear to be dispersed within the genome, and are found independently of other rRNA genes. The sequences of two 5S genes examined show identical coding regions of 119 base pairs but have widely varying flanking sequences. A tRNAAsp gene is found in the 3' flanking region of one of the 5S genes. The tRNAAsp gene is faithfully transcribed in an X. laevis in vitro system, while the 5S genes are not transcribed in this system. The phylogenetic position of S. pombe is examined through comparison of 5S RNA sequences.     

Plant phosphoglucose isomerase genes lack introns and are expressed in Escherichia coli

Nuclear genes that appear to encode both cytosolic and plastid isozymes of phosphoglucose isomerase (PGI), an essential glycolytic enzyme, have been isolated from three diploid species of the annual wild flower genus Clarkia (Onagraceae). The genes do not contain introns and are expressed to varying degrees in Escherichia coli when cloned in either Charon 35 phage or pUC plasmid vectors. The PGI proteins synthesized in E. coli form dimers, are catalytically active, and their electrophoretic mobilities are similar to those of appropriate Clarkia PGIs. The nucleotide sequence of a gene encoding a plastid isozyme of C. unguiculata is described.     

Molecular genetic analysis of U2AF59 in Schizosaccharomyces pombe: differential sensitivity of introns to mutational inactivation.

The large subunit of the mammalian U2AF heterodimer (U2AF65) is essential for splicing in vitro. To expand our understanding of how this protein functions in vivo, we have created a null allele of the gene encoding the Schizosaccharomyces pombe ortholog, U2AF59, and employed it in a variety of genetic complementation assays. First, analysis of an extensive series of double amino acid substitutions indicates that this splicing factor is surprisingly refractory to mutations. Second, despite extensive structural conservation, we find that metazoan large subunit orthologs cannot substitute in vivo for fission yeast U2AF59. Third, because the activity of U2AF65 in vitro involves binding to the 3'' polypyrimidine tract, we examined the splicing of introns containing or lacking this feature in a U2AF59 mutant described here as well as a previously isolated temperature-sensitive mutant (Potashkin et al., 1993, Science 262:573-575). Our data indicate that all four introns tested, including two that lack extensive runs of pyrimidines between the branchpoint and 3'' splice site, show splicing defects upon shifting to the nonpermissive condition. In all cases, splicing is blocked prior to the first transesterification reaction in the mutants, consistent with the role inferred for human U2AF65 based on in vitro experiments.     

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.     

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.     

The mitochondrial genome of the fission yeast Schizosaccharomyces pombe: highly homologous introns are inserted at the same position of the otherwise less conserved cox1 genes in Schizosaccharomyces pombe and Aspergillus nidulans.

The DNA sequence of the second intron in the mitochondrial gene for subunit 1 of cytochrome oxidase (cox1), and the 3'' part of the structural gene have been determined in Schizosaccharomyces pombe. Comparing the presumptive amino acid sequence of the 3'' regions of the cox1 genes in fungi reveals similarly large evolutionary distances between Aspergillus nidulans, Saccharomyces cerevisiae and S. pombe. The comparison of exon sequences also reveals a stretch of only low homology and of general size variation among the fungal and mammalian genes, close to the 3'' ends of the cox1 genes. The second intron in the cox1 gene of S. pombe contains an open reading frame, which is contiguous with the upstream exon and displays all characteristics common to class I introns. Three findings suggest a recent horizontal gene transfer of this intron from an Aspergillus type fungus to S. pombe. (i) The intron is inserted at exactly the same position of the cox1 gene, where an intron is also found in A. nidulans. (ii) Both introns contain the highest amino acid homology between the intronic unassigned reading frames of all fungi identified so far (70% identity over a stretch of 253 amino acids). However, in the most homologous region, a GC-rich sequence is inserted in the A. nidulans intron, flanked by two direct repeats of 5 bp. The 37-bp insert plus 5 bp of direct repeat amounts to an extra 42 bp in the A. nidulans intron. (iii) TGA codons are the preferred tryptophan codons compared with TGG in all mitochondrial protein coding sequences of fungi and mammalia.(ABSTRACT TRUNCATED AT 250 WORDS)     

A gene family for acidic ribosomal proteins in Schizosaccharomyces pombe: two essential and two nonessential genes.

We have cloned the genes for small acidic ribosomal proteins (A-proteins) of the fission yeast Schizosaccharomyces pombe. S. pombe contains four transcribed genes for small A-proteins per haploid genome, as is the case for Saccharomyces cerevisiae. In contrast, multicellular eucaryotes contain two transcribed genes per haploid genome. The four proteins of S. pombe, besides sharing a high overall similarity, form two couples of nearly identical sequences. Their corresponding genes have a very conserved structure and are transcribed to a similar level. Surprisingly, of each couple of genes coding for nearly identical proteins, one is essential for cell growth, whereas the other is not. We suggest that the unequal importance of the four small A-proteins for cell survival is related to their physical organization in 60S ribosomal subunits.