Two group I mitochondrial introns in the cob-box and coxI genes require the same MRS1/PET157 nuclear gene product for splicing

Summary We have studied the role of the product of the nuclear gene PET157 in mitochondrial pre-mRNA splicing. Cytoduction experiments show that a mitochondrial genome deleted for the three introns bI3, aI5 and aI6 is able to suppress the pet157-1 mutation: the strain recovers respiratory competency indicating that the product of the PET157 gene is only required for mitochondrial premRNA splicing. Characterization of the high molecular weight pre-mRNAs which accumulate in the pet157 mutant demonstrate that the product of the PET157 gene is required for the excision of two group I introns bI3 and aI6 (corresponding to aI5) located in the cob-box and coxI genes respectively. Furthermore, the pet157 mutant strain accumulates the bI3 maturase in the form of a polypeptide of 50K (p50) previously observed in mitochondrial mutants defective in the excision of bI3. We have shown by restriction analysis and allelism tests that the pet157-1 mutation is allelic to the nuclear mrs1 mutation, previously described as specifically blocking the excision of bI3. Finally, revertants obtained by the deletion of bI3 or aI6 from the mitochondrial DNA were isolated from the MRS1 disrupted allele, confirming the involvment of the product of the MRS1/PET157 gene in the excision of the two introns bI3 and aI6.     

In vitro mutagenesis of the mitochondrial leucyl-tRNA synthetase of S. cerevisiae reveals residues critical for its in vivo activities

Summary The mitochondrial leucyl-tRNA synthetase (mLRS) of Saccharomyces cerevisiae is involved in both mitochondrial protein synthesis and pre-mRNA splicing. We have created mutations in the regions HIGH, GWD and KMSKS, which are involved in ATP-, amino acid-and tRNA-binding respectively, and which have been conserved in the evolution of group I tRNA synthetases. The mutants GRD and NMSKS have no discernible phenotype. The mutants AWD and ARD act as null alleles and lead to the production of 100% cytoplasmic petites. The mutants HIGN, NIGH and KMSNS are unable to grown on glycerol even in the presence of an intronless mitochondrial genome and accumulate petites to a greater extent than the wild-type but less than 40%. Experiments with an imported bI4 maturase indicate that the lesion in these mutations primarily affects the synthetase and not the splicing functions.     

Prognosis for splicing factor PRPF8 retinitis pigmentosa,novel mutations and correlation between human and yeast phenotypes

PRPF8‐retinitis pigmentosa is said to be severe but there has been no overview of phenotype across different mutations. We screened RP patients for PRPF8 mutations and identified three new missense mutations, including the first documented mutation outside exon 42 and the first de novo mutation. This brings the known RP‐causing mutations in PRPF8 to nineteen. We then collated clinical data from new and published cases to determine an accurate prognosis for PRPF8‐RP. Clinical data for 75 PRPF8‐RP patients were compared, revealing that while the effect on peripheral retinal function is severe, patients generally retain good visual acuity in at least one eye until the fifth or sixth decade. We also noted that prognosis for PRPF8‐RP differs with different mutations, with p.H2309P or p.H2309R having a worse prognosis than p.R2310K. This correlates with the observed difference in growth defect severity in yeast lines carrying the equivalent mutations, though such correlation remains tentative given the limited number of mutations for which information is available. The yeast phenotype is caused by lack of mature spliceosomes in the nucleus, leading to reduced RNA splicing function. Correlation between yeast and human phenotypes suggests that splicing factor RP may also result from an underlying splicing deficit. © 2010 Wiley‐Liss, Inc.     

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. Received: 1 June / 10 July 1998     

Nuclear suppressors of the mitochondrial mutation oxi1-V25 in Saccharomyces cerevisiae

Summary Ten nuclear suppressors (nam mutations) of the mitochondrial oxi1-V25 ochre mutation are characterized. They restore to some extent the functional form of cytochrome oxidase, as judged by the results of growth tests, cytochrome spectra, cytochrome oxidase activities, and electrophoresis of the products of mitochondrial translation. The nam mutants can suppress some mit ^– mutations mapping in four mitochondrial genes. They act on a number of chain-terminating mit ^– mutations. When grown on glycerol medium some double mutants nam _x-V25 show an increased sensitivity to paromomycin, while the growth of others is stimulated by the drug. The nam mutants are probably omnipotent suppressors resulting from mutations in nuclear gene(s) specifying mitoribosomal protein(s).     

Synthesis and function of the mitochondrial intron —encoded bI4 RNA maturase from Saccharomyces cerevisiae

Summary We have analyzed the expression and function of the intron-encoded bI4 maturase when frame-shift mutations in the upstream exon alter the translational process. By constructing secondary cis-acting mutations within the b14 intron, we observed (1) that the bI4 maturase is still translated in the presence of the upstream mutation, albeit in very low amounts, and (2) that the limited amounts of bI4 maturase made under these conditions is no longer able to promote the splicing process of the aI4 intron. These observations, which further strengthen the maturase model, strongly suggest that bI4 maturase acts sequentially on the bI4 intron and then on the aI4 intron.     

A missense mutation in the chloride/proton ClC-5 antiporter gene results in increased expression of an alternative mRNA form that lacks exons 10 and 11. Identification of seven new CLCN5 mutations in patients with Dent’s disease

Mutations in the voltage-gated chloride/proton antiporter ClC-5 gene, CLCN5, are associated with Dent’s disease, an X-linked renal tubulopathy. Our interest is to identify and characterize disease-causing CLCN5 mutations, especially those that alter the splicing of the pre-mRNA. We analyzed the CLCN5 gene from nine unrelated Spanish Dent’s disease patients and their relatives by DNA sequencing. Pre-mRNA splicing analysis was performed by RT-PCR. Seven new mutations were identified, consisting of three missense mutations (C219R, F273L, and W547G), one splice-site mutation (IVS-2A > G), one deletion (976delG), and two non-sense mutations (Y140X and W314X). We found that missense mutation W547G also led to increased expression of a new alternative isoform lacking exons 10 and 11 that was expressed in several human tissues. In addition, we describe another novel CLCN5 splicing variant lacking exon 11 alone, which was expressed only in human skeletal muscle. We conclude that missense mutation W547G can also alter the expression levels of a CLCN5 mRNA splicing variant. This type of mutation has not been previously described in the CLCN5 gene. Our results support the importance of a routine analysis at the pre-mRNA level of mutations that are commonly assumed to cause single amino acids alterations.     

Mitochondrial and nuclear mitoribosomal suppressors that enable misreading of ochre codons in yeast mitochondria

Summary We describe studies on the action spectra of the mitochondrial suppressor mim3-1 and the three alleles of nuclear suppressor nam3. Their specificity of action was tested on 516 mit ^– mutations located in different mitochondrial genes. The degree of suppression was quantified by the extent of cytochrome oxidase and cytochrome b synthesis. We show that the four suppressors are allele-specific gene-nonspecific informational suppressors. They would act by changing the structure of the small mitoribosomal subunit which would decrease fidelity of translation enabling misreading of some but not all ochre codons. The implications of the results on the role of intron encoded maturases are discussed.     

Characterization of peroxisome-deficient mutants of Hansenula polymorpha

In the methylotrophic yeast Hansenula polymorpha, approximately 25% of all methanol-utilization-defective (Mut^-) mutants are affected in genes required for peroxisome biogenesis (PER genes). Previously, we reported that one group of per mutants, termed Pim^-, are characterized by the presence of a few small peroxisomes with the bulk of peroxisomal enzymes located in the cytosol. Here, we describe a second major group of per mutants that were observed to be devoid of any peroxisome-like structure (Per^-). In each Per^- mutant, the peroxisomal methanol-pathway enzymes alcohol oxidase, catalase and dihydroxyacetone synthase were present and active but located in the cytosol. Together, the Pim^- and Per^- mutant collections involved mutations in 14 different PER genes. Two of the genes, PER5 and PER7, were represented by both dominant-negative and recessive alleles. Diploids resulting from crosses of dominant per strains and wild-type H. polymorpha were Mut^- and harbored peroxisomes with abnormal morphology. This is the first report of dominant-negative mutations affecting peroxisome biogenesis.     

The effect of paromomycin and [psi] on the suppression of mitochondrial mutations in Saccharomyces cerevisiae

Summary Paromomycin has been found to suppress certain nonsense mutations located in several mitochondrial genes in yeast. In the mosaic genes, paromomycin preferentially suppresses those mutations located in the introns. There is a strong correlation between this phenotypic suppression by paromomycin and the genetic suppression due to various informational mitoribosomal suppressors. No effect of the cytoplasmic element [psi] on mitoribosomal protein synthesis was observed. This work provides strong evidence for the translation of mRNA maturase proteins from open reading frames of the mitochondrial introns.     

Binding of the CBP2 protein to a yeast mitochondrial group I intron requires the catalytic core of the RNA

The yeast CBP2 gene product is required for the splicing of the terminal intron (bI5) of the mitochondrial cytochrome b pre-mRNA in vivo. In vitro, bI5 RNA self-splices efficiently only at high MgCl2 concentrations (50 mM); at 5 mM MgCl2, efficient splicing requires purified CBP2 protein. To determine the sequences within bI5 recognized by the protein, we have constructed deletion and substitution mutants of the RNA. Their binding to CBP2 was assessed by their ability to inhibit protein-dependent splicing of the wild-type bI5 RNA. Several regions, including the large L1 and L8 loops, can be deleted without affecting binding. They can therefore be eliminated from consideration as critical recognition elements. In contrast, other changes prevent the RNA from binding CBP2 and also impair self-splicing. Thus, either the catalytic core contacts the protein directly, or the integrity of the core is required for proper display of other RNA sequences that bind the protein. The results are consistent with a model in which the CBP2 protein facilitates splicing by binding to and stabilizing the active structure of the RNA. However, a more specific model is proposed in which the protein specifically enhances Mg2+ binding required for catalysis.     

Genetic mapping of nuclear mucidin resistance mutations in Saccharomyces cerevisiae

Summary In the yeast Saccharomyces cerevisiae, two nuclear pleiotropic drug resistance mutations pdr3-1 (former designation muc ^PR) and pdr3-2 (former designation DRI9/T7) have been selected as resistant to mucidin and as resistant to chloramphenicol plus cycloheximide, respectively. The pdr3 mutations were found not to affect the plasma membrane ATPase activity measured in a crude membrane fraction. Meiotic mapping using strains with standard genetic markers revealed that mutation pdr3-1 is centromere linked on the left arm of chromosome II at a distance of 5.9 ± 3.3 cM from its centromere and 11.6 ± 3.1 cM from the marker pet9. The centromere linked pdr3-2 mutation exhibited also genetic linkage to pet9 with a map distance of 9.8 ± 3.2 cM. These results indicate that pdr3-1 and pdr3-2 are alleles of the same pleiotropic drug resistance locus PDR3 which is involved in the control of the plasma membrane permeability in yeast.     

Three nuclear genes suppress a yeast mitochondrial splice defect when present in high copy number

Summary A gene bank of a yeast wild type DNA in the high copy number vector YEp 13 was screened for recombinant plasmids which suppress the mitochondrial RNA splice defect exerted by mutant M1301, a –1 by deletion in the first intron of the mitochondrial COB gene (bIl). A total of 17 recombinant plasmids with similar suppressor activity were found. Restriction mapping and cross-hybridization of the inserts revealed that these 17 plasmids contain three different inserts, all lacking any extended sequence homology. Each of the inserts, when present in high copy number, has a similar suppressor activity: high in the presence of mutation M1301 in bll, a group II intron, and low but significant with the presence of few mutants in bI2 and bI3 of the COB gene, both of which are group I introns.     

Identification of the heterothallic mutation in HO-endonuclease of S. cerevisiae using HO/ho chimeric genes

HO-endonuclease initiates a mating-type switch in the yeast S. cerevisiae by making a doublestrand cleavage in the DNA of the mating-type gene, MAT. Heterothallic strains of yeast have a stable mating type and contain a recessive ho allele. Here we report the sequence of the ho allele; ho has four point mutations all of which encode for substitute amino acids. The fourth mutation is a leucine to histidine substitution within a presumptive zinc finger. Chimeric HO/ho genes were constructed in vivo by converting different parts of the sequence of the genomic ho allele to the HO sequence by gene conversion. HO activity was assessed by three bioassays: a mating-type switch, extinction of expression of an a-specific reporter gene, and the appearance of Can^r Ade^- papillae resulting from excision of an engineered Ty element containing the HO-endonuclease target site and a SUP4 ^o gene. We found that the replacement of the fourth point mutation in ho to the HO sequence restored HO activity to the chimeric endonuclease.     

Chromium resistant mutants of the yeast Saccharomyces cerevisiae

Summary Many strains of Saccharomyces cerevisiae do not grow on YPD agar containing 750 g/ml CrO₃. Mutants able to grow in the presence of 850 g/ml CrO₃ were obtained from such strains after UV mutagenesis. All of the mutants grew even in the presence of 1,000 /ml CrO₃. Chromium resistance was dominant or partial dominant over normal response, therefore it was impossible to determine the number of genetic loci by complementation analysis. However, the segregation of representative mutants strongly indicated that resistance was determined by single mutations. In addition, a limited analysis of recombination suggested that the chromium resistant mutations were located on a certain region of the yeast genome. Although it was determined that the mutants had slightly reduced rates of Cr⁶⁺ uptake, the exact mechanism of resistance was not discovered. According to the studies of interactions between resistant mutations and sensitive mutations, however, we have proposed a preliminary pathway of Cr⁶⁺ detoxification.     

Investigation of Batten Disease with the YeastSaccharomyces cerevisiae

TheCLN3gene, which encodes the protein whose absence is responsible for Batten disease, the most common inherited neurovisceral storage disease of childhood, was identified in 1995. The function of the protein, Cln3p, still remains elusive. We previously cloned theSaccharomyces cerevisiaehomolog to the humanCLN3gene, designatedBTN1,whose product is 39% identical and 59% similar to Cln3p. We report that yeast strains lacking Btn1p,btn1-Δ deletion yeast strains, are more resistant to -(−)-threo-2-amino-1-[p-nitrophenyl]-1,3-propanediol (ANP), in a pH-dependent manner. This phenotype is complemented in yeast by the humanCLN3gene. In addition, point mutations characterized in CLN3 from individuals with less severe forms of Batten disease, when introduced intoBTN1,altered the degree of ANP resistance. Severity of Batten disease due to mutations inCLN3and the degree of ANP resistance in yeast are related when the equivalent amino acid replacements in Cln3p and Btn1p are compared. These results indicate that yeast can be used as a model for the study of Batten disease.     

Identification of mutations in the Bruton's tyrosine kinase gene,including a novel genomic rearrangements resulting in large deletion,in Korean X-linked agammaglobulinemia patients

Mutations in the Bruton's tyrosine kinase (BTK) gene are responsible for X-linked agammaglobulinemia (XLA). We identified BTK mutations in six patients with presumed XLA from unrelated Korean families. Four out of six mutations were novel: two missense mutations (P565T, C154Y), a point mutation in a splicing donor site (IVS11+1G>A), and a large deletion (a 6.1-kb deletion including BTK exons 11–18). The large deletion, identified by long-distance PCR, revealed Alu-Alu mediated recombination extended from an Alu sequence in intron 10 to another Alu sequence in intron 18, spanning a distance of 6.1 kb. The two known mutations consisted of one missense (G462D) mutation, and a point mutation in a splicing acceptor site (IVS7−9A>G). This study suggests that large genomic rearrangements involving Alu repeats are few but an important component of the spectrum of BTK mutations.     

The UV excision-repair system of Saccharomyces cerevisiae is involved in the removal of methylcytosines formed in vivo by a cloned prokaryotic DNA methyltransferase

Summary DNA methyltransferase activity is not normally found in yeast. To investigate the response of Saccharomyces cerevisiae to the presence of methylated bases, we introduced the Bacillus subtilis SPR phage DNA-[cytosine-5] methyltransferase gene on the shuttle vector, YEp51. The methyltransferase gene was functionally expressed in yeast under the control of the inducible yeast GAL10 promoter. Following induction we observed a time-dependent methylation of yeast DNA in RAD ⁺ and rad2 mutant strains; the rad2 mutant is defective in excision-repair of UV-induced DNA damage. Analysis of restriction endonuclease digestion patterns revealed that the relative amount of methylated DNA was greater in the excision defective rad2 mutant than in the RAD ⁺ strain. These data indicate that the yeast excision-repair system is capable of recognizing and removing m⁵C residues.     

Courtship Bout Duration in per Circadian Period Mutants In Drosophila melanogaster

Mutations on the period locus of Drosophila melanogaster influence circadian periods as well as the rhythm in inter-pulse intervals in male courtship song; per ^L mutations produce long circadian periods and courtship song rhythms and per ^s mutations produce short circadian periods and courtship song rhythms. Thus, these mutations influence timing mechanisms over both long and short behavioral time horizons. We examined if the mean courtship duration of male Drosophila melanogaster cycles rhythmically, and if mutations at the period locus influence courtship bout duration. We measured the courtship bout durations of the following: (1) wild type Canton-S (per ⁺) males; (2) per ^L males; and (3)per ^s males. Rhythmicity of courtship bout duration could not be mathematically determined. Mean courtship bout duration did not differ among the three groups; thus, mutations at the period locus did not influence mean courtship duration. There was a nonsignificant trend for per ⁺ males that were successful at mating to have longer mean courtship duration than unsuccessful males.     

Isolation of the TRP2 and the TRP3 genes of Saccharomyces cerevisiae by functional complementation in yeast

Summary This paper describes the isolation of the TRP2 and the TRP3 genes of Saccharomyces cerevisiae. Two pools of plasmids consisting of BamHI and Sa1GI yeast DNA inserts into the bifunctional yeast — Escherichia coli vector pLC544 (Kingsman et al. 1979) were constructed in E. coli and used for the isolation of the two genes by selection for functional complementation of trp2 and trp3 mutations, respectively, in yeast.The TRP2 gene was isolated on a 6.2 kb BamHl and a 5.8 kb Sa1GI yeast DNA fragment which shared an identical 4.5 kb BamHI-SaIGI fragment. The TRP3 gene was located on a 5.2 kb BamHl fragment.By physical, genetic and physiological experiments it could be shown that the cloned yeast DNA fragments contained the whole structural sequences as well as the regulatory regions of the TRP2 and the TRP3 genes.