Basic phenotypic analysis of six novel yeast genes reveals two essential genes and one which affects the growth rate

Phenotypic analysis was performed on six mutants of Saccharomyces cerevisiae deleted in one of the following open reading frames (ORFs), located on chromosome II: YBR254c, YBR255w, YBR257w, YBR258c, YBR259w and YBR266c. Disruption of the ORFs was carried out in the diploid strain FY1679 using the kanMX4 marker flanked by short sequences homologous to the target locus. Tetrad analysis following sporulation of the heterozygous disruptants showed that YBR254c and YBR257w are essential genes. YBR257w was later characterized and renamed POP4, its gene product being involved in 5.8S rRNA and tRNA processing (Chu et al., 1997). The tetrad analysis performed for the heterozygous disruptant for YBR266c showed that two of the four viable spores gave colonies of smaller size, reflecting a slower growth rate. Growth analysis of the disruptant haploids confirmed this defect at 30 degrees C and also at 15 degrees C. However, complementation tests failed to confirm that the deletion of YBR266c is responsible for this growth defect. Growth analysis of the disruptant haploid ybr255w(delta) showed a slower growth rate on YPD and minimal medium at 15 degrees C. Finally, no phenotypic effect could be detected associated to the disruption of ORFs YBR258c and YBR259w.     

Disruption of 12 ORFs located on chromosomes IV,VII and XIV of Saccharomyces cerevisiae reveals two essential genes

We describe the generation of null-mutants of 12 open reading frames (ORFs), discovered during the systematic sequencing of the Saccharomyces cerevisiae genome. These ORFs are located on chromosome IV (YDL183c), on chromosome VII (YGL139w, YGL140c, YGL141w, YGR280c and YGR284c) or on chromosome XIV (YNL006w, YNR004w, YNR007c, YNR008w, YNR009w and YNR013c). Disruptants were generated using the PCR-based short flanking homology (SFH) strategy in yeast strain FY1679. Tetrad analysis, following sporulation of the heterozygous disruptants, revealed that YGR280c and YNL006w are essential genes for vegetative yeast growth in rich medium. The lethality of the two genes was confirmed by gene complementation analysis. The protein encoded by YNL006w (LST8) is now known to be involved in transport of permeases from the Golgi to the plasma membrane. Basic phenotypic analyses were performed on haploid disruptants from both mating types of 10 non-essential genes. One disruptant (YNR004w) revealed a slow growth rate on glucose-minimal medium at 15 degrees C. For each of the individual ORFs, a disruption cassette and the corresponding cognate gene were cloned into appropriate plasmids.     

Disruption and phenotypic analysis of six open reading frames from chromosome VII of Saccharomyces cerevisiae reveals one essential gene.

Six open reading frames (ORFs) located on chromosome VII of Saccharomyces cerevisiae (YGR205w, YGR210c, YGR211w, YGR241c, YGR243w and YGR244c) were disrupted in two different genetic backgrounds using short-flanking homology (SFH) gene replacement. Sporulation and tetrad analysis showed that YGR211w, recently identified as the yeast ZPR1 gene, is an essential gene. The other five genes are non-essential, and no phenotypes could be associated to their inactivation. Two of these genes have recently been further characterized: YGR241c (YAP1802) encodes a yeast adaptor protein and YGR244c (LSC2) encodes the beta-subunit of the succinyl-CoA ligase. For each ORF, a replacement cassette with long flanking regions homologous to the target locus was cloned in pUG7, and the cognate wild-type gene was cloned in pRS416.     

Inactivation of six genes from chromosomes VII and XIV of Saccharomyces cerevisiae and basic phenotypic analysis of the mutant strains

Within the frame of the EUROFAN project, aimed at the functional analysis of the novel ORFs revealed by the systematic sequencing of the Saccharomyces cerevisiae genome, we have inactivated six ORFs encoding putative proteins with unknown function in the two S. cerevisiae strains FY1679 and W303-1B. Five ORFs are located on chromosome VII (YGR250c, YGR251w, YGR260w, YGR262c, YGR263c) and one on chromosome XIV (YNL234w). The genes have been inactivated in the FY1679 strain by a strategy that makes use of deletion cassettes containing the kanMX4 module, which confers resistance to geneticin to yeast cells, and short flanking regions homologous to the target locus (SFH). Tetrad dissection of heterozygous mutants and basic phenotypic analysis of the spores revealed that ORF YGR251w is an essential gene, while the disruption of YGR262c causes a severe slow-growth phenotype. Deletion of the remaining ORFs did not give rise to a detectable phenotype in the mutant strains. For each ORF we have cloned, in the pUG7 plasmid, a replacement cassette that possesses long flanking regions homologous to the target locus (LFH) and, in the pRS416 plasmid, the cognate wild-type gene. The LFH replacement cassettes were used to inactivate the respective genes in the W303-1B strain. This work has been performed in the framework of the B0 Consortium of the EUROFAN I project.     

Disruption of six ORFs on Saccharomyces cerevisiae chromosome X: the YJL069c gene of unknown function is essential to cell viability.

The short flanking homology PCR strategy (Wach et al., 1994) was used to disrupt six open reading frames (ORFs) on chromosome X of diploid strains (FY1679 and W303) of the yeast Saccharomyces cerevisiae. Two of the six ORFs analysed (YJL069c and YJL066c) display no similarity to known sequences. Three others (YJL065c, YJL068c, and YJL070c) are similar to those respectively encoding the DNA polymerase epsilon subunit c, human esterase D and rat AMP deaminase 1. YJL071w has recently been identified as the ARG2 gene coding for acetylglutamate synthase. Inactivation of the YJL069c gene proved lethal and the yjl071w haploid disruptants were auxotrophic for arginine. For the four other gene inactivations, neither the heterozygous deletion diploids nor the corresponding haploid deletion mutants displayed any special phenotype when grown on rich glycerol or glucose medium or on synthetic minimal medium at three different temperatures, or on media containing compounds interfering with nucleic acid or protein synthesis. Mating and sporulation efficiencies were the same for the viable disruptants as for wild-type cells. The six kanMX4 disruption cassettes were cloned into the pUG7 vector and each of the cognate wild-type genes was inserted into the pRS416 centromeric plasmid. All strains and plasmids have been deposited in the EUROFAN collection (EUROSCARF, K. -D. Entian, Frankfurt, Germany).     

Disruption of six Saccharomyces cerevisiae ORFs on chromosome XII results in three lethal disruptants.

Six ORFs of unknown function from the left arm of chromosome XII of Saccharomyces cerevisiae were chosen for a reverse genetic approach to provide materials to assist in assignment of function. A two-step PCR using long-flanking homology was employed to amplify disruption cassettes consisting of a kanMX gene as selectable marker flanked by 250-350 bp long regions homologous to the target gene. The diploid strains FY1679 and CEN.PK2 were transformed with the replacement cassettes and transformants were selected for geneticin (G418) resistance. Correct targeting of the replacement cassettes at the genomic locus was verified by Southern blot analysis with the kanMX gene as a probe. Disruption cassettes were cloned in pUG7 plasmid for systematic gene inactivation in other yeast strains and the cognate genes were cloned in pRS416 plasmid for gene complementation studies. Sporulation and tetrad analysis of heterozygous disruptants showed that three of the six ORFs [YLR141w (RRN5), YLR145w and YLR147c (SMD3)] were essential genes that were complemented by their cognate genes. ylr146c Delta (spe4) homozygous diploids showed enhanced sporulation efficiency, whereas ylr147c Delta heterozygous diploids failed to sporulate in the FY1679 but not in the CEN.PK2 genetic background. The other two disruptants [ylr143w and ylr144c (acf2)] gave no phenotype.     

Disruption and basic phenotypic analysis of six novel genes from the right arm of chromosome XII of Saccharomyces cerevisiae

Six open reading frames (ORFs) of unknown function from the right arm of Saccharomyces cerevisiae chromosome XII were deleted in two genetic backgrounds by disruption cassettes with regions of short flanking homology. This work was carried out within the framework of the EUROFAN consortium. The SFH disruption cassettes, obtained by PCR, were made by amplification of the kanMX marker module with oligonucleotides containing approximately 40 bp of homology to either the promoter or translation terminator regions of the relevant ORF. Transformants resistant to geneticin (G418) were selected. The SFH disruption cassettes were cloned into a bacterial vector. Each cognate gene was also cloned into a yeast centromeric plasmid. Sporulation and tetrad analysis of the disrupted heterozygous strains revealed that ORF YLR153c (now known as ACS2) is essential. Basic phenotypic analysis was performed on haploid deletants of both mating types of the five non-essential ORFs, YLR082c (now known as SRL2), YLR149c, YLR151c, YLR152c and YLR154c. Plate growth tests on different media at 15 degrees C, 30 degrees C and 37 degrees C did not reveal any significant differences between parental and mutant cells. Mating and sporulation efficiencies were not affected in any of the viable disruptants as compared to wild-type cells.     

Basic functional analysis of six unknown open reading frames from Saccharomyces cerevisiae: four from chromosome VII and two from chromosome XV.

Six open reading frames (ORFs) of unknown function from Saccharomyces cerevisiae from the left arms of chromosomes VII and XV were disrupted by the short-flanking homology method in the diploid strains FY1679 and CENPK2. In each case, the entire ORF, with the exception of the first nucleotide of the start codon, was eliminated and replaced by the kanMX4 cassette. Correct integration of the disrupting marker was checked by colony PCR of the geneticin (G418)-resistant transformants. Sporulation followed by tetrad dissection of the diploids revealed that none of the ORFs encoded a product essential for the viability of either yeast strain. The neutral effect of these disruptions extended to mating and sporulation, since it was possible to create homozygous diploid disruptants that were capable of sporulation. Basic phenotypic analysis was carried out on all strains by growing them on three different media at three different temperatures and revealed no significant differences between disruptants and the parental strains. A cognate clone and a kanMX4 disruption cassette were created for five of the six ORFs by gap repair with specific long-flanking homology cassettes. For experimental reasons, the cognate clone and disruption cassette corresponding to the sixth ORF (YGL161w) had to be created by PCR.     

Disruption of six unknown open reading frames from Saccharomyces cerevisiae reveals two genes involved in vacuolar morphogenesis and one gene required for sporulation

In this report we describe the construction and basic phenotypic analysis of deletion mutants in six open reading frames (ORFs) of unknown function from the yeast Saccharomyces cerevisiae. Using the dominant kanMX marker and polymerase chain reaction (PCR) methods, deletion cassettes were constructed for five ORFs (YNL099c, YNL100w, YNL101w, YNL106c and YNL242w) located on chromosome XIV and one ORF (YOR109w) located on chromosome XV. The recovery of viable haploid deletant strains among the meiotic products of heterozygous deletants for each ORF demonstrated that none of the analysed ORFs was essential. With the exception of YNL242w, no alterations in growth characteristics or mating and sporulation efficiencies associated with deletion of the ORFs were observed. Homozygous diploid ynl242w delta cells obtained in three different genetic backgrounds were unable to sporulate, indicating that the product of this ORF is required for sporulation. Complementation of the sporulation defect by the cognate gene clone confirmed this observation. YNL106c and YOR109w are very similar and show strong sequence homology with a mammalian phosphatidylinositol-phosphate 5-phosphatase, synaptojanin, known to be involved in synaptic vesicle cycling. Strains bearing single and double deletions of YNL106c and YOR109w were seen to display abnormal vacuolar morphologies of varying degrees. Complementation tests indicated that YNL106c and YOR109w are redundant genes.     

Disruption of six novel genes from the left arm of chromosome XV of Saccharomyces cerevisiae and basic phenotypic analysis of the generated mutants

Six open reading frames (ORFs) of unknown function from the left arm of Saccharomyces cerevisiae chromosome XV were deleted in two genetic backgrounds by disruption cassettes with long flanking homology (LFH) (Wach, 1996), within the frame of the research project EUROFAN. The LFH disruption cassettes, obtained by PCR, were made by introducing the kanMX4 marker module between two fragments homologous to the promoter and terminator regions of a given ORF. Transformants resistant to geneticin (G418) were selected. The LFH disruption cassettes were cloned in a bacterial vector. Each cognate gene was also cloned in a centromeric plasmid. Correct deletion of each gene was verified by four different PCR reactions. Sporulation and tetrad analysis of heterozygous deletants revealed that ORF YOL102c is essential. The non-growing haploid spores gave rise to microcolonies. Basic phenotypic analyses were performed on haploid deletants of both mating types of the five non-essential ORFs, YOL018c, YOL098c, YOL101c, YOL104c and YOL105c. Plate growth tests on different media at 15 degrees C, 30 degrees C or 37 degrees C did not reveal any significant differences between parental and mutant cells. Mating and sporulation efficiencies were not affected in any of the viable disruptants as compared to wild-type cells.     

Disruption and basic functional analysis of five chromosome X novel ORFs of Saccharomyces cerevisiae reveals YJL125c as an essential gene for vegetative growth

We describe the disruption and basic functional analysis of five novel open reading frames (ORFs) discovered during the sequencing of the Saccharomyces cerevisiae genome: YJL118w, YJL122w, YJL123c, YJL124c, YJL125c, located on chromosome X. Disruptions have been realized using the long-flanking homology-PCR replacement strategy (LFH-PCR; Wach et al., 1996) in the FY1679 diploid strain. Sporulation and tetrad analysis of these heterozygous deletants were performed, as well as a functional analysis on the haploid deleted strains: different growth conditions (complete glucose and glycerol, minimal media) at three temperatures 15, 30 and 37 degrees C were tested. Analysis revealed YJL125c as an essential gene; the four other ORFs were non-essential and showed no particular phenotype. In addition, the five kanMX4 disruption cassettes were cloned in pUG7 vector. Finally, the five ORFs with their promoter and terminator regions were cloned in the centromeric yeast vector pRS416. The vectors containing the disruption cassettes, the cognate wild-type genes, as well as the deletant strains are available at the EU EUROFAN (EUROSCARF, Frankfurt, DE) genetic and stock centre.     

The deletion of six ORFs of unknown function from Saccharomyces cerevisiae chromosome VII reveals two essential genes: YGR195w and YGR198w

We have deleted six different ORFs of unknown function located on the right arm of Saccharomyces cerevisiae chromosome VII; namely, YGR187c/HGH1, YGR189c, YGR194c, YGR195w, YGR196c and YGR198w. No basic phenotypes could be attributed to the strains deleted in any of genes YGR187c/HGH1, YGR189c, YGR194c and YGR196c. These deletants did not show mating, sporulation or growth defects under any of the conditions tested. However, spores bearing deletions in either the YGR195w or YGR198w genes were unable to develop into macroscopical colonies. The YGR195w gene product shows significant homology with bacterial ribonuclease PH, an enzyme hitherto undescribed in yeasts, and its deletion causes a loss of viability after one to three rounds of cell division. Overexpression of this gene, using a tetracycline-regulatable promoter system, did not cause any effect on the cells. Contrary to what has been reported for prokaryotic homologs, this enzyme could play an essential role in yeast cell biology. The product encoded by the other essential ORF, YGR198w, shows no significant homology with any protein of known function in the databases. Spores bearing the deletion usually germinate and give rise to microcolonies of 50–100 non-viable cells. © 1998 John Wiley & Sons, Ltd.     

Annotation of unknown yeast ORFs by correlation analysis of microarray data and extensive literature searches

Changes in the expression of genes were used to elucidate the metabolic pathways and regulatory mechanisms that respond to environmental or genetic modifications. Results from previously published chemostat datasets were merged with novel data generated in the present study. ORFs displaying significant changes in expression that correlated with those of other ORFs were analysed using GO mapping tools and supplemented by literature information. The strategy developed was used to propose annotations for ORFs of unknown function. The following ORFs were assigned functions as a result of this study: YMR090w, YGL157w, YGR243w, YLR327c, YER121w, YFR017c, YGR067c, YKL187c, YGR236c (SPG1), YMR107w (SPG4), YMR206w, YER067w, YJL103c, YNL175C (NOP13) YJL200C, YDL070C (FMP16) and YGR173W.     

Disruption of six novel ORFs on the left arm of chromosome XII reveals one gene essential for vegetative growth of Saccharomyces cerevisiae

Deletion via PCR‐mediated gene replacement, together with basic functional and bioinformatic analyses, have been performed on six novel open reading‐frames (ORFs) on the left arm of chromosome XII of Saccharomyces cerevisiae(YLL033w, YLL032c, YLL031c, YLL030c, YLL029w and YLL028w). ORF deletion was realized using either a short‐flanking homology (SFH) or a long‐flanking homology (LFH) replacement cassette in the diploid strain FY1679. Sporulation and tetrad analysis showed that YLL031c is the only essential gene of the six. Microscopic examination of the non‐growing spores carrying a disrupted copy of the essential gene showed that most of them were blocked after one or two cell divisions with heterogeneous bud size. The standard EUROFAN growth tests failed to reveal any obvious phenotype resulting from the deletion of each the five non‐essential ORFs. Bioinformatic analysis revealed that YLL029w is probably an aminopeptidase for mitochondrial or nuclear protein processing and YLL028w may be involved in drug resistance in S. cerevisiae. Replacement cassettes, comprising the promoter and terminator regions of each of the six ORFs, were cloned into pUG7 and demonstrated to efficiently mediate gene replacement in an alternative diploid strain, W303. All the cognate gene clones were constructed, using either PCR products amplified from genomic DNA, or gap‐repair. All clones and strains generated have been deposited in the EUROFAN genetic stock centre (EUROSCARF, Frankfurt). Copyright © 1999 John Wiley & Sons, Ltd.     

Disruption and functional analysis of six ORFs on chromosome XV: YOL117w, YOL115w ( TRF4), YOL114c, YOL112w ( MSB4), YOL111c and YOL072w.

We have carried out the systematic disruption of six ORFs on chromosome XV, of Saccharomyces cerevisiae using the long flanking homology technique to replace each with the KanMX cassette; we have also constructed plasmids containing replacement cassettes and cognate clones for each ORF. Disruption of three of the ORFs-YOL117w, YOL114c, and YOL112w (also known as MSB4)-does not result in any noteworthy phenotype with respect to temperature or nutritional requirements, but yol112w mutants with an additional disruption of YNL293w, which encodes a protein similar to Yol112w, exhibit a slow growth phenotype. The protein specified by YOL114c shares similarity with the human DS-1 protein. Disruption of YOL115w confers slow growth, cold sensitivity and poor sporulation; this ORF has been described elsewhere as TRF4, which encodes a topoisomerase I-related protein. Cells with disruptions of YOL111c, whose product is weakly similar to the human ubiquitin-like protein GdX, are slightly impaired in mating. Mutants disrupted for YOL072w, the predicted product of which is unrelated to any protein of known function, grow slowly, are cold-sensitive and sporulate with reduced efficiency.     

Disruption and functional analysis of six ORFs on chromosome IV: YDL053c, YDL072c, YDL073w, YDL076c, YDL077c and YDL080c

Six open reading frames (ORFs) from chromosome IV, YDL053c, YDL072c, YDL073w, YDL076c, YDL077c and YDL080c, were disrupted using the long flanking homology technique (LFH) to replace each target locus with the KanMX4 selection marker. We have also constructed plasmids containing replacement cassettes (pYORC) and the cognate clones (pYCG) for each ORF. Disruption of five of the ORFs-YDL053c, YDL072c, YDL073w, YDL076c and YDL080c (THI3)-resulted in no distinctive phenotype with respect to temperature or nutritional requirements. However, disruption of YDL077c (also known as VAM6) exhibited an slow growth phenotype in minimal media and also in rich media containing glycerol as a carbon source. The homozygous disruptant diploid corresponding to this gene also failed to sporulate.     

Disruption and functional analysis of six ORFs of chromosome IV: YDL103c (QRI1), YDL105w (QRI2), YDL112w (TRM3), YDL113c, YDL116w (NUP84) and YDL167c (NRP1)

We have disrupted six ORFs (YDL103c, YDL105w, YDL112w, YDL113c, YDL116w and YDL167c) located on the left arm of chromosome IV. Except for YDL112w, the short flanking homology strategy was used to construct disruption cassettes using the KanMX4 marker. For YDL112w, a disruption cassette including the LEU2 gene was made. YDL103c and YDL105w are essential genes for vegetative growth. Disruption of YDL112w, YDL113c and YDL167c does not result in any detectable phenotype with the tests we used, while disruption of YDL116w confers slow growth, cryosensitivity and thermosensitivity, and the disrupted diploid homozygotes for the disruption failed to sporulate.