Ine Schaaff-Gerstenschläger scite author profile

The entire DNA sequence of chromosome III of the yeast Saccharomyces cerevisiae has been determined. This is the first complete sequence analysis of an entire chromosome from any organism. The 315-kilobase sequence reveals 182 open reading frames for proteins longer than 100 amino acids, of which 37 correspond to known genes and 29 more show some similarity to sequences in databases. Of 55 new open reading frames analysed by gene disruption, three are essential genes; of 42 non-essential genes that were tested, 14 show some discernible effect on phenotype and the remaining 28 have no overt function.

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Nuclear migration in Saccbaromyces cerevisiae is controlled by the highly repetitive 313 kDa NUM1 protein

Kormanec

Schaaff-Gerstenschläger

Zimmermann

et al. 1991

Molec. Gen. Genet.

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We have isolated a novel gene (NUM1) with unusual internal periodicity. The NUM1 gene encodes a 313 kDa protein with a potential Ca2+ binding site and a central domain containing 12 almost identical tandem repeats of a 64 amino acid polypeptide. num1-disrupted strains grow normally, but contain many budded cells with two nuclei in the mother cell instead of a single nucleus at the bud neck, while all unbudded cells are uninucleate. This indicates that most G2 nuclei divide in the mother before migrating to the neck, followed by the migration of one of the two daughter nuclei into the bud. Furthermore, haploid num1 strains tend to diploidize during mitosis, and homozygous num1 diploid or tetraploid cells sporulate to form many budded asci with up to eight haploid or diploid spores, respectively, indicating that meiosis starts before nuclear redistribution and cytokinesis. Our data suggest that the NUM1 protein is involved in the interaction of the G2 nucleus with the bud neck.

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TKL2, a second transketolase gene of Saccharomyces cerevisiae

Schaaff-Gerstenschläger

Mannhaupt

Vetter

et al. 1993

European Journal of Biochemistry

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Transketolase activity is indispensable for the generation of erythrose 4-phosphate and therefore necessary for the biosynthesis of the aromatic amino acids. Yeast mutants with a deletion of the transketolase gene, TKLl, can grow without aromatic amino acid supplement indicating an additional source of erythrose 4-phosphate in the cells. Here we describe the cloning of TKL2, a gene coding for a second transketolase enzyme in Saccharomyces cerevisiae. TKLl and TKL2, are auxotrophic for aromatic amino acids, indicating a complete block in the transketolase activity. Deletion of TKL2 alone does not lead to a significant phenotype, and transketolase activity is not reduced in these mutants. Overexpression of TKL2 on a multi-copy plasmid in a tkll background showed that TKL2 is functionally expressed: transketolase enzyme activity was detectable in the transformants and the protein reacts with anti-transketolase serum in Western blot analysis. In addition, transformation of the tkll tk12 double mutant with the TKL2 plasmid can compensate the growth defect on a medium without aromatic amino acids.

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Pentose-phosphate pathway in Saccharomyces cerevisiae: analysis of deletion mutants for transketolase, transaldolase, and glucose 6-phosphate dehydrogenase

Schaaff-Gerstenschläger¹,

Zimmermann²

1993

Curr Genet

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Deletion mutants for the yeast transketolase gene TKL1 were constructed by gene replacement. Transketolase activity was below the level of detection in mutant crude extracts. Transketolase protein could be detected as a single protein band of the expected size by Western-blot analysis in wild-type strains but not in the deletion mutant. Deletion of TKL1 led to a reduced but distinct growth in synthetic medium without an aromatic amino-acid supplement. We also isolated double and triple mutants for transketolase (tkl1), transaldolase (tal1), and glucose 6-phosphate dehydrogenase (zwf1) by crossing the different mutants. A tal1 tkl1 double mutant grew nearly like wild-type in rich medium. Only the tkl1 zwf1 double and the tal1 tkl1 zwf1 triple mutant grew more slowly than the wild-type in rich medium. This growth defect could be partly alleviated by the addition of xylulose but not ribose. The triple mutant still grew slowly on a synthetic mineral salts medium without a supplement of aromatic amino acids. This suggests the existence of an alternative but limited source of pentose phosphates and erythrose 4-phosphate in the tkl1 zwf1 double mutants. Hybridization with low stringency showed the existence of a sequence with homology to transketolase, possibly a second gene.

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The gene DIS2S1 is essential in Saccharomyces cerevisiae and is involved in glycogen phosphorylase activation

et al. 1991

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S. cerevisiae gene DIS2S1, which codes for a protein very similar to the catalytic subunit of mammalian protein phosphatase 1, was disrupted "in vitro". Diploid yeast cells were transformed and sporulated. Tetrad analysis demonstrated that disruption of DIS2S1 is lethal for the cell. Glycogen phosphorylase alpha and glycogen synthase activity ratio were measured in diploids carrying a disrupted allele of the gene. Phosphorylase was dramatically activated in mutant cells but, under the same conditions, glycogen synthase activity was essentially identical in both mutant and wild-type cells.

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Lysine¹⁴⁴ is essential for the catalytic activity of Saccharomyces cerevisiae transaldolase

Miosga

Schaaff-Gerstenschläger

Franken

et al. 1993

Yeast

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Replacement of lysine144 by glutamine in the pentose phosphate pathway enzyme transaldolase of Saccharomyces cerevisiae is associated with the complete loss of activity indicating the essential role in catalysis. Neither histidine nor cysteine is important for catalytic activity as proposed for the Candida utilis enzyme. Also we could not find any evidence for a half-site character of the enzyme as described for transaldolase of C. utilis. Therefore, the reaction mechanisms for the two enzymes are different.

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Sequence analysis of a 33·1 kb fragment from the left arm of Saccharomyces cerevisiae chromosome X, including putative proteins with leucine zippers, a fungal Zn(II)₂‐Cys₆ binuclear cluster domain and a putative α2‐SCB‐α2 binding site

Miosga

Schaaff-Gerstenschläger

Chalwatzis

et al. 1995

Yeast

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In the framework of the European BIOTECH project for sequencing the Saccharomyces cerevisiae genome, we have determined the nucleotide sequence of the left part of the cosmid clone 232 and the cosmid clone 233 provided by F. Galibert (Rennes Cedex, France). We present here 33,099 base pairs of sequence derived from the left arm of chromosome X of strain S288C. This sequence reveals 17 open reading frames (ORFs) with more than 299 base pairs, including the published sequences for ARG3, LIGTR/LIG1, ORF2, ACT3 and SCP160. Two other ORFs showed similarity with S. cerevisiae genes: one with the CAN1 gene coding for an arginine permease, and one with genes encoding the family of transcriptional activators containing a fungal Zn(II)2-Cys6 binuclear cluster domain like that found in Ppr1p or Ga14p. Both putative proteins contain a leucine zipper motif, the Can1p homologue has 12 putative membrane-spanning domains and a putative alpha 2-SCB-alpha 2 binding site. In a diploid disruption mutant of ORF J0922 coding for the transcriptional activator homologue, no colonies appeared before 10 days after transformation and then grew slowly. In contrast, haploid disruption mutants showed a growth phenotype like wild-type cells. One ORF showed weak similarity to the rad4 gene product of Schizosaccharomyces pombe and is essential for yeast growth. Five ORFs showed similarity to putative genes on the right arm of chromosome XI of S. cerevisiae. Two of them have similarity to each other and belong to a family of extracellular proteins that groups mammalian SCP/Tpx-1, insects Ag3/Ag5, plants PR-1 and fungi Sc7/Sc14.(ABSTRACT TRUNCATED AT 250 WORDS)

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Erratum to: Sequence of a 4.8 kb fragment of Saccharomyces cerevisiae chromosome II including three essential open reading frames

Baur

Schaaff-Gerstenschläger

Boles

et al. 1994

Yeast

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The above paper (Yeast 9 289-293, 1993) erroneously presented a non-updated sequence due to datatransmission errors. The corrected sequence is 4939 bp in length and has been deposited in the EMBL Data Library under the accession number X71329. Consequently the amino acid sequences of YBR12.03 and YBR12.05 changed.Corrected Figure 3. Corrected amino acid sequences and sequence comparisons of the putative proteins encoded by YBR12.03 (244 aa) and YBR12.05 (385 aa). The comparisons were made using the program GAP from the software package of the UWGCG. The vertical lines between the corresponding sequences mark conservative substitutions and identical amino acids. In A the upper amino acid sequence represents YBR12.03, the lower sequence Bacillus subrilis gene ribC (Swiss-Prot accession number P17618). The similarity/identity of both sequences is 48.5%/23.4%. Part B shows the comparison between YBR12.05 (upper sequence) and S. cerevisiae gene STIl (lower sequence, Swiss-Prot accession number PI 5705). The sequences are 334% similar/l3.8% identical.

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