Genomic exploration of the hemiascomycetous yeasts: 1. A set of yeast species for molecular evolution studies.

The identification of molecular evolutionary mechanisms in eukaryotes is approached by a comparative genomics study of a homogeneous group of species classified as Hemiascomycetes. This group includes Saccharomyces cerevisiae, the first eukaryotic genome entirely sequenced, back in 1996. A random sequencing analysis has been performed on 13 different species sharing a small genome size and a low frequency of introns. Detailed information is provided in the 20 following papers. Additional tables available on websites describe the ca. 20000 newly identified genes. This wealth of data, so far unique among eukaryotes, allowed us to examine the conservation of chromosome maps, to identify the 'yeast-specific' genes, and to review the distribution of gene families into functional classes. This project conducted by a network of seven French laboratories has been designated 'Génolevures'.

Genomic exploration of the hemiascomycetous yeasts: 3. Methods and strategies used for sequence analysis and annotation.

The primary analysis of the sequences for our Hemiascomycete random sequence tag (RST) project was performed using a combination of classical methods for sequence comparison and contig assembly, and of specifically written scripts and computer visualization routines. Comparisons were performed first against DNA and protein sequences from Saccharomyces cerevisiae, then against protein sequences from other completely sequenced organisms and, finally, against protein sequences from all other organisms. Blast alignments were individually inspected to help recognize genes within our random genomic sequences despite the fact that only parts of them were available. For each yeast species, validated alignments were used to infer the proper genetic code, to determine codon usage preferences and to calculate their degree of sequence divergence with S. cerevisiae. The quality of each genomic library was monitored from contig analysis of the DNA sequences. Annotated sequences were submitted to the EMBL database, and the general annotation tables produced served as a basis for our comparative description of the evolution, redundancy and function of the Hemiascomycete genomes described in other articles of this issue.

Genomic exploration of the hemiascomycetous yeasts: 4. The genome of Saccharomyces cerevisiae revisited.

Since its completion more than 4 years ago, the sequence of Saccharomyces cerevisiae has been extensively used and studied. The original sequence has received a few corrections, and the identification of genes has been completed, thanks in particular to transcriptome analyses and to specialized studies on introns, tRNA genes, transposons or multigene families. In order to undertake the extensive comparative sequence analysis of this program, we have entirely revisited the S. cerevisiae sequence using the same criteria for all 16 chromosomes and taking into account publicly available annotations for genes and elements that cannot be predicted. Comparison with the other yeast species of this program indicates the existence of 50 novel genes in segments previously considered as 'intergenic' and suggests extensions for 26 of the previously annotated genes.

Genomic exploration of the hemiascomycetous yeasts: 16. Candida tropicalis.

The genome of the diploid hemiascomycetous yeast Candida tropicalis, an opportunistic human pathogen and an important organism for industrial applications, was explored by the analysis of 2541 Random Sequenced Tags (RSTs) covering about 20% of its genome. Comparison of these sequences with Saccharomyces cerevisiae and other species permitted the identification and the analysis of a total of more than 1000 novel genetic elements of C. tropicalis. Moreover, the present study confirms that in C. tropicalis, the rare CUG codon is read as a serine and not a leucine. The sequences have been deposited at EMBL with the accession numbers AL438875-AL441602.

Genomic exploration of the hemiascomycetous yeasts: 18. Comparative analysis of chromosome maps and synteny with Saccharomyces cerevisiae.

We have analyzed the evolution of chromosome maps of Hemiascomycetes by comparing gene order and orientation of the 13 yeast species partially sequenced in this program with the genome map of Saccharomyces cerevisiae. From the analysis of nearly 8000 situations in which two distinct genes having homologs in S. cerevisiae could be identified on the sequenced inserts of another yeast species, we have quantified the loss of synteny, the frequency of single gene deletion and the occurrence of gene inversion. Traces of ancestral duplications in the genome of S. cerevisiae could be identified from the comparison with the other species that do not entirely coincide with those identified from the comparison of S. cerevisiae with itself. From such duplications and from the correlation observed between gene inversion and loss of synteny, a model is proposed for the molecular evolution of Hemiascomycetes. This model, which can possibly be extended to other eukaryotes, is based on the reiteration of events of duplication of chromosome segments, creating transient merodiploids that are subsequently resolved by single gene deletion events.

Genomic exploration of the hemiascomycetous yeasts: 19. Ascomycetes-specific genes.

Comparisons of the 6213 predicted Saccharomyces cerevisiae open reading frame (ORF) products with sequences from organisms of other biological phyla differentiate genes commonly conserved in evolution from 'maverick' genes which have no homologue in phyla other than the Ascomycetes. We show that a majority of the 'maverick' genes have homologues among other yeast species and thus define a set of 1892 genes that, from sequence comparisons, appear 'Ascomycetes-specific'. We estimate, retrospectively, that the S. cerevisiae genome contains 5651 actual protein-coding genes, 50 of which were identified for the first time in this work, and that the present public databases contain 612 predicted ORFs that are not real genes. Interestingly, the sequences of the 'Ascomycetes-specific' genes tend to diverge more rapidly in evolution than that of other genes. Half of the 'Ascomycetes-specific' genes are functionally characterized in S. cerevisiae, and a few functional categories are over-represented in them.

Genomic exploration of the hemiascomycetous yeasts: 20. Evolution of gene redundancy compared to Saccharomyces cerevisiae.

We have evaluated the degree of gene redundancy in the nuclear genomes of 13 hemiascomycetous yeast species. Saccharomyces cerevisiae singletons and gene families appear generally conserved in these species as singletons and families of similar size, respectively. Variations of the number of homologues with respect to that expected affect from 7 to less than 24% of each genome. Since S. cerevisiae homologues represent the majority of the genes identified in the genomes studied, the overall degree of gene redundancy seems conserved across all species. This is best explained by a dynamic equilibrium resulting from numerous events of gene duplication and deletion rather than by a massive duplication event occurring in some lineages and not in others.

Genomic exploration of the hemiascomycetous yeasts: 21. Comparative functional classification of genes.

We explored the biological diversity of hemiascomycetous yeasts using a set of 22000 newly identified genes in 13 species through BLASTX searches. Genes without clear homologue in Saccharomyces cerevisiae appeared to be conserved in several species, suggesting that they were recently lost by S. cerevisiae. They often identified well-known species-specific traits. Cases of gene acquisition through horizontal transfer appeared to occur very rarely if at all. All identified genes were ascribed to functional classes. Functional classes were differently represented among species. Species classification by functional clustering roughly paralleled rDNA phylogeny. Unequal distribution of rapidly evolving, ascomycete-specific, genes among species and functions was shown to contribute strongly to this clustering. A few cases of gene family amplification were documented, but no general correlation could be observed between functional differentiation of yeast species and variations of gene family sizes. Yeast biological diversity seems thus to result from limited species-specific gene losses or duplications, and for a large part from rapid evolution of genes and regulatory factors dedicated to specific functions.

Random exploration of the Kluyveromyces lactis genome and comparison with that of Saccharomyces cerevisiae.

The genome of the yeast Kluyveromyces lactis was explored by sequencing 588 short tags from two random genomic libraries (random sequenced tags, or RSTs), representing altogether 1.3% of the K. lactis genome. After systematic translation of the RSTs in all six possible frames and comparison with the complete set of proteins predicted from the Saccharomyces cerevisiae genomic sequence using an internally standardized threshold, 296 K.lactis genes were identified of which 292 are new. This corresponds to approximately 5% of the estimated genes of this organism and triples the total number of identified genes in this species. Of the novel K.lactis genes, 169 (58%) are homologous to S.cerevisiae genes of known or assigned functions, allowing tentative functional assignment, but 59 others (20%) correspond to S.cerevisiae genes of unknown function and previously without homolog among all completely sequenced genomes. Interestingly, a lower degree of sequence conservation is observed in this latter class. In nearly all instances in which the novel K.lactis genes have homologs in different species, sequence conservation is higher with their S.cerevisiae counterparts than with any of the other organisms examined. Conserved gene order relationships (synteny) between the two yeast species are also observed for half of the cases studied.

Functional analysis of YCL09C: evidence for a role as the regulatory subunit of acetolactate synthase.

We have analysed the function of the open reading frame (ORF) YCL09C. The deletion of this ORF from chromosome III does not affect the physiology of the corresponding yeast strain enough to give a distinct phenotype. Nevertheless a computational analysis reveals high homology between this ORF and the enterobacterial genes encoding the regulatory subunit of acetolactate synthase. We have therefore tested the possibility that yc109cp is the regulatory subunit of yeast acetolactate synthase by in vitro enzymatic analysis. The acetolactate synthase was previously shown to be retroinhibited by its final product valine. In Escherichia coli this retro-control is assured by the regulatory subunit. Using a yeast strain carrying a complete deletion of YCL09C, we have observed the loss of such retro-inhibition. These results together with the computational predictions show that YCL09C encodes the regulatory subunit of yeast acetolactate synthase.

Differential biochemical regulation of the URA7- and URA8-encoded CTP synthetases from Saccharomyces cerevisiae.

The URA7- and URA8-encoded CTP synthetases (EC 6.3.4.2, UTP:ammonia ligase (ADP-forming) are functionally overlapping enzymes responsible for the biosynthesis of CTP in the yeast Saccharomyces cerevisiae. URA8-encoded CTP synthetase was purified to apparent homogeneity by ammonium sulfate fractionation of the cytosolic fraction followed by chromatography with Q-Sepharose, Affi-Gel Blue, Mono Q, and Superose 6. The subunit molecular mass (67 kDa) of purified URA8-encoded CTP synthetase was in good agreement with the predicted size of the URA8 gene product. Antibodies raised against a fusion protein constructed from the coding sequences of the URA8 gene and expressed in Escherichia coli reacted with purified URA8-encoded CTP synthetase. Native URA8-encoded CTP synthetase existed as a dimer which oligomerized to a tetramer in the presence of its substrates UTP and ATP. Maximum URA8-encoded CTP synthetase activity was dependent on Mg2+ ions (Ka = 2.4 mM) and 2-mercaptoethanol at the pH optimum of 7.5. The enzyme followed saturation kinetics toward UTP (Km = 74 microM), ATP (Km = 22 microM), and glutamine (Km = 0.14 mM). GTP stimulated (Ka = 26 microM) URA8-encoded CTP synthetase activity 12-fold. CTP potently inhibited (IC50 = 85 microM) URA8-encoded CTP synthetase activity and, in addition, caused the dependence of activity toward UTP to become cooperative. The URA8-encoded CTP synthetase and the previously purified URA7-encoded CTP synthetase differed significantly with respect to several biochemical properties including turnover number, pH optimum, substrate dependences, and sensitivity to inhibition by CTP. The URA7-encoded CTP synthetase mRNA was 2-fold more abundant when compared with URA8-encoded CTP synthetase mRNA. Both CTP synthetase isoforms were maximally expressed in the exponential phase of growth.

Regulation of phospholipid biosynthesis in Saccharomyces cerevisiae by CTP.

In the yeast Saccharomyces cerevisiae, the major membrane phospholipid phosphatidylcholine is synthesized by the CDP-diacylglycerol and CDP-choline pathways. We examined the regulation of phosphatidylcholine synthesis by CTP. The cellular concentration of CTP was elevated (2.4-fold) by overexpressing CTP synthetase, the enzyme responsible for the synthesis of CTP. The overexpression of CTP synthetase resulted in a 2-fold increase in the utilization of the CDP-choline pathway for phosphatidylcholine synthesis. The increase in CDP-choline pathway usage was not due to an increase in the expression of any of the enzymes in this pathway. CDP-choline, the product of the phosphocholine cytidylyltransferase reaction, was the limiting intermediate in the CDP-choline pathway. The apparent Km of CTP (1.4 mM) for phosphocholine cytidylyltransferase was 2-fold higher than the cellular concentration of CTP (0.7 mM) in control cells. This provided an explanation of why the overexpression of CTP synthetase caused an increase in the cellular concentration of CDP-choline. Phosphatidylserine synthase activity was reduced in cells overexpressing CTP synthetase. This was not due to a transcriptional repression mechanism. Instead, the decrease in phosphatidylserine synthase activity was due, at least in part, to a direct inhibition of activity by CTP. These results show that CTP plays a role in the regulation of the pathways by which phosphatidylcholine is synthesized. This regulation includes the supple of CTP for the phosphocholine cytidylyltransferase reaction in the CDP-choline pathway and the inhibition of the phosphatidylserine synthase reaction in the CDP-diacylglycerol pathway.

Purification and characterization of CTP synthetase, the product of the URA7 gene in Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, CTP synthetase [EC 6.3.4.2; UTP:ammonia ligase (ADP-forming)] is the product of the URA7 gene. CTP synthetase was purified 503-fold to apparent homogeneity from cells bearing the URA7 gene on a multicopy plasmid that directed a 10-fold overproduction of the enzyme. The purification procedure included ammonium sulfate fractionation of the cytosolic fraction followed by chromatography with Sephacryl 300 HR, Q-Sepharose, Affi-Gel Blue, and Superose 6. The N-terminal amino acid sequence of purified CTP synthetase was identified and aligned perfectly with the deduced sequence of the URA7 gene. The minimum subunit molecular mass (68 kDa) of purified CTP synthetase was in good agreement with the size (64.7 kDa) of the URA7 gene product. Antibodies were raised against a maltose-binding protein-CTP synthetase fusion protein which immunoprecipitated CTP synthetase from wild-type cells. Immunoblot analysis was used to identify CTP synthetase in wild-type cells and cells bearing the URA7 gene on a multicopy plasmid. The results of gel filtration chromatography indicated that the size of native CTP synthetase was consistent with a dimeric structure for the enzyme. CTP synthetase oligomerized to a tetramer in the presence of its substrates UTP and ATP. Maximum CTP synthetase activity was dependent on magnesium ions (4 mM) and 2-mercaptoethanol at the pH optimum of 8.0. CTP synthetase exhibited positive cooperative kinetics with respect to UTP and ATP and negative cooperative kinetics with respect to glutamine and GTP. CTP synthetase was potently inhibited by the product CTP which also increased the positive cooperativity of the enzyme toward UTP.(ABSTRACT TRUNCATED AT 250 WORDS)

The sequence of 29.7 kb from the right arm of chromosome II reveals 13 complete open reading frames, of which ten correspond to new genes.

We have determined the complete nucleotide sequence of a 29.7 kb segment from the right arm of chromosome II carried by the cosmid alpha 61. The sequence encodes the 3' region of the IRA1 gene and 13 complete open reading frames, of which ten correspond to new genes and three (CIF1, ATPsv and CKS1) have been sequenced previously. The density of protein coding sequences is particularly high and corresponds to 84% of the total length. Two new genes encode membrane proteins, one of which is particularly large, 273 kDa. In one case (ATPsv), the comparison of our sequence and the published sequence reveals significant differences.

Use of synthetic lethal mutants to clone and characterize a novel CTP synthetase gene in Saccharomyces cerevisiae.

In the pyrimidine biosynthetic pathway, CTP synthetase catalyses the conversion of uridine 5'-triphosphate (UTP) to cytidine 5'-triphosphate (CTP). In the yeast Saccharomyces cerevisiae, the URA7 gene encoding this enzyme was previously shown to be nonessential for cell viability. The present paper describes the selection of synthetic lethal mutants in the CTP biosynthetic pathway that led us to clone a second gene, named URA8, which also encodes a CTP synthetase. Comparison of the predicted amino acid sequences of the products of URA7 and URA8 shows 78% identity. Deletion of the URA8 gene is viable in a haploid strain but simultaneous presence of null alleles both URA7 and URA8 is lethal. Based on the codon bias values for the two genes and the intracellular concentrations of CTP in strains deleted for one of the two genes, relative to the wild-type level, URA7 appears to be the major gene for CTP biosynthesis. Nevertheless, URA8 alone also allows yeast growth, at least under standard laboratory conditions.

Cloning, sequencing and characterization of the Saccharomyces cerevisiae URA7 gene encoding CTP synthetase.

The URA7 gene of Saccharomyces cerevisiae encodes CTP synthetase (EC 6.3.4.2) which catalyses the conversion of uridine 5'-triphosphate to cytidine 5'-triphosphate, the last step of the pyrimidine biosynthetic pathway. We have cloned and sequenced the URA7 gene. The coding region is 1710 bp long and the deduced protein sequence shows a strong degree of homology with bacterial and human CTP synthetases. Gene disruption shows that URA7 is not an essential gene: the level of the intracellular CTP pool is roughly the same in the deleted and the wild-type strains, suggesting that an alternative pathway for CTP synthesis exists in yeast. This could involve either a divergent duplicated gene or a different route beginning with the amination of uridine mono- or diphosphate.

A family of low and high copy replicative, integrative and single-stranded S. cerevisiae/E. coli shuttle vectors.

We describe a set of replicative, integrative and single-stranded shuttle vectors constructed from the pUC19 plasmid that we use routinely in our experiments. They bear a yeast selectable marker: URA3, TRP1 or LEU2. Replicative vectors carrying different yeast replication origins have been constructed in order to have plasmids based on the same construction with a high or low copy number per cell and with different mitotic stabilities. All the vectors are small in size, provide a high yield in Escherichia coli and efficiently transform Saccharomyces cerevisiae. These plasmids have many of the unique sites of the pUC19 multicloning region and many of them allow for the screening of plasmids with an insert by alpha-complementation. The nucleotide sequence of each of them is completely known.

Properties of genetic instability during the vegetative growth of Coprinus radiatus.

In Coprinus radiatus, a mutation at the Nic-2 locus unstable at meiosis has been previously described. Further studies have now shown that this mutation is also unstable, although with lower frequency, during vegetative growth. This 'vegetative instability', which is thermosensitive, is not a random process but an aggregative process, perhaps depending on the physiological state of the mycelium.

Self-fructification associated with genetic instability in Coprinus radiatus.

In the basidiomycete Coprinus radiatus, crosses gave rise with a high frequency to 2 types of self-fructifying progeny. The first type showed monokaryotic fruiting due to the occurrence of a mutation associated with the B1 incompatibility factor. The second type showed fruiting due to the presence of the 2 parental genomes in the original spore. Mutability and abnormal development of the life cycle are responsible for self-fructification. These features occurred in progeny of related strains harbouring a genetic instability located at the Nic-2 locus. High mutability, disturbance of the development of the life cycle and genetic instability are traits which resemble hybrid dysgenesis in Drosophila and meiotic dysgenesis in Phycomyces.