Cerevisiae Counterpart Research Articles

Lethality in Yeast of Trichothiodystrophy (TTD) Mutations in the Human Xeroderma Pigmentosum Group D Gene: IMPLICATIONS FOR TRANSCRIPTIONAL DEFECT IN TTD

Mutations in the human XPD gene result in a defect in nucleotide excision repair of ultraviolet damaged DNA and cause the cancer-prone syndrome xeroderma pigmentosum (XP). Besides XP, mutations in XPD can cause another seemingly unrelated syndrome, trichothiodystrophy (TTD), characterized by sulfur-deficient brittle hair, ichthyosis, and physical and mental retardation. To ascertain the underlying defect responsible for TTD, we have expressed the TTD mutant proteins in the yeast Saccharomyces cerevisiae and determined if these mutations can rescue the inviability of a rad3 null mutation. RAD3, the S. cerevisiae counterpart of XPD, is required for nucleotide excision repair and also has an essential role in RNA polymerase II transcription. Expression of the wild type XPD protein or the XPD Arg-48 protein carrying a mutation in the DNA helicase domain restores viability to the rad3 null mutation. Interestingly, the XPD variants containing TTD mutations fail to complement the lethality of the rad3 null mutation, strongly suggesting that TTD mutations impair the ability of XPD protein to function normally in RNA polymerase II transcription. From our studies, we conclude that XPD DNA helicase activity is not essential for transcription and infer that TTD mutations in XPD result in a defect in transcription.

Binding of basal transcription factor TFIIH to the acidic activation domains of VP16 and p53.

Acidic transcriptional activation domains function well in both yeast and mammalian cells, and some have been shown to bind the general transcription factors TFIID and TFIIB. We now show that two acidic transactivators, herpes simplex virus VP16 and human p53, directly interact with the multisubunit human general transcription factor TFIIH and its Saccharomyces cerevisiae counterpart, factor b. The VP16- and p53-binding domains in these factors lie in the p62 subunit of TFIIH and in the homologous subunit, TFB1, of factor b. Point mutations in VP16 that reduce its transactivation activity in both yeast and mammalian cells weaken its binding to both yeast and human TFIIH. This suggests that binding of activation domains to TFIIH is an important aspect of transcriptional activation.

Binding of basal transcription factor TFIIH to the acidic activation domains of VP16 and p53.

Acidic transcriptional activation domains function well in both yeast and mammalian cells, and some have been shown to bind the general transcription factors TFIID and TFIIB. We now show that two acidic transactivators, herpes simplex virus VP16 and human p53, directly interact with the multisubunit human general transcription factor TFIIH and its Saccharomyces cerevisiae counterpart, factor b. The VP16- and p53-binding domains in these factors lie in the p62 subunit of TFIIH and in the homologous subunit, TFB1, of factor b. Point mutations in VP16 that reduce its transactivation activity in both yeast and mammalian cells weaken its binding to both yeast and human TFIIH. This suggests that binding of activation domains to TFIIH is an important aspect of transcriptional activation.

Disruption of the Kluyveromyces lactis GGS1 gene causes inability to grow on glucose and fructose and is suppressed by mutations that reduce sugar uptake.

In the yeast Saccharomyces cerevisiae the GGS1 gene is essential for growth on glucose or other readily fermentable sugars. GGS1 is the same gene as TPS1 which was identified as encoding a subunit of the trehalose-6-phosphate synthase/phosphatase complex and it is allelic to the fdp1, byp1, glc6 and cif1 mutations. Its precise function in the regulation of sugar catabolism is unknown. We have cloned the GGS1 homologue from the distantly related yeast Kluyveromyces lactis. The KlGGS1 gene is 74% and 79% identical at the nucleotide and amino acid sequence level, respectively, to the S. cerevisiae counterpart. We also compared the sequence with the partly homologous products of the S. cerevisiae genes TPS2 and TSL1 which code for the larger subunits of the trehalose synthase complex and with a TSL1 homologue, TPS3, of unknown function. Multiple alignment of these sequences revealed several particularly well conserved elements. Disruption of GGS1 in K. lactis caused the same pleiotropic phenotype as in S. cerevisiae, i.e. inability to grow on glucose or fructose and strongly reduced trehalose content. We have also studied short-term glucose-induced regulatory effects related to cAMP and cAMP-dependent protein kinase, i.e. the cAMP signal, trehalase activation, trehalose mobilization and inactivation of fructose-1,6-bisphosphatase. These effects occur very rapidly in S. cerevisiae and are absent in the Scggs1 mutant. In K. lactis all these effects were much slower and largely unaffected by the Klggs1 mutation. On the other hand, glucose strongly induced pyruvate decarboxylase and activated the potassium transport system in K. lactis and both effects were absent in the Klggs1 mutant. Addition of glucose to galactose-grown cells of the Klggs1 mutant caused, as in S. cerevisiae, intracellular accumulation of free glucose and of sugar phosphates and a rapid drop of the ATP and inorganic phosphate levels. Glucose transport kinetics were the same for the wild type and the Klggs1 mutant in both derepressed cells and in cells incubated with glucose. We have isolated phenotypic revertants of the Klggs1 mutant for growth on fructose. The suppressors that we characterized had, to different extents, diminished glucose uptake in derepressed cells but cells incubated in glucose showed very different characteristics. The suppressor mutations prevented deregulation of glycolysis in the Klggs1 mutant but not the accumulation of free glucose. The mutants with higher residual uptake activity showed partially restored induction of pyruvate decarboxylase and activation of potassium transport.(ABSTRACT TRUNCATED AT 400 WORDS)

Comparative studies on O-acetylhomoserine sulfhydrylase: physiological role and characterization of the Aspergillus nidulans enzyme.

O-acetylhomoserine sulfhydrylase (OAH SHLase) from Aspergillus nidulans is an oligomeric protein with a broad substrate specificity with regard to sulfhydryl compounds. As its Saccharomyces cerevisiae counterpart the enzyme also reacts with O-acetylserine and is inhibited by carbonyl reagents but not by antiserum raised against the yeast enzyme. In contrast to Saccharomyces cerevisiae the enzyme is not essential for Aspergillus nidulans as indicated by the completely prototrophic phenotype of OAH SHLase-negative mutants. Its major physiological role in Aspergillus nidulans seems to be recycling of the thiomethyl group of methylthio-adenosine but it is also a constituent of the alternative pathway of cysteine synthesis.

Cloning the Cryptococcus neoformans TRP1 gene by complementation in Saccharomyces cerevisiae

We have cloned the phosphoribosyl anthranilate isomerase (PRAI)-encoding gene (TRP1) of Cryptococcus neoformans by genetic complementation in Saccharomyces cerevisiae. Sequence analysis of this gene revealed it to be 939 bp in length, and without known promoter or termination sequences. Unlike some of the filamentous fungi, where PRAI enzymatic activity is controlled by a trifunctional gene product, the C. neoformans PRAI appears to be unifunctional. PRAI of C. neoformans exhibits 39% amino acid (aa) sequence identity compared to the S. cerevisiae counterpart. The TRP1 gene of C. neoformans maps to different size chromosomes in strains with different serotypes. The cloning of this gene for vector constructions, and the demonstration that S. cerevisiae can be used as a surrogate for C. neoformans gene expression, should help with the molecular studies of this significant fungal pathogen in our increasing immunocompromised population.

Elongation factor 3 (EF-3) from Candida albicans shows both structural and functional similarity to EF-3 from Saccharomyces cerevisiae.

As with many other fungi, including the budding yeast Saccharomyces cerevisiae, the dimorphic fungus Candida albicans encodes the novel translation factor, elongation factor 3 (EF-3). Using a rapid affinity chromatography protocol, EF-3 was purified to homogeneity from C. albicans and shown to have an apparent molecular mass of 128 kDa. A polyclonal antibody raised against C. albicans EF-3 also showed cross-reactivity with EF-3 from S. cerevisiae. Similarly, the S. cerevisiae TEF3 gene (encoding EF-3) showed cross-hybridization with genomic DNA from C. albicans in Southern hybridization analysis, demonstrating the existence of a single gene closely related to TEF3 in the C. albicans genome. This gene was cloned by using a 0.7 kb polymerase chain reaction-amplified DNA fragment to screen to C. albicans gene library. DNA sequence analysis of 200 bp of the cloned fragment demonstrated an open reading frame showing 51% predicted amino acid identity between the putative C. albicans EF-3 gene and its S. cerevisiae counterpart over the encoded 65-amino-acid stretch. That the cloned C. albicans sequence did indeed encode EF-3 was confirmed by demonstrating its ability to rescue an otherwise non-viable S. cerevisiae tef3:HIS3 null mutant. Thus EF-3 from C. albicans shows both structural and functional similarity to EF-3 from S. cerevisiae.

Kluyveromyces contains a functional ABF1-homologue.

ABF1 is a multifunctional protein present in Saccharomyces cerevisiae, involved in transcription-activation and -repression as well as in DNA-replication. Several lines of evidence indicate the occurrence in the related species Kluyveromyces lactis of a protein having similar properties to those of ABF1 in S. cerevisiae. In order to identify conserved functional domains in ABF1, we have cloned and sequenced the gene encoding the ABF1-homologue from K. lactis. KIABF1 is much smaller than ScABF1 (54.6 vs. 81.7 kD). It exhibits extensive homology with its S. cerevisiae counterpart in the N-terminal region. The C-terminal domain however, is divergent, with the striking exception of a stretch of 20 amino acids, which is virtually identical in the two proteins. KIABF1 can substitute ABF1 in S. cerevisiae, emphasizing the conservation of the multiple functions of this protein.

Mitochondrial genome of Saccharomyces douglasii: genes coding for components of the protein synthetic apparatus

Mitochondrial genes coding for some components of the protein synthetic apparatus in S. douglasii have been studies in detail. A region containing stretches of high homology to the S. cerevisiae tRNA synthesis locus (TSL) and the tRNA(fmet) gene has been identified and sequenced. The organization of this region was very similar to that present in S. cerevisiae, including the presence of a possible transcription starting signal. The S. douglasii TSL gene is shorter due to several deletions which, however, do not involve the regions coding for RNA domains know to be required for the catalytic activity of mitochondrial RNAse P. The S. douglasii LSU rRNA gene has been shown to contain a typical group I intron highly homologous to its S. cerevisiae counterpart, except for the absence of the open reading frame which in S. cerevisiae codes for I-SceI endonuclease.

Yeast ribosomal proteins: VII. Cytoplasmic ribosomal proteins from Schizosaccharomyces pombe

The cytoplasmic ribosomal proteins from a fission yeast Schizosaccharomyces pombe were analysed by two-dimensional polyacrylamide gel electrophoresis. Seventy-three protein species were identified in the 80S ribosome, and named SP-S1 to SP-S33 and SP-L1 to SP-L40 in the small and large subunits, respectively. Many of these proteins could be correlated to those of Saccharomyces cerevisiae on the basis of their electrophoretic mobilities. Eleven proteins were isolated from the 80S ribosome, and their amino acid compositions were determined. Of these, SP-S6, SP-L1, SP-L12, SP-L15, SP-L17, SP-L27, SP-L36 and SP-L40c and d were sequenced from their amino-termini. SP-S28 and SP-L2 appear to have their amino-termini blocked. These results were compared with the data available for the S. cerevisiae and rat liver ribosomal proteins. The S. cerevisiae counterparts of the eight proteins mentioned above were found to be YS4, YL1, YL10, YL14, YL35, YL40 and YL44c and d, respectively. The rat liver counterparts of SP-S6, SP-L1, SP-L27 and SP-L40c and d were the rat S6, L4, L37 and P2, respectively. Comparison of the partial sequences of these ribosomal proteins suggests that these two yeasts are relatively far apart, phylogenetically.

Comparison of fungal mitochondrial introns reveals extensive homologies in RNA secondary structure

The complete sequences of nine Saccharomyces cerevisiae mitochondrial introns, six of which carry long open reading frames, have already been published. We have recently determined the sequence of an intron in the large ribosomal mitochondrial RNA of Kluyveromyces thermotolerans (Jacquier et al., in preparation), which we found to be closely related to its S. cerevisiae counterpart. This latter result prompted us to undertake a systematic search for possible homologous elements in the other, available sequences with the help of an original computer program. A previously unsuspected wealth of evolutionarily conserved sequences and secondary structures was thus uncovered. Seven at least of the available sequences may be folded up into elaborate secondary structure models, the cores of which are nearly identical. These models result in bringing together the exon-intron junctions into relatively close spatial proximity and looping out either all or most of the sequences in open reading frame, when present. These results and their possible implications with respect to the mechanism of splicing are discussed in the light of available genetic and biochemical data.

Genetic differences between Saccharomyces carlsbergensis and S. cerevisiae II. Restriction endonuclease analysis of genes in chromosome III

Chromosome III in a haploid Saccharomyces cerevisiae strain has been previously substituted for by its homeologue from S. carlsbergensis. With this chromosome substitution line the two homeologous chromosomes were shown to undergo crossing over only in a limited region, and to differ in nucleotide sequence at theHIS4 locus. In the present study the S. carlsbergensis chromosome III was compared to its S. cerevisiae homeologue at several additional loci. Cloned DNA from the S. cerevisiae lociHML, HIS4, LEU2, MAT andSUP-RL1 was used as hybridization probes in the analysis of nucleotide sequence homology at these loci andHMR. Virtually no differences were detected atSUP-RL1 andHMR, located in the region where the two chromosomes recombine, whereas considerable differences were found in the non-recombining part. The data are consistent with the assumption thatHML, MAT andHMR of the S. carlsbergensis chromosome are organized as in S. cerevisiae Segments X and Z1, which are involved in mating type interconversion, were closely homologous to their S. cerevisiae counterparts, whereas Y α as well as sequences outside theHML andMAT cassettes were substantially different.