Suppression of genomic instability by SLX5 and SLX8 in Saccharomyces cerevisiae

Replication forks can stall spontaneously at specific sites in the genome, and upon encountering DNA lesions resulting from chemical or radiation damage. In Saccharomyces cerevisiae proteins implicated in processing of stalled replication forks include those encoded by the SGS1, TOP3, MUS81, MMS4, SLX1, SLX4, SLX5/HEX3, and SLX8 genes. We tested the roles of these genes in suppressing gross chromosomal rearrangements (GCRs), which include translocations, large interstitial deletions, and loss of a chromosome arm with de novo telomere addition. We found that mus81, mms4, slx1, slx4, slx5, and slx8 mutants all have elevated levels of spontaneous GCRs, and that SLX5 and SLX8 are particularly critical suppressors of GCRs during normal cell cycle progression. In addition to increased GCRs, deletion of SLX5 or SLX8 resulted in increased relocalization of the DNA damage checkpoint protein Ddc2 and activation of the checkpoint kinase Rad53, indicating the accumulation of spontaneous DNA damage. Surprisingly, mutants in slx5 or slx8 were not sensitive to transient replication fork stalling induced by hydroxyurea, nor were they sensitive to replication dependent double-strand breaks induced by camptothecin. This suggested that Slx8 and Slx8 played limited roles in stabilizing, restarting, or resolving transiently stalled replication forks, but were critical for preventing the accumulation of DNA damage during normal cell cycle progression.     

Genetic effects of 5-azacytidine in Saccharomyces cerevisiae

The base analog 5-azacytidine induced a variety of genetic and epigenetic effects in different organisms. It was tested in two diploid strains of the yeast Saccharomyces cerevisiae to study the induction of point mutation, mitotic reciprocal crossing-over, mitotic gene conversion (strain D7) and mitotic aneuploidy (strain D61.M). It was used on cells growing in its presence for 4-5 generations. There was a strong induction of both types of mitotic recombination and point mutation. However, there was no induction of mitotic chromosomal malsegregation under the same conditions.     

Genetic and Physiological Aspects of Resistance to 5-Fluoropyrimidines in Saccharomyces cerevisiae

Mutants resistant to 5-fluorouracil, 5-fluorocytosine, and 5-fluorouridine were selected in yeast, and the mechanisms of their resistance were investigated. The investigated mutations map in seven different loci. (i) A mutation at the locus FUI 1 gives specifically resistance to 5-fluorouridine. (ii) Two loci are involved in a specific 5-fluorocytosine resistance: a mutation at locus FCY 1 produces a loss of cytosine deaminase activity; a mutation at locus FCY 2 results in the loss of the activity of a cytosine-specific permease. (iii) A mutation at the locus FUR 4 gives a simultaneous resistance to 5-fluorouracil and to 5-fluorouridine by loss in the activity of the uracil-specific permease. (iv) We found three types of mutants in the locus FUR 1. One is dominant and weakly resistant to 5-fluorouracil, 5-fluorocytosine, and 5-fluorouridine. The two others are recessive and are unable to catalyze one of the steps involved in uracil transformation into uridine 5'-monophosphate; this block-age explains their strong resistance to 5-fluorouracil and 5-fluorocytosine. Of these two mutants, one is resistant to 5-fluorouridine and the other is not. (v) Mutations at locus FUR 2 give resistance to 5-fluorouracil, 5-fluorocytosine, and 5-fluorouridine. These mutations are dominant and lead to a loss in the feedback regulation of the aspartic transcarbamylase activity by uridine triphosphate. (vi) The mutants FUR 3 are resistant to 5-fluorocytosine and 5-fluorouridine. They are dominant and physiologically related to the mutants of the locus FUR 1 but their mechanism of resistance is not understood.     

Interaction mapping between Saccharomyces cerevisiae Smc5 and SUMO E3 ligase Mms21

The multisubunit Smc5-Smc6 holocomplex (Smc5/6) plays a critical role in chromosome stability maintenance, DNA replication, homologous recombination, and double-stranded DNA damage repair. Smc5 and Smc6 form the core of the holocomplex, along with six non-SMC elements, for which most functions are not yet understood. Mms21 (Nse2), the relatively well-studied subunit in Smc5/6, contains a SP-like-RING finger motif on the C-terminus and was identified as a SUMO E3 ligase. Deletion of Mms21 is lethal; however, while deficient in DNA damage repair, SUMO ligase mutants remain viable. These functions of Mms21 in Smc5/6 are hard to address without understanding the interaction between Smc5 and Mms21. Previously, we systematically examined the architecture of Saccharomyces cerevisiae Smc5/6 and, using yeast two-hybrid methods, found that Mms21 interacts with the coiled-coil of Smc5. Later, crystallographic studies revealed the molecular arrangement of Mms21 with Smc5/6. For this study, we use a combination of limited proteolysis, mass spectrometry, and N-terminal sequencing to precisely define the interaction region of Smc5 with Mms21. In addition, using isothermal titration calorimetry, we find that Mms21 interacts with Smc5 in a 1:1 ratio with a K(d) of 0.68 μM. This combination of methods would be useful in examining the structure of any large multiprotein complex.     

Compartmentalization of the SUMO/RNF4 pathway by SLX4 drives DNA repair

1. Download : Download high-res image (212KB)
2. Download : Download full-size image

     

Metabolic flux analysis of the sterol pathway in the yeast Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is a useful model system for examining the biosynthesis of sterols in eukaryotic cells. To investigate underlying regulation mechanisms, a flux analysis of the ergosterol pathway was performed. A stoichiometric model was derived based on well known biochemistry of the pathway. The model was integrated in the Software COMPFlux which uses a global optimization algorithm for the estimation of intracellular fluxes. Sterol concentration patterns were determined by gas chromatography in aerobic and anaerobic batch cultivations, when the sterol metabolism was suppressed due to the absence of oxygen. In addition, the sterol concentrations were observed in a cultivation which was shifted from anaerobic to aerobic growth conditions causing the sterol pools in the cell to be filled. From time-dependent flux patterns, possible limitations in the pathway could be localized and the esterification of sterols was identified as an integral part of regulation in ergosterol biosynthesis.     

Genetic fine-structural analysis of the Saccharomyces cerevisiae alpha-pheromone receptor.

The alpha-pheromone receptor encoded by the STE2 gene contains seven potential transmembrane domains. Its ability to transduce the pheromone signal is thought to require the action of a G protein. As an initial step toward defining the structural features of the receptor required for its activity, we examined the phenotypic consequences of linker insertion mutations (12 bp) at 10 different sites in the STE2 gene. Three mutant classes, which correspond to three different regions of the receptor protein, were observed. 1) The two mutants affecting the C-terminal region (C-terminal mutants) were essentially wild type for mating efficiency, pheromone binding, and pheromone sensitivity. 2) The three mutants in the N-terminus mated with reduced efficiency, showed reduced pheromone binding capacity, and were partially defective in pheromone induction of agglutinin production and cell division arrest. Increased gene dosage of these N-terminal alleles suppressed their mutant phenotypes, whereas the sst2-1 mutation, which blocks adaptation to pheromone, did not result in suppression. Thus, the N-terminal mutants were apparently limited by receptor production, but not by the adaptation function SST2. 3) The five mutants in the central region containing the seven transmembrane segments (central mutants) were completely defective for mating and did not respond to pheromone, but could be distinguished by their ability to bind pheromone. Inserts in or near transmembrane domains 2 and 4 blocked pheromone binding, whereas inserts into transmembrane domains 1, 5, and 6 retained partial pheromone binding activity even though they failed to transduce a signal. The central mutants were not suppressed by increased gene dosage, and one mutant (ste2-/101) was partially suppressed by sst2-1. Furthermore, the central core mutants were also distinguished from one another in that three of the five mutants were able to partially complement the temperature sensitivity of ste2-3.     

Endogenous xylose pathway in Saccharomyces cerevisiae

The baker's yeast Saccharomyces cerevisiae is generally classified as a non-xylose-utilizing organism. We found that S. cerevisiae can grow on D-xylose when only the endogenous genes GRE3 (YHR104w), coding for a nonspecific aldose reductase, and XYL2 (YLR070c, ScXYL2), coding for a xylitol dehydrogenase (XDH), are overexpressed under endogenous promoters. In nontransformed S. cerevisiae strains, XDH activity was significantly higher in the presence of xylose, but xylose reductase (XR) activity was not affected by the choice of carbon source. The expression of SOR1, encoding a sorbitol dehydrogenase, was elevated in the presence of xylose as were the genes encoding transketolase and transaldolase. An S. cerevisiae strain carrying the XR and XDH enzymes from the xylose-utilizing yeast Pichia stipitis grew more quickly and accumulated less xylitol than did the strain overexpressing the endogenous enzymes. Overexpression of the GRE3 and ScXYL2 genes in the S. cerevisiae CEN.PK2 strain resulted in a growth rate of 0.01 g of cell dry mass liter(-1) h(-1) and a xylitol yield of 55% when xylose was the main carbon source.     

Genetic and physiological analysis of UV-sensitive mutants of Saccharomyces cerevisiae

The use of tetrad analysis and complementation tests indicates that the groups of UV-sensitive mutants assigned the labels radI and rad3 are alleles of two single genes involved in the process of cellular repair of UV-induced damage in the yeast Saccharomyces cerevisiae.     

Genetic analysis of inducible sexual agglutination ability in the yeast Saccharomyces cerevisiae

Genetic regulation of the inducibility of sexual agglutination ability in the yeast Saccharomyces cerevisiae was studied. Detailed analysis of the degree of sexual agglutination was carried out; it showed that a greater number of genes are involved in the regulation of inducible sexual agglutination in strain H1-0 than previously assumed. Although dominancy of inducible phenotype over constitutive was confirmed, the effectiveness of one gene changing the constitutive phenotype to the inducible seemed to be somewhat low. Quantity per cell of agglutination substances responsible for sexual agglutination increased as the agglutination ability became greater.