Multidrug resistance in Saccharomyces cerevisiae mainly results from the overexpression of genes coding for the membrane efflux pumps, the major facilitators and the ABC binding cassette transporters, under the control of key transcription regulators encoded by the PDR1 and PDR3 genes. Pdr3p transcriptional activator contains a weak activation domain near the N-terminal zinc finger, a central regulatory domain, and a strong activation domain near the carboxyl terminus. Here we report the results of the mutational analysis of the C-terminal region of Pdr3p. After in vitro mutagenesis of the PDR3 gene six single amino acid substitutions were identified and resulted in resistance to cycloheximide, sulfomethuron methyl, 4-nitroquinoline oxide, fluconazole, mucidin, chloramphenicol and oligomycin. All the C-terminal pdr3 mutant alleles also conferred multidrug resistance in the presence of the wild-type PDR3 gene. The pdr3 mutations resulted in overexpression of both the PDR3 and PDR5 genes as revealed by transactivation experiments involving the PDR3-lacZ and PDR5-lacZ fusion genes and Western blot analyses using antibodies against Pdr5p. Most of the C-terminal pdr3 mutations were found in two sequence stretches exhibiting a high degree of amino acid identity with Pdr1p indicating that they might play a significant role in protein-protein interactions during the initiation of transcription of genes involved in multidrug resistance.
The 90 kDa heat shock protein, Hsp90, is an abundant molecular chaperone participating in the cytoprotection of eukaryotic cells. Here we analyzed the involvement of Hsp90 in the maintenance of cellular integrity using partial cell lysis as a measure. Inhibition of Hsp90 by geldanamycin, radicicol, cisplatin, and novobiocin induced a significant acceleration of detergent-and hypotonic shock-induced cell lysis. The concentration and time dependence of cell lysis acceleration was in agreement with the Hsp90 inhibition characteristics of the N-terminal inhibitors, geldanamycin and radicicol. Glutathione and other reducing agents partially blocked geldanamycin-induced acceleration of cell lysis but were largely ineffective with other inhibitors. Indeed, geldanamycin treatment led to superoxide production and a change in membrane fluidity. When Hsp90 content was diminished using anti-Hsp90 hammerhead ribozymes, an accelerated cell lysis was also observed. Hsp90 inhibition-induced cell lysis was more pronounced in eukaryotic (yeast, mouse red blood, and human T-lymphoma) cells than in bacteria. Our results indicate that besides the geldanamycin-induced superoxide production, and a consequent increase in cell lysis, inhibition or lack of Hsp90 alone can also compromise cellular integrity. Moreover, cell lysis after hypoxia and complement attack was also enhanced by any type of Hsp90 inhibition used, which shows that the maintenance of cellular integrity by Hsp90 is important in physiologically relevant lytic conditions of tumor cells.The 90 kDa heat shock protein (Hsp90) 1 is a central part of a chaperone meshwork chaperoning a large number of substrate proteins (1-5). Besides being a partner of a large number of co-chaperones and substrates, Hsp90 binds to filamentous actin and tubulin (6 -8) and the involvement of the cytoskeleton in the traffic of Hsp90 substrates has also been demonstrated (5, 9). Together with other chaperones, like Hsp27 and Hsp70, Hsp90 is involved in cytoprotection (10 -12).Cell lysis is one of the most commonly used methods to test cellular integrity. Moreover, lysis rate anomalies (13,14) together with diffusional anomalies (15, 16) were used as important arguments for the organization of the cytoplasm. Since cellular integrity is preserved after a partial cell lysis to a large extent (13,14), partial lysis provides a highly sensitized, but still somewhat organized cellular system, where the contribution of various components to both the cytoplasmic organization and cellular stability can be studied.The original aim of the present study was to examine whether Hsp90 inhibition induces any change in the rate of cell lysis induced by mild detergent treatment or hypotonic shock. The rationale behind these experiments was to test, whether Hsp90, a cytoprotective chaperone, binding to "thousand-andone" substrates and other proteins is involved in the maintenance of cellular integrity (17), and whether its inhibition renders cells more "lysis-prone." The first experiments were very promising: geldan...
Selenate-resistant mutants were obtained from several strains of Schizosaccharomyces pombe. The obtained mutants all belonged to the same genetic complementation group. They were low in sulphate uptake activity and in ATP sulphurylase activity. They grew on medium containing sulphite, thiosulphate, cysteine or glutathione but not methionine as the sole source of sulphur. From these results, the mutants were concluded to carry mutations in the ATP sulphurylase gene. Inability of the mutants to utilize methionine as a sulphur source is rationalized by the absence of the reverse transsulphurylation pathway in this organism; wild type strains must utilize methionine as a sulphur source after it is degraded to give rise to sulphate.
Sulphur plays an important role in yeasts, especially in the biosynthesis of methionine and cysteine. The inorganic sulphur source, sulphate, is taken up by the cells via the sulphate-permease(s). After its transport, it is activated and subsequently reduced to sulphide or serves as a donor for sulphurylation reactions. Selenate anion (SeO4(2-)), which has the same metabolic pathway as sulphate, is toxic for the cells of Schizosaccharomyces pombe. We isolated selenate resistant mutants which cannot utilize sulphate, therefore they need organic sulphur source for growth. One of the selenate resistant mutants was successively transformed with S. pombe genomic libraries and the gene complementing the selenate resistance was identified as that of coding for the ATP-sulphurylase enzyme.
The ATP sulphurylase gene of Schizosaccharomyces pombe has been cloned by complementation of cysteine auxotrophy of a selenate-resistant mutant, which supposedly had a defect in ATP sulphurylase. A sulphate nonutilizing (cysteine auxotrophic) and selenate-resistant mutant of S. pombe was transformed with a wild-type S. pombe genomic library and sulphate-utilizing clones were isolated. The open reading frame encoding the ATP sulphurylase enzyme was found to be responsible for the restoration of sulphate assimilation. Transformants became as sensitive for selenate as the wild-type strain and produced a comparable amount of ATP sulphurylase as the prototrophic strains. The cloned ATP sulphurylase gene (sua1) proved to be an efficient selection marker in an ARS vector, when different isogenic or nonisogenic S. pombe selenate-resistant mutants were used as cloning hosts. Complementation of sua1- mutations by sua1-bearing multicopy vectors functions as a useful dual positive and negative selection marker. The cloned sua1 gene also complemented the met3 (ATP sulphurylase deficient) mutation in Saccharomyces cerevisiae.
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