Constructing an open access economy-wide database for bioeconomy impact assessment in the European Union member states

Copper ion homeostasis is complicated in that copper is an essential element needed for a variety of cellular processes but is toxic at excess levels. To identify Candida albicans genes that are involved in resistance to copper ion toxicity, a library containing inserts of C. albicans genomic DNA was used to complement the copper sensitivity phenotype of a Saccharomyces cerevisiae cup1⌬ strain that is unable to produce Cup1p, a metallothionein (MT) responsible for high-level copper ion resistance. A P1-type ATPase (CPx type) that is closely related to the human Menkes and Wilson disease proteins was cloned. The gene encoding this pump was termed CRD1 (for copper resistance determinant). A gene encoding a 76-amino-acid MT similar to higher eukaryotic MTs in structure was also cloned, and the gene was termed CRD2. Transcription of the CRD1 gene was found to increase upon growth with increasing copper levels, while the CRD2 mRNA was expressed at a constant level. Strains with the CRD1 gene disrupted were extremely sensitive to exogenous copper and failed to grow in medium containing 100 M CuSO 4 . These crd1 strains also exhibited increased sensitivity to silver and cadmium, indicating that Crd1p is somewhat promiscuous with respect to metal ion transport. Although strains with the CRD2 gene disrupted showed reduced growth rate with increasing copper concentration, the crd2 mutants eventually attained wild-type levels of growth, demonstrating that CRD2 is less important for resistance to copper ion toxicity. Crd1p is the first example of a eukaryotic copper pump that provides the primary source of cellular copper resistance, and its ability to confer silver resistance may enhance the prevalence of C. albicans as a nosocomial pathogen.

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Mutations in a new Streptomyces coelicolor locus which globally block antibiotic biosynthesis but not sporulation

Adamidis

Riggle

Champness

1990

J Bacteriol

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Streptomyces coelicolor produces four known antibiotics. To define genetic elements that regulate antibiotic synthesis, we screened for mutations that visibly blocked synthesis of the two pigmented antibiotics and found that the mutant strains which we recovered were of two classes--double mutants and mutants in which all four antibiotics were blocked. The mutations in these multiply blocked strains define a new locus of S. coelicolor which we have named absA. The genetic location of absA, at 10 o'clock, is distinct from the locations of the antibiotic gene clusters and from other known mutations that affect antibiotic synthesis. The phenotype of the absA mutants suggests that all S. coelicolor antibiotic synthesis genes are subject to a common global regulation that is at least in part distinct from sporulation and that absA is a genetic component of the regulatory mechanism.

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ThechsBGene ofAspergillus nidulansIs Necessary for Normal Hyphal Growth and Development

Borgia

Iartchouk

Riggle

et al. 1996

Fungal Genetics and Biology

109

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Global negative regulation of Streptomyces coelicolor antibiotic synthesis mediated by an absA-encoded putative signal transduction system

et al. 1996

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Streptomycete antibiotic synthesis is coupled to morphological differentiation such that antibiotics are produced as a colony sporulates. Streptomyces coelicolor produces several structurally and genetically distinct antibiotics. The S. coelicolor absA locus was defined by four UV-induced mutations that globally blocked antibiotic biosynthesis without blocking morphological differentiation. We show that the absA locus encodes a putative eubacterial two-component sensor kinase-response regulator system. All four mutations lie within a single open reading frame, designated absA1, which is predicted to encode a sensor histidine kinase. A second gene downstream of absA1, absA2, is predicted to encode the cognate response regulator. In marked contrast to the antibiotic-deficient phenotype of the previously described absA mutants, the phenotype caused by disruption mutations in the absA locus is precocious hyperproduction of the antibiotics actinorhodin and undecylprodigiosin. Precocious hyperproduction of these antibiotics is correlated with premature expression of XylE activity in a transcriptional fusion to an actinorhodin biosynthetic gene. We propose that the absA locus encodes a signal transduction mechanism that negatively regulates synthesis of the multiple antibiotics produced by S. coelicolor.

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Transcriptional Regulation of MDR1 , Encoding a Drug Efflux Determinant, in Fluconazole-Resistant Candida albicans Strains through an Mcm1p Binding Site

Riggle

Kumamoto

2006

Eukaryot Cell

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Invasive Lesions Containing Filamentous Forms Produced by a Candida albicans Mutant That Is Defective in Filamentous Growth in Culture

et al. 1999

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Genetic analysis in fungi using restriction-enzyme-mediated integration

Riggle

Kumamoto

1998

Current Opinion in Microbiology

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Perry J. Riggle

ThechsDandchsEGenes ofAspergillus nidulansand Their Roles in Chitin Synthesis

Role of a Candida albicans P1-Type ATPase in Resistance to Copper and Silver Ion Toxicity

Mutations in a new Streptomyces coelicolor locus which globally block antibiotic biosynthesis but not sporulation

ThechsBGene ofAspergillus nidulansIs Necessary for Normal Hyphal Growth and Development

Global negative regulation of Streptomyces coelicolor antibiotic synthesis mediated by an absA-encoded putative signal transduction system

Transcriptional Regulation of MDR1 , Encoding a Drug Efflux Determinant, in Fluconazole-Resistant Candida albicans Strains through an Mcm1p Binding Site

Invasive Lesions Containing Filamentous Forms Produced by a Candida albicans Mutant That Is Defective in Filamentous Growth in Culture

Genetic analysis in fungi using restriction-enzyme-mediated integration

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