James H. Crowley scite author profile

Considerable progress has been made in the selection and characterization of mutants that are defective in the synthesis of ergosterol in the yeast, Saccharomyces cerevisiae. Mutations in nearly every step of the yeast sterol biosynthetic pathway have been induced and selected. These mutants have been used to elucidate the sequential order of steps in sterol synthesis, to study the mode of action of antifungal agents and to determine the method of resistance of some pathogenic fungi, and to answer questions on the role of sterols in general cell biology. Physiological examination of ergosterol null mutants, lacking all biochemical activity attributed to the particular gene, supports a role for ergosterol in a number of critical functions in the organism. Among the physiological functions attributed to ergosterol are sparking and bulking requirements, involvement in amino acid and pyrimidine transport, resistance to antifungal agents and certain cations, and a requirement for respiratory activity. Those genetic null alleles discussed in this review are erg24, lacking the ability to reduce the delta 14 double bond; erg6, unable to methylate C-24; and erg3, defective in the C-5 desaturase. The different biochemical activities that are disrupted in the ergosterol mutants support a role for ergosterol in a number of critical functions in yeast.

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Transcriptional Regulation by Ergosterol in the Yeast Saccharomyces cerevisiae

Smith

Crowley

Parks

1996

Molecular and Cellular Biology

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Sterol biosynthesis in the yeast Saccharomyces cerevisiae is an energy-expensive, aerobic process, requiring heme and molecular oxygen. Heme, also synthesized exclusively during aerobic growth, not only acts as an enzymatic cofactor but also is directly and indirectly responsible for the transcriptional control of several yeast genes. Because of their biosynthetic similarities, we hypothesized that ergosterol, like heme, may have a regulatory function. Sterols are known to play a structural role in membrane integrity, but regulatory roles have not been characterized. To test possible regulatory roles of sterol, the promoter for the ERG3 gene, encoding the sterol C-5 desaturase, was fused to the bacterial lacZ reporter gene. This construct was placed in strains making aberrant sterols, and the effect of altered sterol composition on gene expression was monitored by ␤-galactosidase activity. The absence of ergosterol resulted in a 35-fold increase in the expression of ERG3 as measured by ␤-galactosidase activity. The level of ERG3 mRNA was increased as much as ninefold in erg mutant strains or wild-type strains inhibited in ergosterol biosynthesis by antifungal agents. The observed regulatory effects of ergosterol on ERG3 are specific for ergosterol, as several ergosterol derivatives failed to elicit the same controlling effect. These results demonstrate for the first time that ergosterol exerts a regulatory effect on gene transcription in S. cerevisiae. Ergosterol (Fig.

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A Mutation in a Purported Regulatory Gene Affects Control of Sterol Uptake in Saccharomyces cerevisiae

et al. 1998

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Aerobically growing wild-type strains of Saccharomyces cerevisiae are unable to take exogenously supplied sterols from media. This aerobic sterol exclusion is vitiated under anaerobic conditions, in heme-deficient strains, and under some conditions of impaired sterol synthesis. Mutants which can take up sterols aerobically in heme-competent cells have been selected. One of these mutations, designated upc2-1, gives a pleiotropic phenotype in characteristics as diverse as aerobic accumulation of sterols, total lipid storage, sensitivity to metabolic inhibitors, response to altered sterol structures, and cation requirements. During experiments designed to ascertain the effects of various cations on yeast with sterol alterations, it was observed that upc2-1was hypersensitive to Ca2+. Using resistance to Ca2+ as a screening vehicle, we cloned UPC2 and showed that it is YDR213W, an open reading frame on chromosome IV. This belongs to a fungal regulatory family containing the Zn(II)2Cys6 binuclear cluster DNA binding domain. The single guanine-to-adenine transition in upc2-1 gives a predicted amino acid change from glycine to aspartic acid. The regulatory defect explains the semidominance and pleiotropic effects of upc2-1.

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James H. Crowley

A Method of Studying Leukocytic Functions in Vivo

Biochemical and physiological effects of sterol alterations in yeast—A review

Transcriptional Regulation by Ergosterol in the Yeast Saccharomyces cerevisiae

A Mutation in a Purported Regulatory Gene Affects Control of Sterol Uptake in Saccharomyces cerevisiae

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