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J. S. Flick  M. Johnston 《Genetics》1992,130(2):295-304
Repression of GAL1 expression during growth on glucose is mediated in part by cis-acting promoter elements designated URSG. We show that oligonucleotides containing sequences from two regions of URSG confer glucose repression upon a heterologous promoter. Repression caused by URSG is dependent on trans-acting factors of the glucose repression pathway and is independent of orientation or location within a promoter, suggesting that URSG contains binding sites for a glucose-activated repressor protein(s). Genetic analysis identified three apparently novel genes (URR1, URR3 and URR4) that are specifically required for URSG-mediated repression and may encode such repressor proteins. Mutations in the URR genes suppress the defect in URSG derepression caused by a snf1 mutation.  相似文献   

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Specific DNA binding of GAL4, a positive regulatory protein of yeast   总被引:173,自引:0,他引:173  
E Giniger  S M Varnum  M Ptashne 《Cell》1985,40(4):767-774
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J. R. Erickson  M. Johnston 《Genetics》1993,135(3):655-664
Expression of the GAL genes of Saccharomyces cerevisiae is subject to glucose repression, a global regulatory mechanism that requires several gene products. We have isolated GAL83, one of these genes required for glucose repression. The sequence of the predicted Gal83 protein is homologous to two other yeast proteins, Sip1p and Sip2p, which are known to interact with the SNF1 gene product, a protein kinase required for expression of the GAL genes. High-copy clones of SIP1 and SIP2 cross-complement the GAL83-2000 mutation (as well as GAL82-1, a mutation in another gene involved in glucose repression), suggesting that these four genes may perform similar functions in glucose repression. Consistent with this hypothesis, a gal83 null mutation does not affect glucose repression, and only dominant or partially dominant mutations exist in GAL83 (and GAL82). Two other observations were made that suggests that GAL83 functions interdependently with GAL82 and REG1 (another gene involved in glucose repression) to effect glucose repression: 1) REG1 on a low-copy plasmid cross-complements GAL82-1 and GAL83-2000 mutations, and 2) all pairwise combinations of reg1, GAL82-1 and GAL83-2000 fail to complement one another. Such unlinked noncomplementation suggests that Gal83p, Gal82p and Reg1p may interact with one another. Possible roles for GAL83, GAL82 and REG1 are discussed in relation to SNF1, SIP1 and SIP2.  相似文献   

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Vernalization, the promotion of flowering by a prolonged period of low temperature, results in repression of the floral repressor FLOWERING LOCUS C (FLC) and in early flowering. This repression bears the hallmark of an epigenetic event: the low expression state is maintained over many cell division cycles, but expression is derepressed in progeny. We show that the two stages of the response of FLC to vernalization, the repression of FLC and the maintenance of the repression during growth at normal temperatures after vernalization, are mediated through different regions of the FLC gene. Both promoter and intragenic regions are required for the responses. We also identify a 75-bp region in the FLC promoter that, in addition to intragenic sequences, is required for expression in nonvernalized plants.  相似文献   

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We have identified in the promoter of the yeast FBP1 gene two sites able to bind nuclear proteins. These sites have a nucleotide sequence strongly similar to that of sites which bind the regulatory protein MIG1 in the promoters of GAL4 and SUC2. Deletions performed in the FBP1 promoter showed that one of the sites contributes to catabolite repression of this gene. In this same promoter, another region was identified with a strong effect on the catabolite repression of FBP1. In this region a sequence similar to the consensus for the binding site of the MIG1 protein was also present.  相似文献   

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Binding of the MIG1 repressor to the glucose-repressible GAL1 and GAL4 promoters was analyzed in vivo by cyclobutane dimer footprinting in two yeast strains that show different glucose repression responses. Mig1p binding to the two promoters in both strains was glucose-induced. In cells subject to rapid and stringent glucose repression (S288c), long-term Mig1p binding in glucose-grown cells was inhibited by the formation of a competing chromatin structure. Under conditions where glucose repression was only partially effective (gal80 - or low glucose), the chromatin structure did not form and long-term Mig1p binding was observed The same long-term binding of Mig1p was seen in cells of a different strain (W303A) that shows only partial glucose repression of the GAL1 promoter. We conclude from these experiments that Mig1p binding to glucose-repressed promoters is glucose-dependent but transient. We suggest that Mig1p functions at an early step in repression, but is not required to maintain the repressed state.  相似文献   

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