Identification of potential target genes for Adr1p through characterization of essential nucleotides in UAS1.

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Mol Cell Biol. 1994 June; 14(6): 3842-3852

Identification of potential target genes for Adr1p through characterization of essential nucleotides in UAS1.

C Cheng, N Kacherovsky, K M Dombek, S Camier, S K Thukral, E Rhim and E T Young

Department of Biochemistry, University of Washington, Seattle 98195.

ABSTRACT

Adr1p is a regulatory protein in the yeast Saccharomyces cerevisiaethat binds to and activates transcription from two sites ina perfect 22-bp inverted repeat, UAS1, in the ADH2 promoter.Binding requires two C2H2 zinc fingers and a region amino terminalto the fingers. The importance for DNA binding of each positionwithin UAS1 was deduced from two types of assays. Both methodsled to an identical consensus sequence containing only fouressential base pairs: GG(A/G)G. The preferred sequence, TTGG(A/G)GA,is found in both halves of the inverted repeat. The region ofAdr1p amino terminal to the fingers is important for phosphatecontacts in the central region of UAS1. However, no base-specificcontacts in this portion of UAS1 are important for DNA bindingor for ADR1-dependent transcription in vivo. When the central6 bp were deleted, only a single monomer of Adr1p was able tobind in vitro and activation in vivo was severely reduced. Onthe basis of these results and previous knowledge about theDNA binding site requirements, including constraints on thespacing and orientation of sites that affect activation in vivo,a consensus binding site for Adr1p was derived. By using thisconsensus site, potential Adr1p binding sites were located inthe promoters of genes known to show ADR1-dependent expression.In addition, this consensus allowed the identification of newpotential target genes for Adr1p.

Mol Cell Biol. 1994 June; 14(6): 3842-3852

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