A multi-component upstream activation sequence of the Saccharomyces cerevisiae glyceraldehyde-3-phosphate dehydrogenase gene promoter

Summary The majority of the activation potential of the Saccharomyces cerevisiae TDH3 gene promoter is contained within nucleotides –676 to –381 (relative to the translation initiation codon). An upstream activation sequence (UAS) in this region has been characterized by in vitro and in vivo assays and demonstrated to be composed of two small, adjacent DNA sequence elements. The essential determinant of this upstream UAS is a general regulatory factor 1 (GRF1) binding site at nucleotides –513 to –501. A synthetic DNA element comprising this sequence, or an analogue in which two of the degenerate nucleotides of the GRF1 site consensus sequence were altered, activated 5 deleted TDH3 and CYC1 promoters. The second DNA element of the UAS is a 7 by sequence which is conserved in the promoters of several yeast genes encoding glycolytic enzymes and occurs at positions –486 to –480 of the TDH3 promoter. This DNA sequence represents a novel promoter element: it contains no UAS activity itself, yet potentiates the activity of a GRF1 UAS. The potentiation of the GRFl UAS by this element occurs when placed upstream from the TATA box of either the TDH3 or CYC1 promoters. The characteristics of this element (termed GPE for GRF1 site potentiator element) indicate that it represents a binding site for a different yeast protein which increases the promoter activation mediated by the GRF1 protein. Site-specific deletion and promoter reconstruction experiments suggest that the entire activation potential of the –676 to –381 region of the TDH3 gene promoter may be accounted for by a combination of the GRF1 site and the GPE.     

Oxygen-dependent upstream activation sites of Saccharomyces cerevisiae cytochrome c genes are related forms of the same sequence.

In Saccharomyces cerevisiae, the two genes, CYC1 and CYC7, that encode the isoforms of cytochrome c are expressed at different levels. Oxygen regulation is mediated by the expression of the CYP1 gene, and the CYP1 protein interacts with both CYC1 upstream activation sequence 1 (UAS1) and CYC7 UASo. In this study, the homology between the CYP1-binding sites of both genes was investigated. The most noticeable difference between the CYC1 and CYC7 UASs is the presence of GC base pairs at the same positions in a repeated sequence in CYC7 compared with CG base pairs in CYC1. Directed mutagenesis changing these GC residues to CG residues in CYC7 led to CYC1-like expression of CYC7 both in a CYP1 wild-type strain and in a strain carrying the semidominant mutation CYP1-16 which reverses the oxygen-dependent expression of the two genes. Our results strongly support the hypothesis that the CYP1-binding sites in CYC1 and CYC7 are related forms of the same sequence and that the CYP1-16 protein has altered specificity for the variant forms of the consensus sequences in both genes.     

Yeast HAP1 activator binds to two upstream activation sites of different sequence

We show that the HAP1 protein binds in vitro to the upstream activation site (UAS) of the yeast CYC7 gene. Strikingly, this sequence bears no obvious similarity to the sequence bound by HAP1 at UAS1 of the CYC1 gene. The CYC1 and CYC7 sites compete for binding to HAP1 and have comparable affinities for the protein. The gross features of the interaction of HAP1 with the two sites are similar: multiple major and minor groove contacts, spanning 23 bp, on one helical face, with a back-side major groove contact toward one end. The precise positions of the contacts differ, however. A mutant form of HAP1, HAP1-18, abolishes the ability of the protein to bind to UAS1 but not CYC7 DNA. Possible mechanisms for how a single protein recognizes two sequences are discussed.