Abstract
In yeast, the GAL genes encode the enzymes required for normal galactose metabolism. Regulation of these genes in response to the organism being challenged with galactose has served as a paradigm for eukaryotic transcriptional control over the last 50 years. Three proteins, the activator Gal4p, the repressor Gal80p, and the ligand sensor Gal3p, control the switch between inert and active gene expression. Gal80p, the focus of this investigation, plays a pivotal role both in terms of repressing the activity of Gal4p and allowing the GAL switch to respond to galactose. Here we present the three-dimensional structure of Gal80p from Kluyveromyces lactis and show that it is structurally homologous to glucose-fructose oxidoreductase, an enzyme in the sorbitol-gluconate pathway. Our results clearly define the overall tertiary and quaternary structure of Gal80p and suggest that Gal4p and Gal3p bind to Gal80p at distinct but overlapping sites. In addition to providing a molecular basis for previous biochemical and genetic studies, our structure demonstrates that much of the enzymatic scaffold of the oxidoreductase has been maintained in Gal80p, but it is utilized in a very different manner to facilitate transcriptional regulation.
Highlights
In yeast, the GAL genes encode the enzymes required for normal galactose metabolism
The GAL genetic switch in both the bakers’ yeast Saccharomyces cerevisiae and the milk yeast Kluyveromyces lactis is composed of an activator (Gal4p), an inhibitor (Gal80p), and a ligand sensor (Gal3p in S. cerevisiae or Gal1p in K. lactis)
While KlGal1p can complement both a Scgal1 and a Scgal3 mutation (3), ScGal3p cannot complement the non-inducible phenotype of a Klgal1 deletion mutant unless the KlGAL80 gene is replaced by ScGAL80 (4)
Summary
The GAL genes encode the enzymes required for normal galactose metabolism. Regulation of these genes in response to the organism being challenged with galactose has served as a paradigm for eukaryotic transcriptional control over the last 50 years. Gal4p from both S. cerevisiae (ScGal4p) and K. lactis (KlGal4p) will complement a gal4 mutation in either yeast (1, 2) despite the two proteins sharing comparatively little On the basis of these and other data it has been suggested that the S. cerevisiae GAL switch is activated when galactose and ATP bind to Gal3p in the cytoplasm.
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