The Zap1 transcription factor is a central player in the response of yeast to changes in zinc status. Previous studies identified over 80 genes activated by Zap1 in zinc-limited cells. In this report, we identified 36 genes repressed in a zinc-and Zap1-responsive manner. As a result, we have identified a new mechanism of Zap1-mediated gene repression whereby transcription of the MET3, MET14, and MET16 genes is repressed in zinc-limited cells. These genes encode the first three enzymes of the sulfate assimilation pathway. Zinc is an essential nutrient for all organisms because it is required as a structural or catalytic cofactor by many proteins. It was recently estimated that about 10% of the ϳ30,000 proteins encoded by the human genome need zinc for their function (1). Zinc deficiency perturbs a wide variety of processes and is associated with many disease symptoms in mammals (2). Excess zinc can also be toxic to cells (3). Thus, organisms have evolved with mechanisms to tightly control intracellular zinc levels. We have examined cellular responses to zinc deficiency in the yeast Saccharomyces cerevisiae (4, 5). In this yeast, the Zap1 transcription factor is a central player in their response to zinc deficiency (6). For many of its target genes, Zap1 acts as an activator of transcription and increases gene expression when zinc levels are low. To perform this function, Zap1 binds to one or more zinc-responsive elements (ZREs) 2 in the promoters of its target genes. The consensus sequence for a ZRE is ACCTT-NAAGGT (4, 7). Previous studies have identified a large number of Zap1 target genes in the yeast genome (4,5,8,9). Many activated Zap1 targets contribute to zinc homeostasis. For example, Zap1 induces its own expression by positive autoregulation (10). In addition, ZRT1, ZRT2, and FET4 encode transporter proteins responsible for zinc uptake and are targets of Zap1 activation (11-13). Zap1 also induces expression of ZRT3 and ZRC1, which encode vacuolar zinc transporters involved in controlling zinc storage in the vacuole (14). In addition to maintaining zinc homeostasis, Zap1 regulates the expression of genes that play a more adaptive role in zinc-limited cells. For example, Zap1 controls the level of several lipid biosynthetic enzymes (DPP1, PIS1, EKI1, and CKI1) to maintain the levels of some membrane phospholipids and to alter the levels of others (15). Thus, Zap1 mediates both homeostatic and adaptive responses to zinc limitation.Zap1 also activates expression of an antioxidant gene, TSA1, which encodes the major cytosolic thioredoxin-dependent peroxidase, to combat the oxidative stress of zinc deficiency (16). Studies of mammalian cells have shown that zinc deficiency causes the increased accumulation of reactive oxygen species (17). We have observed that yeast also experience increased oxidative stress when grown under low zinc conditions (16). The source of this oxidative stress is unknown. Reactive oxygen species (ROS), including the superoxide anion, hydrogen peroxide (H 2 O 2 ), and hydroxyl radica...
