The Aft1 transcription factor regulates the iron regulon in response to iron availability in Saccharomyces cerevisiae. Aft1 activates a battery of genes required for iron uptake under iron-starved conditions, whereas Aft1 function is inactivated under iron-replete conditions. Previously, we have shown that iron-regulated DNA binding by Aft1 is responsible for the controlled expression of target genes. Here we show that this iron-regulated DNA binding by Aft1 is not due to the change in the total expression level of Aft1 or alteration of DNA binding activity. Rather, nuclear localization of Aft1 responds to iron status, leading to iron-regulated expression of the target genes. We identified the nuclear export signal (NES)-like sequence in the AFT1 open reading frame. Mutation of the NES-like sequence causes nuclear retention of Aft1 and the constitutive activation of Aft1 function independent of the iron status of the cells. These results suggest that the nuclear export of Aft1 is critical for ensuring iron-responsive transcriptional activation of the Aft1 regulon and that the nuclear import/ export systems are involved in iron sensing by Aft1 in S. cerevisiae.Iron is an essential nutrient for virtually all organisms, working as a cofactor for critical proteins that mediate diverse processes such as cellular respiration and synthesis of metabolic intermediates (1). On the other hand, excess iron is extremely toxic, being capable of generating free radicals that damage macromolecules such as proteins, lipids, and DNA (2). The uptake and metabolism of iron must therefore be strictly regulated. In all organisms studied, the rates of iron uptake are tightly coupled to the levels of available iron and the needs of cells (3). In metazoans, the mechanisms that underlie regulation of iron metabolism including uptake, sequestration, and utilization have been well characterized. Two RNA-binding proteins called "iron regulatory protein," IRP1 1 and IRP2, are responsible for this regulation by controlling mRNA translation or mRNA stability by iron regulated mRNA-protein interactions (4). Although these proteins are closely related, IRP1 is a relatively stable protein (5, 6), and its RNA binding activity is inactivated by iron-sulfur cluster formation in iron-replete cells (7). By contrast, IRP2 is degraded by the ubiquitin-proteasome system in iron-replete cells (8).In Saccharomyces cerevisiae, iron deprivation induces activities of a high affinity iron uptake system (9) and siderophoremediated iron uptake system (10, 11). A transcription factor, Aft1, plays a critical role in this process (12). Aft1 protein binds to a regulatory region in the DNA of the genes required for iron uptake and induces the transcription of these genes in ironstarved cells (13). Conversely, Aft1 is not bound to its regulatory target element in iron-replete cells, and the expression of its target genes is not induced. An increasing number of Aft1 target genes have been implicated in iron metabolism, including a putative transporter complex located i...
