Abstract
Hsp90 plays critical roles in the proper functioning of a wide array of eukaryotic signal transducers such as steroid receptors and tyrosine kinases. Hap1 is a naturally occurring substrate of Hsp90 in Saccharomyces cerevisiae. Hap1 transcriptional activity is precisely and stringently controlled by heme. Previous biochemical studies suggest that in the absence of heme, Hap1 is bound to Hsp90 and other proteins, forming a higher order complex termed HMC (high molecular weight complex), and is repressed. Heme promotes the disruption of the HMC and activates Hap1, permitting Hap1 to bind to DNA with high affinity and to stimulate transcription. By lowering the expression levels of wild-type Hsp90, using a highly specific Hsp90 inhibitor, and by examining the effects of various Hsp90 mutants on Hap1, we show that Hsp90 is critical for Hap1 activation by heme. Furthermore, we show that many Hsp90 mutants exert differential effects on Hap1 and steroid receptors. Notably, mutant G313N weakens Hsp90 steroid receptor interaction but strongly enhances Hsp90-Hap1 interaction and increases Hap1 resistance to protease digestion. Additionally, we found that a heme-independent Hap1 mutant still depends on Hsp90 for high activity. These experiments together suggest that Hsp90 promotes Hap1 activation by inducing or maintaining Hap1 in a transcriptionally active conformation.
Highlights
Genetic studies [8, 9] in yeast have provided valuable insights into the function of Hsp90 in steroid signaling
We show that many Hsp90 mutants exert differential effects on Hap1 and steroid receptors
To rule out the possibility here that the interaction of Hsp90 with Hap1 is an artifact and to ascertain whether and how this interaction is important for heme regulation, we examined the effects of defective Hsp90 function on Hap1 activity
Summary
Genetic studies [8, 9] in yeast have provided valuable insights into the function of Hsp in steroid signaling. Recent studies [10, 11] have identified a few natural substrates of Hsp in yeast including the heme activator protein Hap and Ste of the pheromone-signaling pathway. Hap contains 1483 amino acid residues and is composed of multiple functional domains and elements, such as the C6 zinc cluster and the dimerization element at the N terminus, which permit Hap to bind to DNA, the repression modules-1–3 (RPM1–3) and the heme-responsive motifs-1–7 (HRM1–7), which mediate heme regulation, and the activation domain at the C terminus [13, 14, 17,18,19,20,21].
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