Conformational dynamics in specialized C2H2 zinc finger domains enable zinc-responsive gene repression in S. pombe.

Loz1 is a zinc-responsive transcription factor in fission yeast that maintains cellular zinc homeostasis by repressing the expression of genes required for zinc uptake in high zinc conditions. Previous deletion analysis of Loz1 found a region containing two tandem C₂H₂ zinc-fingers and an upstream "accessory domain" rich in histidine, lysine, and arginine residues to be sufficient for zinc-dependent DNA binding and gene repression. Here we report unexpected biophysical properties of this pair of seemingly classical C₂H₂ zinc fingers. Isothermal titration calorimetry and NMR spectroscopy reveal two distinct zinc binding events localized to the zinc fingers. NMR spectra reveal complex dynamic behavior in this zinc-responsive region spanning time scales from fast 10^-12-10^-10 to slow >10⁰ s. Slow exchange due to cis-trans isomerization of the TGERP linker results in the doubling of many signals in the protein. Conformational exchange on the 10^-3 s timescale throughout the first zinc finger distinguishes it from the second and is linked to a weaker affinity for zinc. These findings reveal a mechanism of zinc sensing by Loz1 and illuminate how the protein's rough free-energy landscape enables zinc sensing, DNA binding and regulated gene expression.