Abstract
The makorin (MKRN) family of ubiquitin ligases regulates diverse biological processes, including reproduction, neurogenesis, and immune function. The first identified member, MKRN3, is an inhibitor of sexual development that is the site of inherited mutations linked to central precocious puberty (CPP). All makorin proteins share a distinctive cysteine/histidine-rich (CH) domain. In MKRN3, the CH domain lies between the second C3H zinc finger and the RING domain. Using CD and NMR spectroscopy, we show that the CH domain folds upon coordination of a single Zn(2+) ion with picomolar affinity. Spectroscopic and NMR pH-titration analyses identify a CCHC-type metal-binding site, typical of zinc fingers with protein-interaction functions. The NMR structure reveals the CH-domain adopts a canonical ββα zinc finger fold, despite atypical ligand spacing and the absence of conserved hydrophobic residues that usually stabilize this type of structure. Thermal denaturation monitored by multiple spectroscopic probes indicates sequential unfolding, with side-chain packing becoming disordered near 33 °C but zinc-stabilized secondary structure persisting to ∼63 °C, consistent with a molten-globule conformation at high temperature. Guided by sequence homology to a zinc finger in FAAP20 and Alpha Fold modeling, NMR chemical shift perturbation studies were used to demonstrate the CH-domain binds ubiquitin. In analogous E3-ubiquitin ligases like TRAF6 that contain RING and CCHC-type zinc fingers, the CCHC-type zinc finger interacts with ubiquitin to modulate ligase activity.