Ca2+ binding shifts dimeric dual oxidase's truncated EF-hand domain to monomer

Hydrogen peroxide, produced by Dual Oxidase (Duox), is essential for thyroid hormone synthesis. Duox activation involves Ca2+ binding to its EF-hand Domain (EFD), which contains two EF-hands (EFs). In this study, we characterized a truncated EFD using spectrometry, calorimetry, electrophoretic mobility, and gel filtration to obtain its Ca2+ binding thermodynamic and kinetics, as well as to assess the associated conformational changes. Our results revealed that its 2nd EF-hand (EF2) exhibits a strong exothermic Ca2+ binding (Ka = 107 M−1) while EF1 shows a weaker binding (Ka = 105 M−1), resulting in the burial of its negatively charged residues. The Ca2+ binding to EFD results in a stable structure with a melting temperature shifting from 67 to 99 °C and induces a structural transition from a dimeric to monomeric form. EF2 appears to play a role in dimer formation in its apo form, while the hydrophobic exposure of Ca2+-bound-EF1 is crucial for dimer formation in its holo form. The result is consistent with structures obtained from Cryo-EM, indicating that a stable structure of EFD with hydrophobic patches upon Ca2+ binding is vital for its Duox's domain-domain interaction for electron transfer. [Display omitted] •A truncated ’s Ca2+ binding domain (EFDS) comprising 2 EF-hands was expressed soluble and purified to be homologous.•Differential Ca2+ binding was observed for both EFs in terms of binding thermodynamics and kinetics.•Ca2+ binding exposes hydrophobic patches and buries negatively charged residues, resulting in a more stable structure.•The conformational changes induce a transition between dime and monomer, providing insight into Duox activation mechanism.