Abstract

CarH is a coenzyme B₁₂-dependent photoreceptor involved in regulating carotenoid biosynthesis. How light-triggered cleavage of the B₁₂ Co-C bond culminates in CarH tetramer dissociation to initiate transcription remains unclear. Here, a series of crystal structures of the CarH B₁₂-binding domain after illumination suggest formation of unforeseen intermediate states prior to tetramer dissociation. Unexpectedly, in the absence of oxygen, Co-C bond cleavage is followed by reorientation of the corrin ring and a switch from a lower to upper histidine-Co ligation, corresponding to a pentacoordinate state. Under aerobic conditions, rapid flash-cooling of crystals prior to deterioration upon illumination confirm a similar B₁₂-ligand switch occurs. Removal of the upper His-ligating residue prevents monomer formation upon illumination. Combined with detailed solution spectroscopy and computational studies, these data demonstrate the CarH photoresponse integrates B₁₂ photo- and redox-chemistry to drive large-scale conformational changes through stepwise Co-ligation changes.

CarH is a bacterial B₁₂-binding photoreceptor involved in transcriptional regulation. Here, the authors provide insights into B₁₂ dynamics and associated cobalt redox changes following light activation. These demonstrate the CarH response integrates light and oxygen sensing.