Light-dependent gene regulation by a coenzyme B12-based photoreceptor

Cobalamin (B12) typically functions as an enzyme cofactor but can also regulate gene expression via RNA-based riboswitches. B12-directed gene regulatory mechanisms via protein factors have, however, remained elusive. Recently, we reported down-regulation of a light-inducible promoter in the bacterium Myxococcus xanthus by two paralogous transcriptional repressors, of which one, CarH, but not the other, CarA, absolutely requires B12 for activity even though both have a canonical B12-binding motif. Unanswered were what underlies this striking difference, what is the specific cobalamin used, and how it acts. Here, we show that coenzyme B12 (5′-deoxyadenosylcobalamin, AdoB12), specifically dictates CarH function in the dark and on exposure to light. In the dark, AdoB12-binding to the autonomous domain containing the B12-binding motif foments repressor oligomerization, enhances operator binding, and blocks transcription. Light, at various wavelengths at which AdoB12 absorbs, dismantles active repressor oligomers by photolysing the bound AdoB12 and weakens repressor–operator binding to allow transcription. By contrast, AdoB12 alters neither CarA oligomerization nor operator binding, thus accounting for its B12-independent activity. Our findings unveil a functional facet of AdoB12 whereby it serves as the chromophore of a unique photoreceptor protein class acting in light-dependent gene regulation. The prevalence of similar proteins of unknown function in microbial genomes suggests that this distinct B12-based molecular mechanism for photoregulation may be widespread in bacteria.