Abstract
The absorption of light by the chromophore of rhodopsin initiates a series of interconversions between spectrally distinct intermediates1–3. The possibility has been raised that one of these transitions is accompanied by a change in the state of rhodopsin, and that it is this change which instigates visual excitation via a cascade of enzyme catalysed reactions. It has been suggested that the initial step of this cascade, which leads to the activation of cyclic GMP phosphodiesterase (PDE), involves the interaction of a GTP-binding regulatory (G) protein with rhodopsin4–6. The ability of rhodopsin to activate PDE may be inhibited by the phosphorylation of sites exposed on the opsin surface as a result of light-induced conformational changes7–9. To obtain more information about the relationship between the postchemical and biochemical reactions of rhodopsin we have investigated which transition leads to the activation of rhodopsin as a substrate for rhodopsin kinase, and report here that it is the transition from lumirhodopsin to metarhodopsin I.
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Paulsen, R., Bentrop, J. Activation of rhodopsin phosphorylation is triggered by the lumirhodopsin–metarhodopsin I transition. Nature 302, 417–419 (1983). https://doi.org/10.1038/302417a0
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DOI: https://doi.org/10.1038/302417a0
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