Photoreceptors Take Charge: Emerging Principles for Light Sensing

• Published in: Annual review of biophysics Vol. 47; no. 1; pp. 291 - 313
• Main Authors: Kottke, Tilman, Xie, Aihua, Larsen, Delmar S, Hoff, Wouter D
• Format: Journal Article
• Language: English
• Published: United States Annual Reviews 20.05.2018
• Subjects: chromophore; electrostatic epicenter; isomerization; proton transfer; proton-coupled electron transfer; signaling state; signaling state; chromophore; proton transfer; proton-coupled electron transfer; electrostatic epicenter; isomerization
• ISSN: 1936-122X; 1936-1238
• DOI: 10.1146/annurev-biophys-070317-033047

The first stage in biological signaling is based on changes in the functional state of a receptor protein triggered by interaction of the receptor with its ligand(s). The light-triggered nature of photoreceptors allows studies on the mechanism of such changes in receptor proteins using a wide range of biophysical methods and with superb time resolution. Here, we critically evaluate current understanding of proton and electron transfer in photosensory proteins and their involvement both in primary photochemistry and subsequent processes that lead to the formation of the signaling state. An insight emerging from multiple families of photoreceptors is that ultrafast primary photochemistry is followed by slower proton transfer steps that contribute to triggering large protein conformational changes during signaling state formation. We discuss themes and principles for light sensing shared by the six photoreceptor families: rhodopsins, phytochromes, photoactive yellow proteins, light-oxygen-voltage proteins, blue-light sensors using flavin, and cryptochromes.