ABSTRACT
Vision mediates important behavioural tasks such as mate choice, escape from predators and foraging. In fish, photoreceptors are generally tuned to specific visual tasks and/or to their light environment, according to depth or water colour to ensure optimal performance. Evolutionary mechanisms acting on genes encoding opsin, the protein component of the photopigment, can influence the spectral sensitivity of photoreceptors. Opsin genes are known to respond to environmental conditions on a number of time scales, including short time frames due to seasonal variation, or through longer-term evolutionary tuning. There is also evidence for 'on-the-fly' adaptations in adult fish in response to rapidly changing environmental conditions; however, results are contradictory. Here, we investigated the ability of three reef fish species that belong to two ecologically distinct families, yellow-striped cardinalfish (Ostorhinchus cyanosoma), Ambon damselfish (Pomacentrus amboinensis) and lemon damselfish (Pomacentrus moluccensis), to alter opsin gene expression as an adaptation to short-term (weeks to months) changes of environmental light conditions, and attempted to characterize the underlying expression regulation principles. We report the ability for all species to alter opsin gene expression within months and even a few weeks, suggesting that opsin expression in adult reef fish is not static. Furthermore, we found that changes in opsin expression in single cones generally occurred more rapidly than in double cones, and identified different responses of RH2 opsin gene expression between the ecologically distinct reef fish families. Quantum catch correlation analysis suggested different regulation mechanisms for opsin expression dependent on gene class.
