Mixing of color signals by turtle cone photoreceptors.

The direct mixing of red and green cone signals in the outer plexiform layer of the turtle retina was studied by using intracellular recordings from red cone photoreceptors. Cone photoresponses were a function of the wavelength of the photons that stimulated them, even when small-diameter stimuli were used. The intensity response curves measured with red and green test flashes had different shapes. The kinetics of approximately equal amplitude red and green responses also differed. To quantify the short wavelength input onto red cones, differential chromatic adaptation was used. The relative sensitivity of the red cone to red and green test flashes was a function of the color and intensity of the background illumination; red backgrounds decreased relative red sensitivity, and green backgrounds increased relative red sensitivity. The spectral sensitivity of the additional short wavelength input onto red cones was determined by using differential chromatic adaptation, and was found to peak approximately 550 nm. We conclude that red cones receive an additional excitatory input from green cones (and possibly blue cones). A model of the cone mosaic suggests that approximately 50% of the red cone response (linear range) to a dim green test flash arises from neighboring green cones.