Motion detection and adaptation in crayfish photoreceptors: A Spatiotemporal analysis of linear movement sensitivity

Abstract

Impulse and sine wave responses of crayfish photoreceptors were examined to establish the limits and the parameters of linear behavior. These receptors exhibit simple low pass behavior which is well described by the transfer function of a linear resistor-capacitor cascade of three to five stages, each with the same time constant (τ). Additionally, variations in mean light intensity modify τ twofold and the contrast sensitivity by fourfold. The angular sensitivity profile is Gaussian and the acceptance angle (φ) increases 3.2-fold with dark adaptation. The responses to moving stripes of positive and negative contrast were measured over a 100-fold velocity range. The amplitude, phase, and waveform of these responses were predicted from the convolution of the receptor's impulse response and angular sensitivity profile. A theoretical calculation based on the convolution of a linear impulse response and a Gaussian sensitivity profile indicates that the sensitivity to variations in stimulus velocity is determined by the ratio φ/τ. These two parameters are sufficient to predict the velocity of the half-maximal response over a wide range of ambient illumination levels. Because φ and τ vary in parallel during light adaptation, it is inferred that many arthropods can maintain approximately constant velocity sensitivity during large shifts in mean illumination and receptor time constant. The results are discussed relative to other arthropod and vertebrate receptors and the strategies that have evolved for movement detection in varying ambient illumination.