The structure and functional mechanism of eyespot in Chlamydomonas.

Abstract

Light plays a crucial role in photosynthesis, photoperiodism, and photomorphogenesis. Algae have a specialized visual system to perceive the light signal known as eyespot. A typical eyespot is an orange-colored, membranous structure packed with pigmented granules. In algae, the eyespot membrane bears a specialized type of photoreceptors, which shows similarity with animal rhodopsin photoreceptors. This light-sensing receptor is responsible for the photo-mobility response known as phototaxis. In this, light acts as a signal for onset and cascade of downstream signal transduction pathway leading to a conformational change in photoreceptor. This induces the continuous influx of calcium ions through the opening of calcium ion channels leading to membrane depolarization, and beating of flagella which is responsible for phototaxis. Mutational studies have assisted the discovery of eyespot genes, which are involved in eyespot development, assembly, size control, and functioning in Chlamydomonas. These genes belong to photoreceptors (cop1-12, acry, pcry, cry-dash1, cry-dash2, phot, uvr8), eyeless mutants (eye2, eye3), miniature-eyespot mutants (min1, min2), multiple eyespot mutants (mlt1, mlt2). This review discusses the structural biology of eyespots with special reference to Chlamydomonas, molecular insights, related genes, and proteins responsible for its proper functioning.