Light-activated channelrhodopsins: a revolutionary toolkit for the remote control of plant signalling

Abstract

Channelrhodopsins (CHRs), originating within algae and protists, are membrane-spanning ion channel proteins that are directly activated and/or deactivated by specific wavelengths of light. Since 2005, CHRs have been deployed as genetically encoded optogenetic tools to rapidly advance understanding of neuronal networks. CHRs provide the opportunity to finely tune ion transport across membranes and regulate membrane potential. These are fundamental biochemical signals, which in plants can be translated into physiological and developmental responses such as changes in photosynthesis, growth, turgor, vascular hydraulics, phosphorylation or reactive oxygen species (ROS) status, gene expression, or even cell death. Exploration of CHR family diversity and structure–function engineering has led to the expansion of the CHR optogenetic toolbox, offering unparalleled opportunities to precisely control and understand electrical and secondary messenger signalling in higher plants. In this Tansley Insight, we provide an overview of the recent progress in the application of CHR optogenetics in higher plants and discuss their possible uses in the remote control of plant biology, illuminating a new future domain for plant research enabled through synthetic biology.