WHIRLY Proteins, multi-layer regulators linking the nucleus and organelles in developmental and stress-induced senescence of plants

Abstract Plant senescence is an integrated program of plant development that aims to remobilize nutrients and energy from senescing tissues to developing organs under developmental and stress-induced conditions. Upstream in the regulatory network, a small family of single-stranded DNA/RNA-binding proteins known as WHIRLYs occupy a central node, acting at multiple regulatory levels and via trans-localization between the nucleus and organelles. In this review, we summarize the current progress on the role of WHIRLY members in plant development and stress-induced senescence. WHIRLY proteins can be traced back in evolution to green algae. WHIRLY proteins trade off the balance of plant developmental senescence and stress-induced senescence through maintaining organelle genome stability via R-loop homeostasis, repressing the transcription at a configuration condition, recruiting RNA to impact organelle RNA editing and splicing, as evidenced in several species, WHIRLY proteins also act as retrograde signal transducers between organelles and the nucleus through protein modification and stromule or vesicle trafficking. In addition, WHIRLY proteins interact with hormones, ROS and environmental signals to orchestrate cell fate in an age-dependent manner. Finally, prospects for further research and promotion to improve crop production under environmental constraints are highlighted.