Epigenetic regulation of a heat-trainable sHSP locus controls thermomemory in a unicellular alga

A powerful way to enhance heat tolerance is to prime organisms with a moderate heat treatment to establish a molecular stress memory permitting the survival of the organism when exposed to subsequent heat shocks. While this has been extensively studied in multicellular organisms, we demonstrate that the unicellular red alga Cyanidioschyzon merolae exhibits heat stress memory. We show that, similarly to more complex organisms, thermomemory in this alga is underpinned by transcriptomic reprogramming, with the chloroplast emerging as the main site of gene trainability. Additionally, we find a conserved small heat shock protein (sHSP)-encoding locus in the nuclear genome to be heat-trainable, likely by histone depletion and sustained removal of the repressive mark histone H3 Lysine 27 trimethylation (H3K27me3). Of C. merolaes two sHSPs, only the nuclear-localizing CmsHSP2 is necessary for proper HS memory establishment. Finally, we reveal a role for the H3K27me3-transferase CmE(z) (Enhancer of zeste) in heat stress memory which shapes the transcriptome to recurring heat exposures, beyond regulating the trainable sHSP locus. Overall, our work provides a molecular framework for the regulation of heat stress memory in a unicellular eukaryote.