A Bivalent Chromatin Controls Timing of Expression of Camalexin Biosynthesis Genes in Response to a Pathogen Signal in Arabidopsis

Temporal dynamics of gene expression underpins the responses to internal and environmental stimuli. In eukaryotes, regulation of gene induction includes changing chromatin states at the target genes, and recruitment of the transcriptional machinery that includes transcription factors. As one of the most potent specialized metabolites in Arabidopsis thaliana, camalexin can be rapidly induced by bacterial and fungal infections. Though several transcription factors controlling camalexin biosynthesis genes have been characterized, it remains unknown how the rapid activation of genes in this pathway upon a pathogen signal happens. By combining publicly available epigenomic data with in vivo chromatin mapping, we found that camalexin biosynthesis genes are marked with two epigenetic modifications with opposite effects on gene expression, H3K27me3 (repression) and H3K18ac (activation), to form a bivalent chromatin. Mutants with reduced H3K27m3 or H3K18ac showed that both modifications were required to determine the timing of gene expression and metabolite accumulation at an early stage of the stress response. Our study indicates that this type of bivalent chromatin, which we name a kairostat, plays an important role controlling the timely induction of gene expression upon stimuli in plants.