Epigenetic reprogramming rewires transcription during the alternation of generations in Arabidonsis

Alternation between morphologically distinct haploid and diploid life forms is a defining feature of most plant and algal life cycles, yet the underlying molecular mechanisms that govern these transitions remain unclear. Here, we explore the dynamic relationship between chromatin accessibility and epigenetic modifications during life form transitions in Arabidopsis. The diploid-to-haploid life form transition is governed by the loss of H3K9me2 and DNA demethylation of transposon-associated cis-regulatory elements. This event is associated with dramatic changes in chromatin accessibility and transcriptional reprogramming. In contrast, the global loss of H3K27me3 in the haploid form shapes a chromatin accessibility landscape that is poised to reinitiate the transition back to diploid life after fertilisation. Hence, distinct epigenetic reprogramming events rewire transcription through major reorganisation of the regulatory epigenome to guide the alternation of generations in flowering plants.

Automated summary

The alternation between morphologically distinct haploid and diploid life forms in plants and algae is controlled by epigenetic modifications such as the loss of H3K9me2 and global loss of H3K27me3. These events lead to significant changes in chromatin accessibility and transcriptional reprogramming, guiding the transition between generations in flowering plants.