Nuclear encoded photosynthesis genes are specifically controlled by the NuA4 complex

Abstract

AbstractNuA4, an essential histone acetyltransferase complex, is required for efficient transcription in eukaryotes. Using genome editing, genomic approaches and biochemical assays, we characterized plant homologues of two key components of this complex, EPL1 and EAF1 inArabidopsis thaliana. Surprisingly, we found that loss of AtEPL1, which is necessary for enzymatic activity of NuA4, is not lethal. Contrary to yeast, mutants lacking AtEAF1, responsible for complex targeting, display severe pleiotropic phenotype which copies that ofAtepl1.Atepl1andAteaf1mutants grow slowly, contain reduced chlorophyll levels and small chloroplasts. We provide evidence that these alterations are not caused by disturbance of GLK transcription factors, the major regulators of chloroplast development. Using ChIP-seq we show that H4 acetylation levels are dramatically reduced in the chromatin of theAtepl1mutant, while H3 acetylation remains mostly unchanged. We use our data to define NuA4-dependent genes and show that chloroplast-related genes are significantly overrepresented in this group, consistent with the pale-green phenotypes of the mutants. We propose that NuA4 was adopted in plants to control nuclear-encoded photosynthesis genes.SignificancePhotosynthesis depends on chloroplast proteins, most of which are nucleus-encoded and thus subject to control mechanisms common across eukaryotes. Here we show that NuA4, an evolutionary conserved transcriptional coactivator, is necessary for proper development of photosynthetic apparatus. Surprisingly, in contrast to yeast and metazoans, plants engineered to lack core NuA4 subunits are capable of vegetative development despite dramatic genome-wide loss of NuA4-dependent H4K5 acetylation. This chromatin perturbation seems to directly affect 350 genes which, in addition to reduced H4K5ac levels, display decreased transcript levels but no loss of transcription-related H3K9ac. A significant proportion of these genes are related to chloroplast function, particularly to translation, an intriguing parallel to the yeast NuA4’s role in transcription of ribosome biogenesis-related genes.