A Common histone modification code on C4 genes in maize and its conservation in Sorghum and Setaria italica.

C4 photosynthesis evolved more than 60 times independently in different plant lineages. Each time, multiple genes were recruited into C4 metabolism. The corresponding promoters acquired new regulatory features such as high expression, light induction, or cell type-specific expression in mesophyll or bundle sheath cells. We have previously shown that histone modifications contribute to the regulation of the model C4 phosphoenolpyruvate carboxylase (C4-Pepc) promoter in maize (Zea mays). We here tested the light- and cell type-specific responses of three selected histone acetylations and two histone methylations on five additional C4 genes (C4-Ca, C4-Ppdk, C4-Me, C4-Pepck, and C4-RbcS2) in maize. Histone acetylation and nucleosome occupancy assays indicated extended promoter regions with regulatory upstream regions more than 1,000 bp from the transcription initiation site for most of these genes. Despite any detectable homology of the promoters on the primary sequence level, histone modification patterns were highly coregulated. Specifically, H3K9ac was regulated by illumination, whereas H3K4me3 was regulated in a cell type-specific manner. We further compared histone modifications on the C4-Pepc and C4-Me genes from maize and the homologous genes from sorghum (Sorghum bicolor) and Setaria italica. Whereas sorghum and maize share a common C4 origin, C4 metabolism evolved independently in S. italica. The distribution of histone modifications over the promoters differed between the species, but differential regulation of light-induced histone acetylation and cell type-specific histone methylation were evident in all three species. We propose that a preexisting histone code was recruited into C4 promoter control during the evolution of C4 metabolism.

Developmental and environmental signals induce distinct histone acetylation profiles on distal and proximal promoter elements of the C4-Pepc gene in maize.

The maize C(4)-Pepc gene is expressed in an organ- and cell-type-specific manner, inducible by light and modulated by nutrient availability and the metabolic state of the cell. We studied the contribution of histone acetylation at five lysine residues to the integration of these signals into a graduated promoter response. In roots and coleoptiles, where the gene is constitutively inactive, three of the five lysines were acetylated and the modifications showed unique patterns with respect to their distribution on the gene. A similar pattern was observed in etiolated leaves, where the gene is poised for activation by light. Here, illumination selectively induced the acetylation of histone H4 lysine 5 and histone H3 lysine 9 in both the promoter and the transcribed region, again with unique distribution patterns. Induction was independent of transcription and fully reversible in the dark. Nitrate and hexose availability modulated acetylation of all five lysines restricted to a distal promoter region, whereas proximal promoter acetylation was highly resistant to these stimuli. Our data suggest that light induction of acetylation is controlled by regulating HDAC activity, whereas metabolic signals regulate HAT activity. Acetylation turnover rates were high in the distal promoter and the transcribed regions, but low on the proximal promoter. On the basis of these results, we propose a model with three levels of stimulus-induced histone modifications that collectively adjust promoter activity. The results support a charge neutralization model for the distal promoter and a stimulus-mediated, but transcription-independent, histone acetylation pattern on the core promoter, which might be part of a more complex histone code.

Developmental information but not promoter activity controls the methylation state of histone H3 lysine 4 on two photosynthetic genes in maize.

We have investigated the establishment of histone H3 methylation with respect to environmental and developmental signals for two key genes associated with C4 photosynthesis in maize. Tri-methylation of histone H3 lysine 4 (H3K4) in roots and leaves was shown to be controlled by autonomous cell-type-specific developmental signals that are independent of illumination and therefore independent of the initiation of transcription. Di- and mono-methylation of H3K4 act antagonistically to this process. The modifications were already established in etiolated seedlings, and remained stable when genes were inactivated by dark treatment or pharmaceutical inhibition of transcription. Constitutive di-methylation of H3K9 was concomitantly detected at specific gene positions. The data support a histone code model whereby cell-type-specific signals induce the formation of a chromatin structure that potentiates gene activation by environmental cues.