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  • Histone Lysine-to-Methionine Mutations Reduce Histone Methylation and Cause Developmental Pleiotropy.

Histone Lysine-to-Methionine Mutations Reduce Histone Methylation and Cause Developmental Pleiotropy.

Plant physiology (2017-02-17)
Dean Sanders, Shuiming Qian, Rachael Fieweger, Li Lu, James A Dowell, John M Denu, Xuehua Zhong
ABSTRACT

Epigenetic modifications play critical roles in diverse biological processes. Histone Lys-to-Met (K-to-M) mutations act as gain-of-function mutations to inhibit a wide range of histone methyltransferases and are thought to promote tumorigenesis. However, it is largely unknown whether K-to-M mutations impact organismal development. Using Arabidopsis (Arabidopsis thaliana) as a model system, we discovered that a transgene exogenously expressing histone 3 Lys-36 to Met mutation (K36M) acts in a dominant-negative manner to cause global reduction of H3K36 methylation. Remarkably, this dominant repressive activity is dosage-dependent and causes strong developmental perturbations including extreme branching and early flowering by affecting the expression of genes involved in developmental and metabolic processes. Besides the established pathological roles of K-to-M mutations in tumor cells, we demonstrate a physiological outcome for K-to-M induced H3K36 hypomethylation. This study provides evidence for a conserved dominant-negative inhibitory role of histone K-to-M mutation across the plant and animal kingdoms. We also highlight the unique ability of K36M mutations to alter plant developmental processes leading to severe pleiotropic phenotypes. Finally, our data suggests K-to-M mutations may provide a useful strategy for altering epigenetic landscapes in organisms where histone methyltransferases are uncharacterized.

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Monoclonal ANTI-FLAG® M2 antibody produced in mouse, clone M2, purified immunoglobulin (Purified IgG1 subclass), buffered aqueous solution (10 mM sodium phosphate, 150 mM NaCl, pH 7.4, containing 0.02% sodium azide)