Srihari C. Sampath scite author profile

Cocaine-induced alterations in gene expression cause changes in neuronal morphology and behavior that may underlie cocaine addiction. We identified an essential role for histone 3 lysine 9 (H3K9) dimethylation and the lysine dimethyltransferase G9a in cocaine-induced structural and behavioral plasticity. Repeated cocaine administration reduced global levels of H3K9 dimethylation in the nucleus accumbens. This reduction in histone methylation was mediated through the repression of G9a in this brain region, which was regulated by the cocaine-induced transcription factor ΔFosB. Using conditional mutagenesis and viral-mediated gene transfer, we found that G9a downregulation increased dendritic spine plasticity of nucleus accumbens neurons and enhanced preference for cocaine, thereby establishing a crucial role for histone methylation in the long-term actions of cocaine.Repeated cocaine exposure is characterized by persistent changes in gene expression and altered neuronal morphology within the nucleus accumbens (NAc), a key component of the brain's reward circuitry (1-2). Chromatin remodeling is important in aberrant transcriptional changes in this brain region that may underlie aspects of cocaine addiction (3-9). Cocaine regulation of chromatin structure in the NAc results, in part, from direct cocaine-induced modifications of the chromatin enzymatic machinery, leading to changes in histone acetylation *To whom correspondence should be addressed. eric.nestler@mssm.edu. I certify that none of the materials included within the manuscript entitled Essential Role of the Histone Methyltransferase G9a in Cocaineinduced Plasticity have been previously published or are under consideration elsewhere, including on the Internet.All work involving the use of animals was conducted in accordance with institutional and IACUC guidelines at both The

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Control of Cognition and Adaptive Behavior by the GLP/G9a Epigenetic Suppressor Complex

Schaefer

Sampath

Intrator

et al. 2009

Neuron

291

288

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SUMMARY The genetic basis of cognition and behavioral adaptation to the environment remains poorly understood. Here we demonstrate that the histone methyltransferase complex GLP/G9a controls cognition and adaptive responses in a region-specific fashion in the adult brain. Using conditional mutagenesis in mice, we show that postnatal, neuron-specific deficiency of GLP/G9a leads to de-repression of numerous non-neuronal and neuron progenitor genes in adult neurons. This transcriptional alteration is associated with complex behavioral abnormalities, including defects in learning, motivation and environmental adaptation. The behavioral changes triggered by GLP/G9a deficiency are similar to key symptoms of the human 9q34 mental retardation syndrome that is associated with structural alterations of the GLP gene. The likely causal role of GLP/G9a in mental retardation in mice and humans suggests a key role for the GLP/G9a controlled histone H3K9 di-methylation in regulation of brain function through maintenance of the transcriptional homeostasis in adult neurons.

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Methylation of a Histone Mimic within the Histone Methyltransferase G9a Regulates Protein Complex Assembly

Sampath¹,

Marazzi²,

et al. 2007

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Epigenetic gene silencing in eukaryotes is regulated in part by lysine methylation of the core histone proteins. While histone lysine methylation is known to control gene expression through the recruitment of modification-specific effector proteins, it remains unknown whether nonhistone chromatin proteins are targets for similar modification-recognition systems. Here we show that the histone H3 methyltransferase G9a contains a conserved methylation motif with marked sequence similarity to H3 itself. As with methylation of H3 lysine 9, autocatalytic G9a methylation is necessary and sufficient to mediate in vivo interaction with the epigenetic regulator heterochromatin protein 1 (HP1), and this methyl-dependent interaction can be reversed by adjacent G9a phosphorylation. NMR analysis indicates that the HP1 chromodomain recognizes methyl-G9a through a binding mode similar to that used in recognition of methyl-H3K9, demonstrating that the chromodomain functions as a generalized methyl-lysine binding module. These data reveal histone-like modification cassettes - or "histone mimics" - as a distinct class of nonhistone methylation targets and directly extend the principles of the histone code to the regulation of nonhistone proteins.

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The microprotein Minion controls cell fusion and muscle formation

et al. 2017

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Although recent evidence has pointed to the existence of small open reading frame (smORF)-encoded microproteins in mammals, their function remains to be determined. Skeletal muscle development requires fusion of mononuclear progenitors to form multinucleated myotubes, a critical but poorly understood process. Here we report the identification of Minion (microprotein inducer of fusion), a smORF encoding an essential skeletal muscle specific microprotein. Myogenic progenitors lacking Minion differentiate normally but fail to form syncytial myotubes, and Minion-deficient mice die perinatally and demonstrate a marked reduction in fused muscle fibres. The fusogenic activity of Minion is conserved in the human orthologue, and co-expression of Minion and the transmembrane protein Myomaker is sufficient to induce cellular fusion accompanied by rapid cytoskeletal rearrangement, even in non-muscle cells. These findings establish Minion as a novel microprotein required for muscle development, and define a two-component programme for the induction of mammalian cell fusion. Moreover, these data also significantly expand the known functions of smORF-encoded microproteins.

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