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Molecular basis for hierarchical histone de-?-hydroxybutyrylation by SIRT3.


ABSTRACT: Chemical modifications on histones constitute a key mechanism for gene regulation in chromatin context. Recently, histone lysine ?-hydroxybutyrylation (Kbhb) was identified as a new form of histone acylation that connects starvation-responsive metabolism to epigenetic regulation. Sirtuins are a family of NAD+-dependent deacetylases. Through systematic profiling studies, we show that human SIRT3 displays class-selective histone de-?-hydroxybutyrylase activities with preference for H3 K4, K9, K18, K23, K27, and H4K16, but not for H4 K5, K8, K12, which distinguishes it from the Zn-dependent HDACs. Structural studies revealed a hydrogen bond-lined hydrophobic pocket favored for the S-form Kbhb recognition and catalysis. ?-backbone but not side chain-mediated interactions around Kbhb dominate sequence motif recognition, explaining the broad site-specificity of SIRT3. The observed class-selectivity of SIRT3 is due to an entropically unfavorable barrier associated with the glycine-flanking motif that the histone Kbhb resides in. Collectively, we reveal the molecular basis for class-selective histone de-?-hydroxybutyrylation by SIRT3, shedding lights on the function of sirtuins in Kbhb biology through hierarchical deacylation.

SUBMITTER: Zhang X 

PROVIDER: S-EPMC6796883 | biostudies-literature | 2019

REPOSITORIES: biostudies-literature

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Molecular basis for hierarchical histone de-β-hydroxybutyrylation by SIRT3.

Zhang Xingrun X   Cao Ruili R   Niu Jinrong J   Yang Shumin S   Ma Huida H   Zhao Shuai S   Li Haitao H  

Cell discovery 20190709


Chemical modifications on histones constitute a key mechanism for gene regulation in chromatin context. Recently, histone lysine β-hydroxybutyrylation (Kbhb) was identified as a new form of histone acylation that connects starvation-responsive metabolism to epigenetic regulation. Sirtuins are a family of NAD<sup>+</sup>-dependent deacetylases. Through systematic profiling studies, we show that human SIRT3 displays class-selective histone de-β-hydroxybutyrylase activities with preference for H3 K  ...[more]

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