Coordinated neuron-specific splicing events restrict nucleosome engagement of the LSD1 histone demethylase complex

Coordinated neuron-specific splicing events restrict nucleosome engagement of the LSD1 histone demethylase complex

Summary: Chromatin regulatory proteins are expressed broadly and assumed to exert the same intrinsic function across cell types. Here, we report that 14 chromatin regulators undergo evolutionary-conserved neuron-specific splicing events involving microexons. Among them are two components of a histon...

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Main Authors: Robert S. Porter, Sojin An, Maria C. Gavilan, Masayoshi Nagai, Yumie Murata-Nakamura, Bo Zhou, Katherine M. Bonefas, Olivier Dionne, Jeru Manoj Manuel, Joannie St-Germain, Suzanne Gascon, Jacqueline Kim, Liam Browning, Benoit Laurent, Uhn-Soo Cho, Shigeki Iwase
Format: Article
Language:English
Published: Elsevier 2025-01-01
Series:Cell Reports
Subjects:
CP: Molecular biology
CP: Neuroscience
Online Access:http://www.sciencedirect.com/science/article/pii/S221112472401564X
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Summary:Summary: Chromatin regulatory proteins are expressed broadly and assumed to exert the same intrinsic function across cell types. Here, we report that 14 chromatin regulators undergo evolutionary-conserved neuron-specific splicing events involving microexons. Among them are two components of a histone demethylase complex: LSD1 H3K4 demethylase and the H3K4me0-reader PHF21A. We found that neuronal LSD1 splicing reduces the enzymes’ affinity to the nucleosome. Meanwhile, neuronal PHF21A splicing significantly attenuates histone H3 binding and further ablates the DNA-binding function exerted by an AT-hook motif. Furthermore, in vitro reconstitution of the canonical and neuronal PHF21A-LSD1 complexes, combined with in vivo methylation mapping, identified the neuronal complex as a hypomorphic H3K4 demethylating machinery. The neuronal PHF21A, albeit with its weaker nucleosome binding, is necessary for normal gene expression and the H3K4 landscape in the developing brain. Thus, ubiquitously expressed chromatin regulatory complexes can exert neuron-specific functions via alternative splicing of their subunits.
ISSN:2211-1247

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