An autoinhibited state of 53BP1 revealed by small molecule antagonists and protein engineering

Gaofeng Cui; Maria Victoria Botuyan; Pascal Drané; Qi Hu; Benoît Bragantini; James R. Thompson; David J. Schuller; Alexandre Detappe; Michael T. Perfetti; Lindsey I. James; Stephen V. Frye; Dipanjan Chowdhury; Georges Mer

doi:10.1038/s41467-023-41821-6

An autoinhibited state of 53BP1 revealed by small molecule antagonists and protein engineering

Gaofeng Cui, Maria Victoria Botuyan, Pascal Drané, Qi Hu, Benoît Bragantini, James R. Thompson, David J. Schuller, Alexandre Detappe, Michael T. Perfetti, Lindsey I. James, Stephen V. Frye, Dipanjan Chowdhury, Georges Mer

Research output: Contribution to journal › Article › peer-review

Abstract

The recruitment of 53BP1 to chromatin, mediated by its recognition of histone H4 dimethylated at lysine 20 (H4K20me2), is important for DNA double-strand break repair. Using a series of small molecule antagonists, we demonstrate a conformational equilibrium between an open and a pre-existing lowly populated closed state of 53BP1 in which the H4K20me2 binding surface is buried at the interface between two interacting 53BP1 molecules. In cells, these antagonists inhibit the chromatin recruitment of wild type 53BP1, but do not affect 53BP1 variants unable to access the closed conformation despite preservation of the H4K20me2 binding site. Thus, this inhibition operates by shifting the conformational equilibrium toward the closed state. Our work therefore identifies an auto-associated form of 53BP1—autoinhibited for chromatin binding—that can be stabilized by small molecule ligands encapsulated between two 53BP1 protomers. Such ligands are valuable research tools to study the function of 53BP1 and have the potential to facilitate the development of new drugs for cancer therapy.

Original language	English (US)
Article number	6091
Journal	Nature communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-41821-6
State	Published - Dec 2023

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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title = "An autoinhibited state of 53BP1 revealed by small molecule antagonists and protein engineering",

abstract = "The recruitment of 53BP1 to chromatin, mediated by its recognition of histone H4 dimethylated at lysine 20 (H4K20me2), is important for DNA double-strand break repair. Using a series of small molecule antagonists, we demonstrate a conformational equilibrium between an open and a pre-existing lowly populated closed state of 53BP1 in which the H4K20me2 binding surface is buried at the interface between two interacting 53BP1 molecules. In cells, these antagonists inhibit the chromatin recruitment of wild type 53BP1, but do not affect 53BP1 variants unable to access the closed conformation despite preservation of the H4K20me2 binding site. Thus, this inhibition operates by shifting the conformational equilibrium toward the closed state. Our work therefore identifies an auto-associated form of 53BP1—autoinhibited for chromatin binding—that can be stabilized by small molecule ligands encapsulated between two 53BP1 protomers. Such ligands are valuable research tools to study the function of 53BP1 and have the potential to facilitate the development of new drugs for cancer therapy.",

author = "Gaofeng Cui and Botuyan, {Maria Victoria} and Pascal Dran{\'e} and Qi Hu and Beno{\^i}t Bragantini and Thompson, {James R.} and Schuller, {David J.} and Alexandre Detappe and Perfetti, {Michael T.} and James, {Lindsey I.} and Frye, {Stephen V.} and Dipanjan Chowdhury and Georges Mer",

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year = "2023",

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doi = "10.1038/s41467-023-41821-6",

language = "English (US)",

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AU - Cui, Gaofeng

AU - Botuyan, Maria Victoria

AU - Drané, Pascal

AU - Hu, Qi

AU - Bragantini, Benoît

AU - Thompson, James R.

AU - Schuller, David J.

AU - Detappe, Alexandre

AU - Perfetti, Michael T.

AU - James, Lindsey I.

AU - Frye, Stephen V.

AU - Chowdhury, Dipanjan

AU - Mer, Georges

PY - 2023/12

Y1 - 2023/12

N2 - The recruitment of 53BP1 to chromatin, mediated by its recognition of histone H4 dimethylated at lysine 20 (H4K20me2), is important for DNA double-strand break repair. Using a series of small molecule antagonists, we demonstrate a conformational equilibrium between an open and a pre-existing lowly populated closed state of 53BP1 in which the H4K20me2 binding surface is buried at the interface between two interacting 53BP1 molecules. In cells, these antagonists inhibit the chromatin recruitment of wild type 53BP1, but do not affect 53BP1 variants unable to access the closed conformation despite preservation of the H4K20me2 binding site. Thus, this inhibition operates by shifting the conformational equilibrium toward the closed state. Our work therefore identifies an auto-associated form of 53BP1—autoinhibited for chromatin binding—that can be stabilized by small molecule ligands encapsulated between two 53BP1 protomers. Such ligands are valuable research tools to study the function of 53BP1 and have the potential to facilitate the development of new drugs for cancer therapy.

AB - The recruitment of 53BP1 to chromatin, mediated by its recognition of histone H4 dimethylated at lysine 20 (H4K20me2), is important for DNA double-strand break repair. Using a series of small molecule antagonists, we demonstrate a conformational equilibrium between an open and a pre-existing lowly populated closed state of 53BP1 in which the H4K20me2 binding surface is buried at the interface between two interacting 53BP1 molecules. In cells, these antagonists inhibit the chromatin recruitment of wild type 53BP1, but do not affect 53BP1 variants unable to access the closed conformation despite preservation of the H4K20me2 binding site. Thus, this inhibition operates by shifting the conformational equilibrium toward the closed state. Our work therefore identifies an auto-associated form of 53BP1—autoinhibited for chromatin binding—that can be stabilized by small molecule ligands encapsulated between two 53BP1 protomers. Such ligands are valuable research tools to study the function of 53BP1 and have the potential to facilitate the development of new drugs for cancer therapy.

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An autoinhibited state of 53BP1 revealed by small molecule antagonists and protein engineering

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