Mechanism of biomolecular recognition of trimethyllysine by the fluorinated aromatic cage of KDM5A PHD3 finger

Bas J.G.E. Pieters; Maud H.M. Wuts; Jordi Poater; Kiran Kumar; Paul B. White; Jos J.A.G. Kamps; Woody Sherman; Ger J.M. Pruijn; Robert S. Paton; Thijs Beuming; F. Matthias Bickelhaupt; Jasmin Mecinović

doi:10.1038/s42004-020-0313-2

Mechanism of biomolecular recognition of trimethyllysine by the fluorinated aromatic cage of KDM5A PHD3 finger

Bas J.G.E. Pieters, Maud H.M. Wuts, Jordi Poater, Kiran Kumar, Paul B. White, Jos J.A.G. Kamps, Woody Sherman, Ger J.M. Pruijn, Robert S. Paton, Thijs Beuming, F. Matthias Bickelhaupt, Jasmin Mecinović

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12 Citations (Scopus)

Abstract

The understanding of biomolecular recognition of posttranslationally modified histone proteins is centrally important to the histone code hypothesis. Despite extensive binding and structural studies on the readout of histones, the molecular language by which posttranslational modifications on histone proteins are read remains poorly understood. Here we report physical-organic chemistry studies on the recognition of the positively charged trimethyllysine by the electron-rich aromatic cage containing PHD3 finger of KDM5A. The aromatic character of two tryptophan residues that solely constitute the aromatic cage of KDM5A was fine-tuned by the incorporation of fluorine substituents. Our thermodynamic analyses reveal that the wild-type and fluorinated KDM5A PHD3 fingers associate equally well with trimethyllysine. This work demonstrates that the biomolecular recognition of trimethyllysine by fluorinated aromatic cages is associated with weaker cation–π interactions that are compensated by the energetically more favourable trimethyllysine-mediated release of high-energy water molecules that occupy the aromatic cage.

Original language	English
Article number	69
Journal	Communications Chemistry
Volume	3
Issue number	1
DOIs	https://doi.org/10.1038/s42004-020-0313-2
Publication status	Published - 1 Dec 2020
Externally published	Yes

ASJC Scopus subject areas

Biochemistry
General Chemistry
Environmental Chemistry
Materials Chemistry

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Pieters, B. J. G. E., Wuts, M. H. M., Poater, J., Kumar, K., White, P. B., Kamps, J. J. A. G., Sherman, W., Pruijn, G. J. M., Paton, R. S., Beuming, T., Bickelhaupt, F. M., & Mecinović, J. (2020). Mechanism of biomolecular recognition of trimethyllysine by the fluorinated aromatic cage of KDM5A PHD3 finger. Communications Chemistry, 3(1), Article 69. https://doi.org/10.1038/s42004-020-0313-2

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title = "Mechanism of biomolecular recognition of trimethyllysine by the fluorinated aromatic cage of KDM5A PHD3 finger",

abstract = "The understanding of biomolecular recognition of posttranslationally modified histone proteins is centrally important to the histone code hypothesis. Despite extensive binding and structural studies on the readout of histones, the molecular language by which posttranslational modifications on histone proteins are read remains poorly understood. Here we report physical-organic chemistry studies on the recognition of the positively charged trimethyllysine by the electron-rich aromatic cage containing PHD3 finger of KDM5A. The aromatic character of two tryptophan residues that solely constitute the aromatic cage of KDM5A was fine-tuned by the incorporation of fluorine substituents. Our thermodynamic analyses reveal that the wild-type and fluorinated KDM5A PHD3 fingers associate equally well with trimethyllysine. This work demonstrates that the biomolecular recognition of trimethyllysine by fluorinated aromatic cages is associated with weaker cation–π interactions that are compensated by the energetically more favourable trimethyllysine-mediated release of high-energy water molecules that occupy the aromatic cage.",

author = "Pieters, \{Bas J.G.E.\} and Wuts, \{Maud H.M.\} and Jordi Poater and Kiran Kumar and White, \{Paul B.\} and Kamps, \{Jos J.A.G.\} and Woody Sherman and Pruijn, \{Ger J.M.\} and Paton, \{Robert S.\} and Thijs Beuming and Bickelhaupt, \{F. Matthias\} and Jasmin Mecinovi{\'c}",

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year = "2020",

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doi = "10.1038/s42004-020-0313-2",

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AU - Pieters, Bas J.G.E.

AU - Wuts, Maud H.M.

AU - Poater, Jordi

AU - Kumar, Kiran

AU - White, Paul B.

AU - Kamps, Jos J.A.G.

AU - Sherman, Woody

AU - Pruijn, Ger J.M.

AU - Paton, Robert S.

AU - Beuming, Thijs

AU - Bickelhaupt, F. Matthias

AU - Mecinović, Jasmin

PY - 2020/12/1

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N2 - The understanding of biomolecular recognition of posttranslationally modified histone proteins is centrally important to the histone code hypothesis. Despite extensive binding and structural studies on the readout of histones, the molecular language by which posttranslational modifications on histone proteins are read remains poorly understood. Here we report physical-organic chemistry studies on the recognition of the positively charged trimethyllysine by the electron-rich aromatic cage containing PHD3 finger of KDM5A. The aromatic character of two tryptophan residues that solely constitute the aromatic cage of KDM5A was fine-tuned by the incorporation of fluorine substituents. Our thermodynamic analyses reveal that the wild-type and fluorinated KDM5A PHD3 fingers associate equally well with trimethyllysine. This work demonstrates that the biomolecular recognition of trimethyllysine by fluorinated aromatic cages is associated with weaker cation–π interactions that are compensated by the energetically more favourable trimethyllysine-mediated release of high-energy water molecules that occupy the aromatic cage.

AB - The understanding of biomolecular recognition of posttranslationally modified histone proteins is centrally important to the histone code hypothesis. Despite extensive binding and structural studies on the readout of histones, the molecular language by which posttranslational modifications on histone proteins are read remains poorly understood. Here we report physical-organic chemistry studies on the recognition of the positively charged trimethyllysine by the electron-rich aromatic cage containing PHD3 finger of KDM5A. The aromatic character of two tryptophan residues that solely constitute the aromatic cage of KDM5A was fine-tuned by the incorporation of fluorine substituents. Our thermodynamic analyses reveal that the wild-type and fluorinated KDM5A PHD3 fingers associate equally well with trimethyllysine. This work demonstrates that the biomolecular recognition of trimethyllysine by fluorinated aromatic cages is associated with weaker cation–π interactions that are compensated by the energetically more favourable trimethyllysine-mediated release of high-energy water molecules that occupy the aromatic cage.

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SN - 2399-3669

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JF - Communications Chemistry

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ER -

Mechanism of biomolecular recognition of trimethyllysine by the fluorinated aromatic cage of KDM5A PHD3 finger

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