Bas J. G. E. Pieters scite author profile

Supramolecular protein assemblies are an emerging area within the chemical sciences, which combine the topological structures of the field of supramolecular chemistry and the state-of-the-art chemical biology approaches to unravel the formation and function of protein assemblies. Recent chemical and biological studies on natural multimeric protein structures, including fibers, rings, tubes, catenanes, knots, and cages, have shown that the quaternary structures of proteins are a prerequisite for their highly specific biological functions. In this review, we illustrate that a striking structural diversity of protein assemblies is present in nature. Furthermore, we describe structure-function relationship studies for selected classes of protein architectures, and we highlight the techniques that enable the characterisation of supramolecular protein structures.

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Chemical basis for the recognition of trimethyllysine by epigenetic reader proteins

Kamps¹,

Huang

Poater³

et al. 2015

Nat Commun

103

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A large number of structurally diverse epigenetic reader proteins specifically recognize methylated lysine residues on histone proteins. Here we describe comparative thermodynamic, structural and computational studies on recognition of the positively charged natural trimethyllysine and its neutral analogues by reader proteins. This work provides experimental and theoretical evidence that reader proteins predominantly recognize trimethyllysine via a combination of favourable cation–π interactions and the release of the high-energy water molecules that occupy the aromatic cage of reader proteins on the association with the trimethyllysine side chain. These results have implications in rational drug design by specifically targeting the aromatic cage of readers of trimethyllysine.

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Investigatingd-lysine stereochemistry for epigenetic methylation, demethylation and recognition

Belle

Temimi²,

Kumar

et al. 2017

Chem. Commun.

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Histone lysine methylation is regulated by N-methyltransferases, demethylases, and N-methyl lysine binding proteins. Thermodynamic, catalytic and computational studies were carried out to investigate the interaction of three epigenetic protein classes with synthetic histone substrates containing l- and d-lysine residues. The results reveal that out of the three classes, N-methyl lysine binding proteins are superior in accepting lysines with the d-configuration.

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Recognition of shorter and longer trimethyllysine analogues by epigenetic reader proteins

Temimi¹,

Belle²,

Kumar

et al. 2018

Chem. Commun.

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Histone N-lysine methylation is a widespread posttranslational modification that is specifically recognised by a diverse class of N-methyllysine binding reader proteins. Combined thermodynamic data, molecular dynamics simulations, and quantum chemical studies reveal that reader proteins efficiently bind trimethylornithine and trimethylhomolysine, the simplest N-trimethyllysine analogues that differ in the length of the side chain.

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The Effect of the Length of Histone H3K4me3 on Recognition by Reader Proteins

2013

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Bas J. G. E. Pieters

Natural supramolecular protein assemblies

Chemical basis for the recognition of trimethyllysine by epigenetic reader proteins

Investigatingd-lysine stereochemistry for epigenetic methylation, demethylation and recognition

Recognition of shorter and longer trimethyllysine analogues by epigenetic reader proteins

The Effect of the Length of Histone H3K4me3 on Recognition by Reader Proteins

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