Characterization of functional disordered regions within chromatin-associated proteins

Musselman, Catherine A.; Kutateladze, Tatiana G.

doi:10.1016/j.isci.2021.102070

Cited by 42 publications

(33 citation statements)

References 71 publications

(135 reference statements)

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“…This loss of flexibility could additionally limit internucleosomal interactions (Collepardo-Guevara et al, 2015) and thus provide another perspective on how H4K16ac opens up chromatin. This insight was based on nuclear magnetic resonance (NMR) spectroscopy, which enables analysis of nucleosome structure and tail dynamics in combination with computational simulation studies (Musselman & Kutateladze, 2021). Similar approaches could be used to systematically compare the effect of non-acetyl acylations on histone tail dynamics for all core Box 1: Histone modification mimics and designer chromatin Site-specific mutations of histones have been used to mimic modifications or the unmodified state.…”

Section: Impact Of Histone Acylations On Chromatin Structurementioning

confidence: 99%

Histone acylations and chromatin dynamics: concepts, challenges, and links to metabolism

2021

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In eukaryotic cells, DNA is tightly packed with the help of histone proteins into chromatin. Chromatin architecture can be modified by various post-translational modifications of histone proteins. For almost 60 years now, studies on histone lysine acetylation have unraveled the contribution of this acylation to an open chromatin state with increased DNA accessibility, permissive for gene expression. Additional complexity emerged from the discovery of other types of histone lysine acylations. The acyl group donors are products of cellular metabolism, and distinct histone acylations can link the metabolic state of a cell with chromatin architecture and contribute to cellular adaptation through changes in gene expression. Currently, various technical challenges limit our full understanding of the actual impact of most histone acylations on chromatin dynamics and of their biological relevance. In this review, we summarize the state of the art and provide an overview of approaches to overcome these challenges. We further discuss the concept of subnuclear metabolic niches that could regulate local CoA availability and thus couple cellular metabolisms with the epigenome.

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Section: Impact Of Histone Acylations On Chromatin Structurementioning

confidence: 99%

Histone acylations and chromatin dynamics: concepts, challenges, and links to metabolism

2021

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“…In the last two decades, intrinsically disordered regions (IDRs) of proteins have been reported to play a role in different processes (such as protein:protein and protein:nucleic acid interactions and protein phase separation) and often be modified by PTMs, including R methylation (Bremang et al, 2013; Darling & Uversky, 2018; Musselman & Kutateladze, 2021). In addition, methylated Rs can serve as docking sites for the recruitment of other proteins and the formation of multi-protein complexes; two examples of R methylation “readers” are represented by the Tudor domain, found in several proteins linked to transcriptional regulation, mRNA splicing and formation of RNP granules (Ying & Chen, 2012), and the WD40 repeat domain, located on a wide range of scaffolding proteins whose role is to bring together interactions partners into stable complexes (Jain & Pandey, 2018).…”

Section: Resultsmentioning

confidence: 99%

ProMetheusDB: an in-depth analysis of the high-quality human methyl-proteome

Massignani

Giambruno

Maniaci

et al. 2021

Preprint

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Protein Arginine (R) methylation is a post-translational modification involved in various biological processes, such as RNA splicing, DNA repair, immune response, signal transduction, and tumour development. Although several advancements were made in the study of this modification by mass spectrometry, researchers still face the problem of a high false discovery rate. We present a dataset of high-quality methylations obtained from several different heavy methyl SILAC (hmSILAC) experiments analysed with a machine learning-based tool doublets and show that this model allows for improved high-confidence identification of real methyl-peptides. Overall, our results are consistent with the notion that protein R methylation modulates protein:RNA interactions and suggest a role in rewiring protein:protein interactions, for which we provide experimental evidence for a representative case (i.e. NONO:PSPC1). Upon intersecting our R-methyl-sites dataset with a phosphosites dataset, we observed that R methylation correlates differently with S/T-Y phosphorylation in response to various stimuli. Finally, we explored the application of hmSILAC to identify unconventional methylated residues and successfully identified novel histone methylation marks on Serine 28 and Threonine 32 of H3.

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“…In comparison with CTCF, the N-terminal domain of CLAMP apparently has more dynamic folding, which is reflected by SAXS and NMR data more typical of IDRs. Intrinsically disordered proteins are abundant within the structures of transcription factors and other chromatin-associated proteins [ 15 , 18 ]. IDRs’ protein–protein interaction properties are difficult to predict [ 56 ], and thus similar domains could be widespread within eukaryotic transcription factors.…”

Section: Discussionmentioning

confidence: 99%

“…This domain lacks secondary structure and has biochemical properties more typical of an intrinsically disordered region (IDR) [ 12 ]. IDRs are abundant in chromatin-associated proteins [ 15 , 16 ], playing diverse roles in molecular recognition, chromatin compaction, and subcellular compartmentalization through phase separation [ 17 , 18 ].…”

Section: Introductionmentioning

confidence: 99%

Dimerization Activity of a Disordered N-Terminal Domain from Drosophila CLAMP Protein

Tikhonova

Mariasina

Arkova

et al. 2022

IJMS

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In Drosophila melanogaster, CLAMP is an essential zinc-finger transcription factor that is involved in chromosome architecture and functions as an adaptor for the dosage compensation complex. Most of the known Drosophila architectural proteins have structural N-terminal homodimerization domains that facilitate distance interactions. Because CLAMP performs architectural functions, we tested its N-terminal region for the presence of a homodimerization domain. We used a yeast two-hybrid assay and biochemical studies to demonstrate that the adjacent N-terminal region between 46 and 86 amino acids is capable of forming homodimers. This region is conserved in CLAMP orthologs from most insects, except Hymenopterans. Biophysical techniques, including nuclear magnetic resonance (NMR) and small-angle X-ray scattering (SAXS), suggested that this domain lacks secondary structure and has features of intrinsically disordered regions despite the fact that the protein structure prediction algorithms suggested the presence of beta-sheets. The dimerization domain is essential for CLAMP functions in vivo because its deletion results in lethality. Thus, CLAMP is the second architectural protein after CTCF that contains an unstructured N-terminal dimerization domain.

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Characterization of functional disordered regions within chromatin-associated proteins

Cited by 42 publications

References 71 publications

Histone acylations and chromatin dynamics: concepts, challenges, and links to metabolism

Histone acylations and chromatin dynamics: concepts, challenges, and links to metabolism

ProMetheusDB: an in-depth analysis of the high-quality human methyl-proteome

Dimerization Activity of a Disordered N-Terminal Domain from Drosophila CLAMP Protein

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