Peng Y , Li S , Onufriev A , Landsman D , Panchenko AR .

R21 GM134404 NIGMS NIH HHS

             nucleosome
             DNA binding
             nucleosomal histone binding

	Fig. 1: Binding of histone tails to nucleosomal and linker DNA in the context of the full nucleosome. a Interconversions of DNA-bound and unbound tail conformations. The conformational snapshots are taken from the last frame of each simulation run and superimposed onto the initial models by minimizing RMSD values of Cα atoms in histone cores. While we observe multiple binding/unbinding events in the simulations, only a few snapshots are shown for clarity. b A total number of full histone tail binding/unbinding events observed in all simulations for both copies of histones. c Full histone tail residence time. Each point represents a binding/unbinding event observed in simulations for each histone copy (n(H2A_N) = 174, n(H2A_C) = 359, n(H2B) = 173, n(H3) = 31, n(H4) = 160). Data points with residence time shorter than 10 ns are excluded as this time is required for establishing stable interactions with DNA. An unbound state for the full tail is defined if no more than 10% of the tail residues maintain contacts with DNA (other cut-off values are given in Supplementary Fig. 2). Box-plot elements are defined as: center line, median; box limits, upper and lower quartiles; whiskers are drawn at values equal to 1.5× interquartile range; d The histone tail–DNA standard binding free energy derived from counting the number of bound/unbound events in histone tail conformational ensemble in all simulations for both copies of histones (number of binding/unbinding events ≥ 5, Supplementary Table 4). e A representative run shows a fraction of DNA bound residues and tail binding/unbinding events during simulation for H2B tails (see Supplementary Figs. 6–10 for other tails). Source data are provided as a Source Data file.
	Fig. 2: Nucleosomal and linker DNA solvent accessibility modulated by histone tail binding. a A mean number of contacts between histone tails and nucleosomal/linker DNA averaged over all independent simulation runs for two copies (n = 44) plotted in the DNA coordinate frame, zero corresponds to the dyad position and superhelical locations (SHL) are shown as integers; a combined conformational ensemble from both copies of histone tails is shown. The error bars represent standard errors of the mean calculated from independent simulation runs. b Mean number of contacts between histone tails and DNA mapped onto the molecular surface of the nucleosomal and linker DNA. c Mean values of changes of DNA solvent accessibility imposed by tail binding. The error bars represent standard errors of the mean calculated from independent simulation runs for two copies (n = 44). d Percentage of frames with more than 20% SASA decrease upon tail binding per DNA base pair. Source data are provided as a Source Data file
	Fig. 3: Histone tail-modulated recognition modes of nucleosomes by binding partners. a A summary of 131 available nucleosome complex structures classified based on their binding entity and function. b An example of chromatin remodeler ISWI which binds to both histone H4 tail and DNA (PDB: 6IRO). Here coordinates of histone tails are taken from the PDB structure. Nucleosome-binding proteins are colored in orange and histone tails are colored using their canonical colors. c Analysis of the contact numbers between the nucleosomal/linker DNA and partners (averaged over all structures of nucleosome complexes) plotted in DNA coordinate frame. The error bars represent standard errors calculated from the number of contacts of different nucleosome complex structures (n = 86). The top track shows the presence or absence of five or more contacts between histone tails and DNA regions (indicating the histone tail preferred binding regions). d The fraction of interface overlap between tail–DNA and partner–DNA binding interfaces. It is calculated for each nucleosome complex structure and the distribution is smoothed using the gaussian kernel function. e, f Examples of INO80 chromatin remodeler (PDB: 6HTS) and UV-damaged DNA-binding protein (PDB: 6R8Z) targeting overlapping regions on DNA. Histone tail representative conformations are taken from simulations and superimposed onto the PDB structures. The intensity of the color of the DNA surface is scaled with the mean number of contacts between histone tails and DNA as in Fig. 2b. Source data are provided as a Source Data file.
	Fig. 4: Recognition of nucleosomal DNA and histone tails by binding partners depicted via electrostatic potential analysis. Nucleosome complex structures where proteins interact with DNA are classified based on their histone tail binding modes. Positively charged DNA-binding interfaces are highlighted for chromatin remodeler INO80 (PDB: 6HTS) and UV-damaged DNA-binding protein (PDB: 6R8Z) where partners do not interact with histone tails in structures. Another two representative examples, chromatin remodeler ISWI (PDB: 6IRO) and polycomb repressive complex 2 (PDB: 6WKR), show the DNA-binding interfaces and the partner acidic patches recognized by H3 and H4 tails. Electrostatic potentials are mapped onto the molecular surfaces of nucleosome-binding proteins. Blue and red colors indicate the positive and negative electrostatic potentials, and the intensity of the color is scaled with the surface electrostatic potential values. H3 and H4 tails are colored light blue and green. The molecular surface of nucleosomal and linker DNA is highlighted with cyan color. Core histone regions are not shown for clarity.
	Fig. 5: Histone tail post-translational modifications and mutations modulate histone tail–DNA interaction modes and DNA accessibility. a Mean number of histone tail–DNA contacts for different types of modifications per residue. The result of simulations of model D with and without corresponding modifications are shown in different colors and modifications are shown by a symbol next to the residue. b Mean numbers of nucleosomal and linker DNA contacts with histone tails for different types of modifications per DNA base pair. For each type of modification, the reported values are averaged, and the error bars represent the standard errors of the mean calculated from independent simulation runs for two copies (n = 10). The locations and types of modifications and mutations are listed in Supplementary Table 2. The mean number of contacts of unmodified tails was calculated using the first 1600 ns frames from the trajectory of the simulation of Model D with the AMBER package (Supplementary Table 1). Source data are provided as a Source Data file.
	Fig. 6: A generalized model explaining how tails and their modifications can modulate nucleosomes’ interactions with nucleosome-binding proteins. a Histone tails’ interactions with DNA may in some cases modulate the accessibility of DNA to binding partners; nucleosome-binding proteins compete with histone tails for binding to DNA. b Post-translational modifications and mutations in histone tails can suppress tail–DNA interactions, enhance histone tail dynamics, and regulate the binding of proteins to nucleosomes. c Some nucleosome-binding proteins may exhibit multivalent binding modes and recognize both histones and DNA. d DNA-binding domains (DBDs) of nucleosome-binding proteins compete with histone tails if they recognize DNA and reader domains compete with DNA if they recognize tails; interactions of DBD with nucleosome can displace histone tails from their DNA preferred binding modes and increase their accessibility for recognition by reader domains.

Allahverdi, The effects of histone H4 tail acetylations on cation-induced chromatin folding and self-association. 2011, Pubmed

Allahverdi, The effects of histone H4 tail acetylations on cation-induced chromatin folding and self-association. 2011, Pubmed
Angelov, Preferential interaction of the core histone tail domains with linker DNA. 2001, Pubmed
Armeev, Histone dynamics mediate DNA unwrapping and sliding in nucleosomes. 2021, Pubmed
Bascom, Chromatin Fiber Folding Directed by Cooperative Histone Tail Acetylation and Linker Histone Binding. 2018, Pubmed
Bergonzo, Improved Force Field Parameters Lead to a Better Description of RNA Structure. 2015, Pubmed
Berman, The Protein Data Bank. 2000, Pubmed
Böhm, Proteases as structural probes for chromatin: the domain structure of histones. 1984, Pubmed
Bonnet, Quantification of Proteins and Histone Marks in Drosophila Embryos Reveals Stoichiometric Relationships Impacting Chromatin Regulation. 2019, Pubmed
Chakraborty, Molecular Mechanism for the Role of the H2A and H2B Histone Tails in Nucleosome Repositioning. 2018, Pubmed
Chakraborty, Asymmetric breathing motions of nucleosomal DNA and the role of histone tails. 2017, Pubmed
Davey, Solvent mediated interactions in the structure of the nucleosome core particle at 1.9 a resolution. 2002, Pubmed , Xenbase
Draizen, HistoneDB 2.0: a histone database with variants--an integrated resource to explore histones and their variants. 2016, Pubmed
El Kennani, MS_HistoneDB, a manually curated resource for proteomic analysis of human and mouse histones. 2017, Pubmed
Eswar, Comparative protein structure modeling using Modeller. 2006, Pubmed
Ferreira, Histone tails and the H3 alphaN helix regulate nucleosome mobility and stability. 2007, Pubmed , Xenbase
Gaffney, Controls of nucleosome positioning in the human genome. 2012, Pubmed
Galindo-Murillo, Assessing the Current State of Amber Force Field Modifications for DNA. 2016, Pubmed
Gao, Binding enthalpy calculations for a neutral host-guest pair yield widely divergent salt effects across water models. 2015, Pubmed
Gao, Histone H3 and H4 N-terminal tails in nucleosome arrays at cellular concentrations probed by magic angle spinning NMR spectroscopy. 2013, Pubmed
Gatchalian, Accessibility of the histone H3 tail in the nucleosome for binding of paired readers. 2017, Pubmed
Gebala, Ion counting demonstrates a high electrostatic field generated by the nucleosome. 2019, Pubmed , Xenbase
Ghoneim, Histone Tail Conformations: A Fuzzy Affair with DNA. 2021, Pubmed
Hart, Optimization of the CHARMM additive force field for DNA: Improved treatment of the BI/BII conformational equilibrium. 2012, Pubmed
Huang, CHARMM36m: an improved force field for folded and intrinsically disordered proteins. 2017, Pubmed
Huang, SnapShot: histone modifications. 2014, Pubmed
Humphrey, VMD: visual molecular dynamics. 1996, Pubmed
Ikebe, H3 Histone Tail Conformation within the Nucleosome and the Impact of K14 Acetylation Studied Using Enhanced Sampling Simulation. 2016, Pubmed
Iwasaki, Contribution of histone N-terminal tails to the structure and stability of nucleosomes. 2013, Pubmed
Javanainen, Atomistic Model for Nearly Quantitative Simulations of Langmuir Monolayers. 2018, Pubmed
Kale, Molecular recognition of nucleosomes by binding partners. 2019, Pubmed
Kang, Sequence-dependent DNA condensation as a driving force of DNA phase separation. 2018, Pubmed
Khoury, Forcefield_PTM: Ab Initio Charge and AMBER Forcefield Parameters for Frequently Occurring Post-Translational Modifications. 2013, Pubmed
Klemm, Chromatin accessibility and the regulatory epigenome. 2019, Pubmed
Korolev, A systematic analysis of nucleosome core particle and nucleosome-nucleosome stacking structure. 2018, Pubmed
Lehmann, Dynamics of the nucleosomal histone H3 N-terminal tail revealed by high precision single-molecule FRET. 2020, Pubmed , Xenbase
Li, Web 3DNA 2.0 for the analysis, visualization, and modeling of 3D nucleic acid structures. 2019, Pubmed
Li, DelPhi Suite: New Developments and Review of Functionalities. 2019, Pubmed
Li, Distinct Roles of Histone H3 and H2A Tails in Nucleosome Stability. 2016, Pubmed
Liu, dbAMEPNI: a database of alanine mutagenic effects for protein-nucleic acid interactions. 2018, Pubmed
Luger, Crystal structure of the nucleosome core particle at 2.8 A resolution. 1997, Pubmed
Maier, ff14SB: Improving the Accuracy of Protein Side Chain and Backbone Parameters from ff99SB. 2015, Pubmed
Makowski, Global profiling of protein-DNA and protein-nucleosome binding affinities using quantitative mass spectrometry. 2018, Pubmed
Morrison, Nucleosome composition regulates the histone H3 tail conformational ensemble and accessibility. 2021, Pubmed
Morrison, The conformation of the histone H3 tail inhibits association of the BPTF PHD finger with the nucleosome. 2018, Pubmed
Murphy, HMGN1 and 2 remodel core and linker histone tail domains within chromatin. 2017, Pubmed , Xenbase
Nacev, The expanding landscape of 'oncohistone' mutations in human cancers. 2019, Pubmed
Parsons, Critical role of histone tail entropy in nucleosome unwinding. 2019, Pubmed
Peng, Histone tails as signaling antennas of chromatin. 2021, Pubmed
Pepenella, Intra- and inter-nucleosome interactions of the core histone tail domains in higher-order chromatin structure. 2014, Pubmed
Pettersen, UCSF Chimera--a visualization system for exploratory research and analysis. 2004, Pubmed
Phair, Global nature of dynamic protein-chromatin interactions in vivo: three-dimensional genome scanning and dynamic interaction networks of chromatin proteins. 2004, Pubmed
Pich, Somatic and Germline Mutation Periodicity Follow the Orientation of the DNA Minor Groove around Nucleosomes. 2018, Pubmed
Pilotto, Interplay among nucleosomal DNA, histone tails, and corepressor CoREST underlies LSD1-mediated H3 demethylation. 2015, Pubmed
Pohl, bwtool: a tool for bigWig files. 2014, Pubmed
Rhee, Subnucleosomal structures and nucleosome asymmetry across a genome. 2014, Pubmed
Rohs, The role of DNA shape in protein-DNA recognition. 2009, Pubmed
Rose, The RCSB protein data bank: integrative view of protein, gene and 3D structural information. 2017, Pubmed
Shabane, General Purpose Water Model Can Improve Atomistic Simulations of Intrinsically Disordered Proteins. 2019, Pubmed
Shabane, Significant compaction of H4 histone tail upon charge neutralization by acetylation and its mimics, possible effects on chromatin structure. 2021, Pubmed
Shaytan, Hydroxyl-radical footprinting combined with molecular modeling identifies unique features of DNA conformation and nucleosome positioning. 2017, Pubmed
Shaytan, Coupling between Histone Conformations and DNA Geometry in Nucleosomes on a Microsecond Timescale: Atomistic Insights into Nucleosome Functions. 2016, Pubmed , Xenbase
Skrajna, Comprehensive nucleosome interactome screen establishes fundamental principles of nucleosome binding. 2020, Pubmed
Stützer, Modulations of DNA Contacts by Linker Histones and Post-translational Modifications Determine the Mobility and Modifiability of Nucleosomal H3 Tails. 2016, Pubmed , Xenbase
Sun, TMB Library of Nucleosome Simulations. 2019, Pubmed
Takada, Nucleosomes as allosteric scaffolds for genetic regulation. 2020, Pubmed
Tan, Nucleosome allostery in pioneer transcription factor binding. 2020, Pubmed
UniProt Consortium, UniProt: a worldwide hub of protein knowledge. 2019, Pubmed
Valieva, Stabilization of Nucleosomes by Histone Tails and by FACT Revealed by spFRET Microscopy. 2017, Pubmed
Weaver, Reading More than Histones: The Prevalence of Nucleic Acid Binding among Reader Domains. 2018, Pubmed
Zhou, Histone H4 K16Q mutation, an acetylation mimic, causes structural disorder of its N-terminal basic patch in the nucleosome. 2012, Pubmed
Zhou, Distinct Structures and Dynamics of Chromatosomes with Different Human Linker Histone Isoforms. 2021, Pubmed