Volume 22, Issue 2, Pages (February 2014)

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Volume 22, Issue 2, Pages 353-360 (February 2014) Structural Insights into Acetylated-Histone H4 Recognition by the Bromodomain-PHD Finger Module of Human Transcriptional Coactivator CBP  Alexander N. Plotnikov, Shuai Yang, Thomas Jiachi Zhou, Elena Rusinova, Antonio Frasca, Ming-Ming Zhou  Structure  Volume 22, Issue 2, Pages 353-360 (February 2014) DOI: 10.1016/j.str.2013.10.021 Copyright © 2014 Elsevier Ltd Terms and Conditions

Figure 1 Crystal Structure of CBP BrD-PHD in Complex with H4K20ac Peptide (A) Domain organization of CBP and other human BrD proteins (left). Phylogenetic tree of human BrD proteins (right). (B) Ribbon depiction of 3D structure of the tandem BrD (green) and PHD finger (orange) of CBP bound to a histone H4K20ac peptide (shown in sticks with carbon atoms in yellow). The linker of the BrD-PHD module is colored in light cyan and regions that lack electron density are indicated by dots. Zinc atoms are shown in magenta spheres. (C) Surface-filled representation of the CBP BrD-PHD/H4K20ac complex structure. (D) Electrostatic surface potential representation of the CBP BrD-PHD/H4K20ac structure. See also Figure S1. Structure 2014 22, 353-360DOI: (10.1016/j.str.2013.10.021) Copyright © 2014 Elsevier Ltd Terms and Conditions

Figure 2 Molecular Basis of Histone Recognition of the BrD-PHD Module of CBP (A) A close-up view of the PHD finger of CBP. The residues coordinating the zinc atoms (in magenta spheres) are in sticks and labeled. (B) Interdomain interactions of the Brd and the PHD finger of CBP. (C) Structural comparison of the tandem BrD-PHD finger modules of CBP, BPTF, TRIM24, TRIM28, and TRIM33. PHD modules are colored in orange, BrDs are in blue, CBP is in green, and linkers between domains are in light cyan. Zinc atoms are shown in magenta spheres. (D) Superimposition of CBP and BPTF PHD modules. The domain is represented in cartoons and is colored in orange and salmon for CBP and BPTF, respectively. Zinc atoms are shown in magenta and salmon spheres for CBP and BPTF, respectively. On the right is a surface representation of BPTF PHD finger bound to H3K4me2 peptide (shown in sticks with carbon atom labeled in yellow). The residues comprising aromatic cage are shown in sticks. (E) A surface representation of a model of CBP bound to H3K4me2 peptide. The orientation is as in (A). (F) Close-up view of a model of the CBP PHD finger bound to H3K4me2 peptide. The residues close to the methylated lysine and line up the groove of the domain are shown in sticks and labeled. See also Figures S2 and S3. Structure 2014 22, 353-360DOI: (10.1016/j.str.2013.10.021) Copyright © 2014 Elsevier Ltd Terms and Conditions

Figure 3 Molecular Insights into H4 Recognition by the BrDs of CBP versus BRD4 (A) A close-up view of superimposed crystal structures of CBP BrD-PHD bound to H4K20ac (yellow) and H4K12ac/K16ac (white). The H4 peptides are color coded by atom type. (B and C) Close-up views of acetylated H4 binding sites in the individual structure of CBP BrD-PHD bound to H4K20ac (yellow) and H4K12ac/K16ac (white). Key protein residues interacting with the peptides are shown in sticks. (D) Binding affinity of lysine-acetylated H4 peptides by the BrDs of CBP and BRD4, determined in a fluorescence anisotropy assay. The H4 peptides H4K5ac/K8ac, H4K12ac/K16ac, and H4K20ac consist of H4 residues 1–13, 5–25, and 17–23, respectively. (E) Superimposition of ligand-binding pockets of CBP BrD and BRD4-BrD1. The ligand binding sites are shown in transparent surfaces and colored in gray and light orange for CBP BrD and BRD4-BrD1, respectively. H4K5ac/K8ac peptide of BRD4-BrD1-H4K5ac/K8ac complex and H4K20ac peptide of CBP-BrD-PHD/H4K20ac complex are colored in cyan and gray, respectively. Acetyl-lysine residues are shown in sticks. Water molecules tightly bound in the ligand binding sites are shown in spheres. In the left panel, CBP protein chain is shown in cartoon and colored in green. (F) The role of water molecules in acetyl-lysine recognition by the BrDs. Schematic diagram of the interaction between water molecules in acetyl-lysine binding sites of CBP-H4K20ac and BRD4-BrD1-H4K5ac8Kac complexes. Water molecules are shown in spheres, hydrogen bonds are drawn in dashed line, and donor-acceptor distances are given. The figure was generated by using the program LIGPLOT. (G) Structural comparison of singly and dually lysine-acetylated H4 peptides by CBP (left) and BRD4 BrDs (middle), respectively. CBP and BRD4 are shown in light gray surfaces, carbon atoms of H4K20Ac and H4K5Ac8Ac peptides are colored in yellow and cyan, respectively, residues interacting with peptides are shown in sticks, and carbon atoms are in light gray. The right panel shows structure superimposition of CBP-BrD-PHD/H4K20ac and BRD4-BrD1-H4K5ac/K8ac complexes. Surface representation of CBP is shown only. Residues involved in discriminating of binding singly and diacetylated H4 are shown in sticks and carbon atoms are colored in green. See also Figure S4. Structure 2014 22, 353-360DOI: (10.1016/j.str.2013.10.021) Copyright © 2014 Elsevier Ltd Terms and Conditions