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Joe G. Greener, Ioannis Filippis, Michael J.E. Sternberg  Structure 

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Presentation on theme: "Joe G. Greener, Ioannis Filippis, Michael J.E. Sternberg  Structure "— Presentation transcript:

1 Predicting Protein Dynamics and Allostery Using Multi-Protein Atomic Distance Constraints 
Joe G. Greener, Ioannis Filippis, Michael J.E. Sternberg  Structure  Volume 25, Issue 3, Pages (March 2017) DOI: /j.str Copyright © 2017 The Authors Terms and Conditions

2 Structure 2017 25, 546-558DOI: (10.1016/j.str.2017.01.008)
Copyright © 2017 The Authors Terms and Conditions

3 Figure 1 T4-Lysozyme Ensembles
(A) Four structures generated from ExProSE using the open (PDB: 169L, chain E) and closed (PDB: 2LZM) conformations as input are shown in orange. The crystal structures of the open and closed conformations are shown in blue and green, respectively, for reference. The arrow shows the opening motion caused by the breaking of a hydrogen bond between Arg137 and Glu22. (B) Projections of the 38 crystal structures used in a prior study (de Groot et al., 1998) onto the first (x axis) and second (y axis) PCs of the PCA of the crystal structures, which account for 70% and 12% of the motion, respectively (black dots). Projections from the ensembles generated with ExProSE are also shown (red dots). (C) Projections of two tCONCOORD ensembles on the same plot as (B). An ensemble using the open structure as input (blue dots) and an ensemble using the closed structure as input (yellow dots) are shown. (D) Projections of two NMSim ensembles with parameters for large-scale motions on the same plot as (B). An ensemble using the open structure as input (blue dots) and an ensemble using the closed structure as input (yellow dots) are shown. See also Figure S1 and Table S1. Structure  , DOI: ( /j.str ) Copyright © 2017 The Authors Terms and Conditions

4 Figure 2 MD T4-Lysozyme Ensembles
Projections of two repeats of a particular MD run onto the PCA of the crystal structures are shown (blue and yellow dots), with snapshots taken every 100 ps. Similarly to Figure 1, in each graph the projections of the crystals are also shown (black dots). (A) 50-ns MD runs starting from the closed structure (PDB: 2LZM). (B) 50-ns MD runs starting from the open structure (PDB: 169L). (C) 20-ns targeted MD runs starting from the closed structure and targeting the open structure. (D) 20-ns targeted MD runs starting from the open structure and targeting the closed structure. Structure  , DOI: ( /j.str ) Copyright © 2017 The Authors Terms and Conditions

5 Figure 3 Closest Models from Each Ensemble to T4-Lysozyme Crystal Structures (A) The RMSD of the closest model from each generated ensemble to the crystal structures. The crystal structures are sorted by the lower of the two RMSD values to the open and closed crystals used as input. The crystals used as inputs are omitted from the graph. (B) PROCHECK overall G factors of the closest model from each generated ensemble to the crystal structures. The crystal structures are sorted as in (A). Structure  , DOI: ( /j.str ) Copyright © 2017 The Authors Terms and Conditions

6 Figure 4 CDK2 Pockets and Projections of Ensembles
(A) CDK2 in its holo conformation bound to two ANS molecules in the allosteric site (PDB: 3PXF). CDK2 is shown as a green cartoon with the two bound ANS shown as blue sticks. Pocket centers predicted by LIGSITEcs are shown as purple spheres. The pockets are numbered by descending volume. Pocket 1 represents the ANS allosteric pocket. Pocket 2 represents the ATP binding pocket. (B) Structures generated using ExProSE, with input structures the apo and holo structures (PDB: 1HCL and 3PXF, respectively), are shown as red dots. The axes are projections onto the first (x axis) and third (y axis) PCs of the ExProSE ensemble, which account for 35% and 8% of the motion, respectively. The blue dots represent the structures in the ensemble with perturbation at pocket centers 1–8 from (A). Structure  , DOI: ( /j.str ) Copyright © 2017 The Authors Terms and Conditions

7 Figure 5 Mean Square Fluctuations across CAP Ensembles Compared with Apo-CAP The four ensembles are generated separately. Apo-CAP has no cAMP. The other ensembles have additional constraints (see Experimental Procedures) representing cAMP bound to chain A, cAMP bound to chain B, or cAMP bound to both chains A and B. The bound cAMP molecules are shown for reference as green sticks. Red regions indicate residues with more flexibility compared with apo-CAP, and blue regions indicate residues with less flexibility compared with apo-CAP. Structure  , DOI: ( /j.str ) Copyright © 2017 The Authors Terms and Conditions

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