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. 2017 Jul 26;292(38):15717–15730. doi: 10.1074/jbc.M117.792705

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© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.

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Figure 11. — Modeling of the amino acid changes inducing steric hindrance. A, close-up view of a hydrophobic pocket with modeled proline in place of Val¹⁸³. Val¹⁸³ makes two main-chain–to–main-chain hydrogen bonds with Ala²²⁶ (not shown). Leu¹⁷¹, Val¹⁸³, Leu¹⁹⁷, Ala²²⁶, and Phe²³⁵ of p59 correspond to Leu²⁷⁴, Leu²⁸⁴, Leu²⁹⁸, Val³²⁸, and Phe³³⁹ of Dpb2, respectively. B, close-up view of a hydrophobic pocket with modeled tryptophan in place of Leu¹⁸⁴. In the shown conformation, tryptophan clashes with the side chains of Pro²⁴³ and Leu¹³⁷. Tyr¹³⁴, Leu¹³⁷, Thr¹⁴¹, Leu¹⁶⁵, Leu¹⁸⁴, Phe²²³, Leu²²⁵, and Pro²⁴³ of p59 correspond to Tyr²²², Thr²²⁵, Val²²⁹, Ile²⁶⁸, Leu²⁸⁵, Met³²⁵, Leu³²⁷, and Pro³⁴⁷ of Dpb2, respectively. p59 and p261_C are colored according to Fig. 1. Carbons of the modeled residues are colored purple. The residues are shown as sticks. The secondary structure elements are shown with 20% transparency. Blue dashed lines depict the closest distance between the residues. Proline and tryptophan rotamers, shown in A and B, respectively, correspond to minimal steric hindrance.