| Literature DB >> 33392964 |
Xin-Hua Lu1, Wei-Ya Li2, Shan Du2, Li-Peng Li2, Yang-Chun Ma2, Liang Zhou2, Jing-Wei Wu2, Ying Ma3, Run-Ling Wang4.
Abstract
The E69K mutation is one of the most frequent protein tyrosine phosphatase-2 (SHP2) mutations in leukemia, and it can cause the increase in the protein activity. Recent studies have shown that the E69K mutation was fairly sensitive to the allosteric inhibitor of SHP2 (SHP099). However, the molecular mechanism of the allosteric drug SHP099 inhibiting SHP2E69K remains unclear. Thus, the molecular dynamic simulations and the post-dynamics analyses (RMSF, PCA, DCCM, RIN and the binding free energies) for SHP2WT, SHP2WT-SHP099, SHP2E69K and SHP2E69K-SHP099 were carried out, respectively. Owing to the strong binding affinity of SHP099 to residues Thr219 and Arg220, the flexibility of linker region (residues Val209-Arg231) was reduced. Moreover, the presence of SHP099 kept the autoinhibition state of the SHP2 protein through enhancing the interactions between the linker region and Q loop in PTP domain, such as Thr219/Val490, Thr219/Asn491, Arg220/Ile488 and Leu254/Asn491. In addition, it was found that the residues (Thr219, Arg220, Leu254 and Asn491) might be the key residues responsible for the conformational changes of protein. Overall, this study may provide an important basis for understanding how the SHP099 effectively inhibited the SHP2E69K activity at the molecular level.Entities:
Keywords: Allosteric inhibitor SHP099; E69K mutation; Molecular dynamic simulation; Post-dynamics analyses; Protein tyrosine phosphatase-2
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Year: 2021 PMID: 33392964 DOI: 10.1007/s11030-020-10179-y
Source DB: PubMed Journal: Mol Divers ISSN: 1381-1991 Impact factor: 2.943