Antipsychotic phenothiazine drugs bind to KRAS in vitro

IF 1.3 3区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biomolecular NMR Pub Date : 2021-06-26 DOI:10.1007/s10858-021-00371-z

Xu Wang, Alemayehu A. Gorfe, John A. Putkey

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引用次数: 1

Abstract

We used NMR to show that the antipsychotic phenothiazine drugs promazine and promethazine bind to GDP-KRAS. Promazine also binds to oncogenic GDP-KRAS(G12D), and to wild type GppNHp-KRAS. A panel of additional phenothiazines bind to GDP-KRAS but with lower affinity than promazine or promethazine. Binding is most dependent on substitutions at C-2 of the tricyclic phenothiazine ring. Promazine was used to generate an NMR-driven HADDOCK model of the drug/GDP-KRAS complex. The structural model shows the tricyclic phenothiazine ring of promazine associates with the hydrophobic pocket p1 that is bordered by the central β sheet and Switch II in KRAS. Binding appears to stabilize helix 2 in a conformation that is similar to that seen in KRAS bound to other small molecules. Association of phenothiazines with KRAS may affect normal KRAS signaling that could contribute to multiple biological activities of these antipsychotic drugs. Moreover, the phenothiazine ring represents a new core scaffold on which to design modulators of KRAS activity.

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抗精神病吩噻嗪类药物与KRAS的体外结合

我们用核磁共振表明抗精神病的吩噻嗪类药物丙嗪和异丙嗪与GDP-KRAS结合。丙嗪还能结合致癌GDP-KRAS(G12D)和野生型gppnpp - kras。一组额外的吩噻嗪与GDP-KRAS结合，但与丙嗪或异丙嗪的亲和力较低。结合最依赖于三环吩噻嗪环C-2的取代。Promazine用于生成药物/GDP-KRAS复合物的核磁共振驱动HADDOCK模型。结构模型显示，丙嗪的三环吩噻嗪环与KRAS中以中心β片和Switch II为边界的疏水口袋p1相结合。结合似乎稳定了螺旋2的构象，类似于KRAS与其他小分子结合的构象。吩噻嗪类药物与KRAS的关联可能影响正常的KRAS信号传导，从而影响这些抗精神病药物的多种生物活性。此外，吩噻嗪环代表了一个新的核心支架，在其上设计KRAS活性调节剂。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomolecular NMR 生物-光谱学

CiteScore

6.00

自引率

3.70%

发文量

审稿时长

6-12 weeks

期刊介绍： The Journal of Biomolecular NMR provides a forum for publishing research on technical developments and innovative applications of nuclear magnetic resonance spectroscopy for the study of structure and dynamic properties of biopolymers in solution, liquid crystals, solids and mixed environments, e.g., attached to membranes. This may include: Three-dimensional structure determination of biological macromolecules (polypeptides/proteins, DNA, RNA, oligosaccharides) by NMR. New NMR techniques for studies of biological macromolecules. Novel approaches to computer-aided automated analysis of multidimensional NMR spectra. Computational methods for the structural interpretation of NMR data, including structure refinement. Comparisons of structures determined by NMR with those obtained by other methods, e.g. by diffraction techniques with protein single crystals. New techniques of sample preparation for NMR experiments (biosynthetic and chemical methods for isotope labeling, preparation of nutrients for biosynthetic isotope labeling, etc.). An NMR characterization of the products must be included.