Characterization of allosteric modulators that disrupt androgen receptor co-activator protein-protein interactions to alter transactivation–Drug leads for metastatic castration resistant prostate cancer

IF 2.7 4区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS
Ashley T. Fancher , Yun Hua , David A. Close , Wei Xu , Lee A. McDermott , Christopher J. Strock , Ulises Santiago , Carlos J. Camacho , Paul A. Johnston
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引用次数: 1

Abstract

Three series of compounds were prioritized from a high content screening campaign that identified molecules that blocked dihydrotestosterone (DHT) induced formation of Androgen Receptor (AR) protein-protein interactions (PPIs) with the Transcriptional Intermediary Factor 2 (TIF2) coactivator and also disrupted preformed AR-TIF2 PPI complexes; the hydrobenzo-oxazepins (S1), thiadiazol-5-piperidine-carboxamides (S2), and phenyl-methyl-indoles (S3). Compounds from these series inhibited AR PPIs with TIF2 and SRC-1, another p160 coactivator, in mammalian 2-hybrid assays and blocked transcriptional activation in reporter assays driven by full length AR or AR-V7 splice variants. Compounds inhibited the growth of five prostate cancer cell lines, with many exhibiting differential cytotoxicity towards AR positive cell lines. Representative compounds from the 3 series substantially reduced both endogenous and DHT-enhanced expression and secretion of the prostate specific antigen (PSA) cancer biomarker in the C4–2 castration resistant prostate cancer (CRPC) cell line. The comparatively weak activities of series compounds in the H3-DHT and/or TIF2 box 3 LXXLL-peptide binding assays to the recombinant ligand binding domain of AR suggest that direct antagonism at the orthosteric ligand binding site or AF-2 surface respectively are unlikely mechanisms of action. Cellular enhanced thermal stability assays (CETSA) indicated that compounds engaged AR and reduced the maximum efficacy and right shifted the EC50 of DHT-enhanced AR thermal stabilization consistent with the effects of negative allosteric modulators. Molecular docking of potent representative hits from each series to AR structures suggest that S1–1 and S2–6 engage a novel binding pocket (BP-1) adjacent to the orthosteric ligand binding site, while S3–11 occupies the AR binding function 3 (BF-3) allosteric pocket. Hit binding poses indicate spaces and residues adjacent to the BP-1 and BF-3 pockets that will be exploited in future medicinal chemistry optimization studies. Small molecule allosteric modulators that prevent/disrupt AR PPIs with coactivators like TIF2 to alter transcriptional activation in the presence of orthosteric agonists might evade the resistance mechanisms to existing prostate cancer drugs and provide novel starting points for medicinal chemistry lead optimization and future development into therapies for metastatic CRPC.

破坏雄激素受体共激活因子蛋白的变构调节剂的特性-蛋白相互作用改变转移性去势抵抗性前列腺癌的转激活
三个系列的化合物从高含量筛选活动中被优先考虑,这些化合物确定了阻断双氢睾酮(DHT)诱导的雄激素受体(AR)蛋白与转录中介因子2 (TIF2)共激活因子相互作用(PPIs)形成的分子,并破坏预形成的AR-TIF2 PPI复合物;氢苯并恶氮平类(S1)、噻二唑-5-哌啶-羧胺类(S2)和苯基甲基吲哚类(S3)。在哺乳动物2杂交实验中,来自这些系列的化合物抑制带有TIF2和SRC-1(另一种p160共激活因子)的AR PPIs,并在全长AR或AR- v7剪接变体驱动的报告基因实验中阻断转录激活。化合物抑制五种前列腺癌细胞系的生长,其中许多对AR阳性细胞系表现出不同的细胞毒性。在C4-2去势抵抗性前列腺癌(CRPC)细胞系中,3个系列的代表性化合物显著降低了内源性和dht增强的前列腺特异性抗原(PSA)癌症生物标志物的表达和分泌。在H3-DHT和/或TIF2 box - 3 lxxll -肽结合实验中,系列化合物对AR重组配体结合域的活性相对较弱,这表明分别在正位配体结合位点或AF-2表面直接拮抗不太可能是作用机制。细胞增强热稳定性实验(CETSA)表明,化合物参与AR,降低了dht增强AR热稳定性的最大功效,右移了EC50,与负变构调节剂的作用一致。对每个系列中具有代表性的强效位点与AR结构的分子对接表明,S1-1和S2-6结合了紧邻正构配体结合位点的一个新的结合袋(BP-1),而S3-11则占据了AR结合功能3 (BF-3)变构袋。Hit结合姿势表明BP-1和BF-3口袋附近的空间和残基将在未来的药物化学优化研究中被利用。小分子变构调节剂可以阻止/破坏AR PPIs与TIF2等共激活因子在正位激动剂存在下改变转录激活,可能会逃避对现有前列腺癌药物的耐药机制,并为药物化学先导物优化和转移性CRPC治疗的未来发展提供新的起点。
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来源期刊
SLAS Discovery
SLAS Discovery Chemistry-Analytical Chemistry
CiteScore
7.00
自引率
3.20%
发文量
58
审稿时长
39 days
期刊介绍: Advancing Life Sciences R&D: SLAS Discovery reports how scientists develop and utilize novel technologies and/or approaches to provide and characterize chemical and biological tools to understand and treat human disease. SLAS Discovery is a peer-reviewed journal that publishes scientific reports that enable and improve target validation, evaluate current drug discovery technologies, provide novel research tools, and incorporate research approaches that enhance depth of knowledge and drug discovery success. SLAS Discovery emphasizes scientific and technical advances in target identification/validation (including chemical probes, RNA silencing, gene editing technologies); biomarker discovery; assay development; virtual, medium- or high-throughput screening (biochemical and biological, biophysical, phenotypic, toxicological, ADME); lead generation/optimization; chemical biology; and informatics (data analysis, image analysis, statistics, bio- and chemo-informatics). Review articles on target biology, new paradigms in drug discovery and advances in drug discovery technologies. SLAS Discovery is of particular interest to those involved in analytical chemistry, applied microbiology, automation, biochemistry, bioengineering, biomedical optics, biotechnology, bioinformatics, cell biology, DNA science and technology, genetics, information technology, medicinal chemistry, molecular biology, natural products chemistry, organic chemistry, pharmacology, spectroscopy, and toxicology. SLAS Discovery is a member of the Committee on Publication Ethics (COPE) and was published previously (1996-2016) as the Journal of Biomolecular Screening (JBS).
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