摘要/ Abstract 2749:吡咪酮小分子与GPCR结合的构效关系及抗癌效果的确定

V. Prabhu, A. Kawakibi, Neel S. Madhukar, L. Anantharaman, Sean W. Deacon, N. Charter, M. Garnett, U. McDermott, C. Benes, W. Oster, O. Elemento, M. Stogniew, J. Allen
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引用次数: 2

摘要

G蛋白偶联受体(gpcr)代表了fda批准的许多疾病治疗中最广泛利用的药物靶点超家族,然而,这些受体在肿瘤治疗中的利用不足。ONC201是GPCRs多巴胺受体D2 (DRD2)和DRD3的选择性拮抗剂,已被证明在高级别胶质瘤患者中可诱导肿瘤消退并具有良性安全性。ONC201 (benzyl-2-methylbenzyl-imipridone)是具有独特的三杂环核心化学结构的小分子丙米普利酮类的创始成员。吡普利酮具有几种理想的药物样特性的化学和生物学特性:口服给药、宽治疗窗口、化学稳定性和血脑屏障穿透性。在这项研究中,我们分析了一系列吡普利酮的GPCR参与和抗癌功效。几种吡普利酮通过β-抑制蛋白招募试验对大量人类gpcr进行筛选。测试的吡普利酮导致GPCR激动剂/拮抗剂活性(阈值设置为>20%的活性)是异质性的,但在代表最大类别的A类GPCR中是排他性的。对ONC201化学结构的微小化学修饰导致gpcr的激动剂与拮抗剂活性和选择性的巨大变化。具体来说,将ONC201吡喃酮核心从一个角度转换为一个线性异构体导致DRD2拮抗剂活性的丧失和对癌细胞活力的抑制受损,这表明吡喃酮核心结构对GPCR参与和抗癌作用至关重要。在甲基苄环上加入吸电子基团(如二卤素或三卤素取代)可以提高与GPCR结合的效力和抗癌作用,但对苄基环没有作用。苯环的缺失削弱了抗癌作用。在所有确定的GPCR命中中,最大的差异被确定为DRD2/DRD3拮抗剂和GPR132拮抗剂,考虑到它们在肿瘤学中的已知生物学相关性,优先考虑它们。ONC206(苄基-2,4-二氟甲基苄基-丙米普利酮)成为d2样多巴胺受体的最具选择性和最有效的拮抗剂,d2样多巴胺受体在几种癌症中过度表达,对生存至关重要。ONC212(苄基-4-三氟甲基苄基-丙米普利酮)是肿瘤抑制因子GPR132的最具选择性和最有效的激动剂。这两种化合物在超过1000个癌细胞系的GDSC面板中进行了测试,显示出广谱的纳米摩尔抑制癌细胞活力和宽的治疗窗口。GPCR靶表达与两种化合物的GDSC面板的抗癌功效相关,为反应提供了潜在的生物标志物。因此,ONC201的化学衍生化产生了一类新的gpcr靶向药物,在肿瘤学中具有良好的临床前疗效和安全性。引文格式:Varun V. Prabhu, Abed Rahman Kawakibi, Neel S. Madhukar, Lakshmi Anantharaman, Sean Deacon, Neil S. Charter, Mathew J. Garnett, Ultan McDermott, Cyril H. Benes, Wolfgang Oster, Olivier Elemento, Martin Stogniew, Joshua E. Allen确定吡咪酮小分子与GPCR结合及抗癌功效的构效关系[摘要]。摘自:2019年美国癌症研究协会年会论文集;2019年3月29日至4月3日;亚特兰大,乔治亚州。费城(PA): AACR;癌症杂志,2019;79(13增刊):2749。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Abstract 2749: Defining structure activity relationships for GPCR engagement and anti-cancer efficacy of imipridone small molecules
G protein-coupled receptors (GPCRs) represent the most widely exploited superfamily of drug targets for FDA-approved therapies for many diseases, however, these receptors are underexploited for oncology. ONC201 is a selective antagonist of GPCRs dopamine receptor D2 (DRD2) and DRD3 that has been shown to induce tumor regressions with a benign safety profile in high grade glioma patients. ONC201 (benzyl-2-methylbenzyl-imipridone) is the founding member of the imipridone class of small molecules that share a unique tri-heterocyclic core chemical structure. Imipridones share several chemical and biological properties that are desirable drug-like characteristics: oral administration, wide therapeutic window, chemical stability and blood brain barrier penetrance. In this study, we profiled a series of imipridones for GPCR engagement and anti-cancer efficacy. Several imipridones were screened against a large panel of human GPCRs using a β-arrestin recruitment assay. The imipridones tested resulted in GPCR agonist/antagonist activity (threshold set at >20% activity) that was heterogenous, but exclusive among Class A GPCRs that represent the largest class. Minor chemical modifications to the ONC201 chemical structure caused large shifts in agonist versus antagonist activity and selectivity for GPCRs. Specifically, switching the ONC201 imipridone core from an angular to a linear isomer resulted in loss of DRD2 antagonist activity and impaired inhibition of cancer cell viability, indicating the imipridone core structure is critical for GPCR engagement and anti-cancer effects. The addition of electron withdrawing groups (e.g. di- or tri-halogen substitution) to the methyl benzyl ring improved potency for GPCR engagement and anti-cancer effects, but not for the benzyl ring. Loss of the benzyl ring impaired anti-cancer effects. Among all of the GPCR hits identified, maximal variance in imipridone GPCR engagement was identified for DRD2/DRD3 antagonism and GPR132 agonism that were prioritized considering their known biological relevance in oncology. ONC206 (benzyl-2,4-difluoromethylbenzyl-imipridone) emerged as the most selective and potent antagonist for D2-like dopamine receptors that are overexpressed and critical for survival in several cancers. ONC212 (benzyl-4-trifluoromethylbenzyl-imipridone) was the most selective and potent agonist for tumor suppressor GPR132. Both compounds were tested in the GDSC panel of >1000 cancer cell lines and demonstrated broad spectrum nanomolar inhibition of cancer cell viability and a wide therapeutic window. GPCR target expression correlated with anti-cancer efficacy in the GDSC panel for both compounds, providing potential biomarkers of response. Thus, chemical derivatization of ONC201 has generated a class of novel GPCR-targeting agents with promising preclinical efficacy and safety profiles in oncology. Citation Format: Varun V. Prabhu, Abed Rahman Kawakibi, Neel S. Madhukar, Lakshmi Anantharaman, Sean Deacon, Neil S. Charter, Mathew J. Garnett, Ultan McDermott, Cyril H. Benes, Wolfgang Oster, Olivier Elemento, Martin Stogniew, Joshua E. Allen. Defining structure activity relationships for GPCR engagement and anti-cancer efficacy of imipridone small molecules [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2749.
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