Dou Xiao-Zheng, Nath Dinesh, Shin Younghwa, Ma Jian-Xing, Duerfeldt Adam S
Department of Chemistry & Biochemistry, Stephenson Life Sciences Research Center, University of Oklahoma, Norman, OK, United States.
Department of Physiology, University of Oklahoma Health Sciences Center, Oklahoma City, OK, United States.
Bioorg Med Chem Lett. 2018 Sep 1;28(16):2717-2722. doi: 10.1016/j.bmcl.2018.03.010. Epub 2018 Apr 5.
Small molecule agonism of PPARα represents a promising new avenue for the development of non-invasive treatments for oculovascular diseases like diabetic retinopathy and age-related macular degeneration. Herein we report initial structure-activity relationships for the newly identified quinoline-based PPARα agonist, Y-0452. Preliminary computational studies led to the hypothesis that carboxylic acid transposition and deconstruction of the Y-0452 quinoline system would enhance ligand-protein interactions and better complement the nature of the binding pocket. A focused subset of analogs was designed, synthesized, and assessed for PPARα agonism. Two key observations arose from this work 1) contrary to other PPARα agonists, incorporation of the fibrate "head-group" decreases PPARα selectivity and instead provides pan-PPAR agonists and 2) computational models reveal a relatively unexploited amphiphilic pocket in PPARα that provides new opportunities for the development of novel agonists. As an example, compound 10 exhibits more potent PPARα agonism (EC = ∼6 µM) than Y-0452 (EC = ∼50 µM) and manifests >20-fold selectivity for PPARα over the PPARγ and PPARδ isoforms. More detailed biochemical analysis of 10 confirms typical downstream responses of PPARα agonism including PPARα upregulation, induction of target genes, and inhibition of cell migration.
过氧化物酶体增殖物激活受体α(PPARα)的小分子激动作用代表了一种有前景的新途径,可用于开发针对糖尿病性视网膜病变和年龄相关性黄斑变性等眼血管疾病的非侵入性治疗方法。在此,我们报告了新鉴定的喹啉基PPARα激动剂Y-0452的初步构效关系。初步的计算研究提出了一个假设,即Y-0452喹啉系统的羧酸转位和解构将增强配体与蛋白质的相互作用,并更好地匹配结合口袋的性质。设计、合成并评估了一组聚焦的类似物的PPARα激动作用。这项工作产生了两个关键发现:1)与其他PPARα激动剂相反,引入贝特类“头基”会降低PPARα的选择性,反而产生泛PPAR激动剂;2)计算模型揭示了PPARα中一个相对未被开发的两亲性口袋,为新型激动剂的开发提供了新机会。例如,化合物10表现出比Y-0452(EC = ∼50 μM)更强的PPARα激动作用(EC = ∼6 μM),并且对PPARα的选择性比对PPARγ和PPARδ亚型高20倍以上。对10进行的更详细的生化分析证实了PPARα激动作用的典型下游反应,包括PPARα上调、靶基因诱导和细胞迁移抑制。