发现强效且选择性的 BRD4 抑制剂,能够阻断 TLR3 诱导的急性气道炎症。
Discovery of potent and selective BRD4 inhibitors capable of blocking TLR3-induced acute airway inflammation.
机构信息
Chemical Biology Program, Department of Pharmacology and Toxicology, Galveston, TX, 77555, USA.
Department of Internal Medicine, Galveston, TX, 77555, USA; Sealy Center for Molecular Medicine, Galveston, TX, 77555, USA.
出版信息
Eur J Med Chem. 2018 May 10;151:450-461. doi: 10.1016/j.ejmech.2018.04.006. Epub 2018 Apr 3.
Abstract
A series of diverse small molecules have been designed and synthesized through structure-based drug design by taking advantage of fragment merging and elaboration approaches. Compounds ZL0420 (28) and ZL0454 (35) were identified as potent and selective BRD4 inhibitors with nanomolar binding affinities to bromodomains (BDs) of BRD4. Both of them can be well docked into the acetyl-lysine (KAc) binding pocket of BRD4, forming key interactions including the critical hydrogen bonds with Asn140 directly and Tyr97 indirectly via a HO molecule. Both compounds 28 and 35 exhibited submicromolar potency of inhibiting the TLR3-dependent innate immune gene program, including ISG54, ISG56, IL-8, and Groβ genes in cultured human small airway epithelial cells (hSAECs). More importantly, they also demonstrated potent efficacy reducing airway inflammation in a mouse model with low toxicity, indicating a proof of concept that BRD4 inhibitors may offer the therapeutic potential to block the viral-induced airway inflammation.
摘要
通过基于结构的药物设计,利用片段融合和衍生化方法,设计和合成了一系列不同的小分子。化合物 ZL0420(28)和 ZL0454(35)被鉴定为具有强大和选择性的 BRD4 抑制剂,对 BRD4 的溴结构域(BDs)具有纳摩尔的结合亲和力。它们都可以很好地对接进 BRD4 的乙酰-赖氨酸(KAc)结合口袋,形成关键相互作用,包括与 Asn140 直接和 Tyr97 通过一个 HO 分子间接形成的关键氢键。这两种化合物 28 和 35 都表现出对 TLR3 依赖性先天免疫基因程序的亚微摩尔抑制作用,包括在培养的人小气道上皮细胞(hSAECs)中的 ISG54、ISG56、IL-8 和 Groβ 基因。更重要的是,它们还在具有低毒性的小鼠模型中表现出抑制气道炎症的有效作用,这表明 BRD4 抑制剂可能具有阻断病毒诱导的气道炎症的治疗潜力,这为概念验证提供了证据。
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