Kirby Emily F, Heard Ashley S, Wang X Robert
Department of Pharmaceutical, Social and Administrative Sciences, Samford University, McWhorter School of Pharmacy, Birmingham, Alabama, USA.
J Pharmacol Clin Toxicol. 2013 Aug 28;1(1):1007.
With better understanding of the cellular and molecular pathophysiology underlying cystic fibrosis (CF), novel drugs are being developed that specifically target the molecular defects of the cystic fibrosis transmembrane conductance regulator (CFTR), a cAMP-activated chloride channel on the plasma membrane that causes CF. Starting with cell-based high-throughput screening, small molecules have been identified that are able to fix specific molecular defects of various disease-causing CFTR mutants. With the successful development of ivacaftor, a "potentiator" that enhances CFTR chloride channel activity, new types of small-molecule compounds that "correct" the misfolding and misprocessing of the most common CF-causing mutation, F508del, are actively being sought for. Recent studies focused on the potential mechanisms of action of some of the investigational CFTR "correctors" shed new light on how the F508del mutant can be targeted in an attempt to ameliorate the clinical symptoms associated with CF. A multi-layer combinational approach has been proposed to achieve the high-potency correction necessary for significant clinical outcome. The mechanistic insights obtained from such studies will shape the future therapeutics development for the vast majority of CF patients.
随着对囊性纤维化(CF)潜在细胞和分子病理生理学的深入了解,正在开发针对囊性纤维化跨膜传导调节因子(CFTR)分子缺陷的新型药物。CFTR是质膜上一种由cAMP激活的氯离子通道,其功能异常会导致CF。从小分子药物研发的最初阶段开始,基于细胞的高通量筛选技术已经鉴定出能够修复各种致病CFTR突变体特定分子缺陷的小分子。随着依伐卡托(一种增强CFTR氯离子通道活性的“增效剂”)的成功研发,人们正在积极寻找新型小分子化合物,以“纠正”最常见的致CF突变F508del的错误折叠和错误加工。最近关于一些CFTR“校正剂”潜在作用机制的研究,为如何靶向F508del突变体以改善与CF相关的临床症状提供了新线索。为了获得显著临床疗效所需的高效校正效果,人们提出了一种多层组合方法。这些研究获得的机制性见解将为绝大多数CF患者塑造未来的治疗方案发展方向。