Department of Clinical Development, Xenon Pharmaceuticals Inc, Burnaby, British Columbia, Canada.
Clin Genet. 2012 Oct;82(4):367-73. doi: 10.1111/j.1399-0004.2012.01942.x. Epub 2012 Aug 13.
We have utilized a novel application of human genetics, illuminating the important role that rare genetic disorders can play in the development of novel drugs that may be of relevance for the treatment of both rare and common diseases. By studying a very rare Mendelian disorder of absent pain perception, congenital indifference to pain, we have defined Nav1.7 (endocded by SCN9A) as a critical and novel target for analgesic development. Strong human validation has emerged with SCN9A gain-of-function mutations causing inherited erythromelalgia (IEM) and paroxysmal extreme pain disorder, both Mendelian disorder of spontaneous or easily evoked pain. Furthermore, variations in the Nav1.7 channel also modulate pain perception in healthy subjects as well as in painful conditions such as osteoarthritis and Parkinson disease. On the basis of this, we have developed a novel compound (XEN402) that exhibits potent, voltage-dependent block of Nav1.7. In a small pilot study, we showed that XEN402 blocks Nav1.7 mediated pain associated with IEM thereby demonstrating the use of rare genetic disorders with mutant target channels as a novel approach to rapid proof-of-concept. Our approach underscores the critical role that human genetics can play by illuminating novel and critical pathways pertinent for drug discovery.
我们利用了人类遗传学的一种新应用,阐明了罕见遗传疾病在新型药物开发中的重要作用,这些药物可能对治疗罕见病和常见病都具有重要意义。通过研究一种非常罕见的先天性无痛觉的孟德尔遗传疾病,我们发现 Nav1.7(由 SCN9A 编码)是开发镇痛药物的关键和新颖靶点。SCN9A 获得性功能突变导致遗传性红斑性肢痛症(IEM)和阵发性极度疼痛障碍,这两种疾病都是自发性或易诱发疼痛的孟德尔遗传病,强有力的人类验证已经出现。此外,Nav1.7 通道的变异也调节健康受试者以及骨关节炎和帕金森病等疼痛情况下的疼痛感知。基于此,我们开发了一种新型化合物(XEN402),它表现出对 Nav1.7 的强大、电压依赖性阻断作用。在一项小型初步研究中,我们表明 XEN402 阻断 IEM 相关的 Nav1.7 介导的疼痛,从而证明了利用具有突变靶通道的罕见遗传疾病作为快速概念验证的新方法。我们的方法强调了人类遗传学可以发挥的关键作用,阐明了与药物发现相关的新的关键途径。
