去氢骆驼蓬碱
β细胞
生物
细胞生长
细胞生物学
BETA(编程语言)
NFAT公司
小岛
癌症研究
转录因子
胰岛素
药理学
内分泌学
遗传学
程序设计语言
计算机科学
基因
作者
Peng Wang,Juan Carlos Álvarez-Pérez,Dan P. Felsenfeld,Hongtao Liu,Sharmila Sivendran,Aaron Bender,Anil Kumar,Roberto Sánchez,Donald K. Scott,Adolfo García‐Ocaña,Andrew F. Stewart
出处
期刊:Nature Medicine
[Nature Portfolio]
日期:2015-03-09
卷期号:21 (4): 383-388
被引量:384
摘要
Types 1 and 2 diabetes affect some 380 million people worldwide. Both ultimately result from a deficiency of functional pancreatic insulin-producing beta cells. Beta cells proliferate in humans during a brief temporal window beginning around the time of birth, with a peak percentage (∼2%) engaged in the cell cycle in the first year of life. In embryonic life and after early childhood, beta cell replication is barely detectable. Whereas beta cell expansion seems an obvious therapeutic approach to beta cell deficiency, adult human beta cells have proven recalcitrant to such efforts. Hence, there remains an urgent need for antidiabetic therapeutic agents that can induce regeneration and expansion of adult human beta cells in vivo or ex vivo. Here, using a high-throughput small-molecule screen (HTS), we find that analogs of the small molecule harmine function as a new class of human beta cell mitogenic compounds. We also define dual-specificity tyrosine-regulated kinase-1a (DYRK1A) as the likely target of harmine and the nuclear factors of activated T cells (NFAT) family of transcription factors as likely mediators of human beta cell proliferation and differentiation. Using three different mouse and human islet in vivo-based models, we show that harmine is able to induce beta cell proliferation, increase islet mass and improve glycemic control. These observations suggest that harmine analogs may have unique therapeutic promise for human diabetes therapy. Enhancing the potency and beta cell specificity of these compounds are important future challenges.
科研通智能强力驱动
Strongly Powered by AbleSci AI