发现5-氮杂吲哚（GNE-955）作为一种具有优化生物利用度的强效泛Pim抑制剂。

Discovery of 5-Azaindazole (GNE-955) as a Potent Pan-Pim Inhibitor with Optimized Bioavailability.

作者信息

Wang Xiaojing, Kolesnikov Aleksandr, Tay Suzanne, Chan Grace, Chao Qi, Do Steven, Drummond Jason, Ebens Allen J, Liu Ning, Ly Justin, Harstad Eric, Hu Huiyong, Moffat John, Munugalavadla Veerendra, Murray Jeremy, Slaga Dionysos, Tsui Vickie, Volgraf Matthew, Wallweber Heidi, Chang Jae H

机构信息

Genentech, Inc. , 1 DNA Way, South San Francisco, California 94080, United States.

ChemPartner , No. 1 Building, 998 Halei Road, Zhangjiang Hi-Tech Park, Pudong New Area, Shanghai 201203, China.

出版信息

J Med Chem. 2017 May 25;60(10):4458-4473. doi: 10.1021/acs.jmedchem.7b00418. Epub 2017 May 5.

DOI:10.1021/acs.jmedchem.7b00418

PMID:28445037

Abstract

Pim kinases have been identified as promising therapeutic targets for hematologic-oncology indications, including multiple myeloma and certain leukemia. Here, we describe our continued efforts in optimizing a lead series by improving bioavailability while maintaining high inhibitory potency against all three Pim kinase isoforms. The discovery of extensive intestinal metabolism and major metabolites helped refine our design strategy, and we observed that optimizing the pharmacokinetic properties first and potency second was a more successful approach than the reverse. In the resulting work, novel analogs such as 20 (GNE-955) were discovered bearing 5-azaindazole core with noncanonical hydrogen bonding to the hinge.

摘要

Pim激酶已被确定为血液肿瘤适应症（包括多发性骨髓瘤和某些白血病）的有前景的治疗靶点。在此，我们描述了我们在优化先导化合物系列方面的持续努力，通过提高生物利用度，同时保持对所有三种Pim激酶亚型的高抑制效力。广泛的肠道代谢和主要代谢物的发现有助于完善我们的设计策略，并且我们观察到先优化药代动力学性质再优化效力比相反的做法是更成功的方法。在后续工作中，发现了新型类似物，如带有5-氮杂吲哚核心并与铰链区有非经典氢键作用的20（GNE-955）。

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发现5-氮杂吲哚（GNE-955）作为一种具有优化生物利用度的强效泛Pim抑制剂。

Discovery of 5-Azaindazole (GNE-955) as a Potent Pan-Pim Inhibitor with Optimized Bioavailability.

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