Department of Biotechnology, Nerviano Medical Sciences Srl, Nerviano (MI), Italy.
Clin Cancer Res. 2013 Jul 1;19(13):3520-32. doi: 10.1158/1078-0432.CCR-12-3512. Epub 2013 May 14.
Recent developments of second generation Hsp90 inhibitors suggested a potential for development of this class of molecules also in tumors that have become resistant to molecular targeted agents. Disease progression is often due to brain metastases, sometimes related to insufficient drug concentrations within the brain. Our objective was to identify and characterize a novel inhibitor of Hsp90 able to cross the blood-brain barrier (BBB).
Here is described a detailed biochemical and crystallographic characterization of NMS-E973. Mechanism-based anticancer activity was described in cell models, including models of resistance to kinase inhibitors. Pharmacokinetics properties were followed in plasma, tumor, liver, and brain. In vivo activity and pharmacodynamics, as well as the pharmacokinetic/pharmacodynamic relationships, were evaluated in xenografts, including an intracranially implanted melanoma model.
NMS-E973, representative of a novel isoxazole-derived class of Hsp90 inhibitors, binds Hsp90α with subnanomolar affinity and high selectivity towards kinases, as well as other ATPases. It possesses potent antiproliferative activity against tumor cell lines and a favorable pharmacokinetic profile, with selective retention in tumor tissue and ability to cross the BBB. NMS-E973 induces tumor shrinkage in different human tumor xenografts, and is highly active in models of resistance to kinase inhibitors. Moreover, consistent with its brain penetration, NMS-E973 is active also in an intracranially implanted melanoma model.
Overall, the efficacy profile of NMS-E973 suggests a potential for development in different clinical settings, including tumors that have become resistant to molecular targeted agents, particularly in cases of tumors which reside beyond the BBB.
第二代 Hsp90 抑制剂的最新进展表明,该类分子也有可能在对分子靶向药物产生耐药的肿瘤中得到发展。疾病的进展通常是由于脑转移,有时与大脑内的药物浓度不足有关。我们的目标是鉴定和表征一种新型的 Hsp90 抑制剂,使其能够穿过血脑屏障(BBB)。
本文详细描述了 NMS-E973 的生化和晶体学特征。在细胞模型中,包括对激酶抑制剂耐药的模型中,描述了基于机制的抗癌活性。在血浆、肿瘤、肝脏和大脑中监测了药代动力学特性。在异种移植模型中,包括颅内植入的黑色素瘤模型,评估了体内活性和药效学以及药代动力学/药效学关系。
NMS-E973 是一种新型异噁唑衍生的 Hsp90 抑制剂,对 Hsp90α 的结合具有亚纳摩尔亲和力和对激酶以及其他 ATP 酶的高选择性。它对肿瘤细胞系具有很强的增殖抑制活性和良好的药代动力学特性,选择性地保留在肿瘤组织中,并具有穿过血脑屏障的能力。NMS-E973 可引起不同人肿瘤异种移植的肿瘤缩小,并且在对激酶抑制剂耐药的模型中具有高度活性。此外,与其脑穿透一致,NMS-E973 也对颅内植入的黑色素瘤模型有效。
总的来说,NMS-E973 的疗效特征表明,它有可能在不同的临床环境中得到发展,包括对分子靶向药物产生耐药的肿瘤,特别是在位于血脑屏障之外的肿瘤。
