A Novel Eg5 Inhibitor (LY2523355) Causes Mitotic Arrest and Apoptosis in Cancer Cells and Shows Potent Antitumor Activity in Xenograft Tumor Models.

Xiang S Ye,Kelly M Credille,Eric H Westin,Heng Li,Shiro Akinaga,Gregory P Donoho,Robert D Van Horn,Amit Aggarwal,Tinggui Yin,Yoshihisa Ohta,Li Fan,Farhana F Merzoug,Kerry Blanchard,Ryuichiro Nakai,Yoshinori Yamashita,Chikara Murakata

doi:10.1158/1535-7163.mct-15-0241

Xiang S Ye, Kelly M Credille + Show 14 more

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https://doi.org/10.1158/1535-7163.mct-15-0241

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Abstract

Intervention of cancer cell mitosis by antitubulin drugs is among the most effective cancer chemotherapies. However, antitubulin drugs have dose-limiting side effects due to important functions of microtubules in resting normal cells and are often rendered ineffective by rapid emergence of resistance. Antimitotic agents with different mechanisms of action and improved safety profiles are needed as new treatment options. Mitosis-specific kinesin Eg5 represents an attractive anticancer target for discovering such new antimitotic agents, because Eg5 is essential only in mitotic progression and has no roles in resting, nondividing cells. Here, we show that a novel selective Eg5 inhibitor, LY2523355, has broad target-mediated anticancer activity in vitro and in vivo. LY2523355 arrests cancer cells at mitosis and causes rapid cell death that requires sustained spindle-assembly checkpoint (SAC) activation with a required threshold concentration. In vivo efficacy of LY2523355 is highly dose/schedule-dependent, achieving complete remission in a number of xenograft tumor models, including patient-derived xenograft (PDX) tumor models. We further establish that histone-H3 phosphorylation of tumor and proliferating skin cells is a promising pharmacodynamic biomarker for in vivo anticancer activity of LY2523355.

Highlights

During G2–M progression, duplicated centrosomes are separated by the microtubule-based bipolar mitotic spindle through a complex process involving chromosomes, mitotic kinases, and microtubule-associated proteins [1,2,3]
LY2523355 showed potent, broad-spectrum anticancer activity in vitro at low concentrations (IC50 values ranging from 0.4 nmol/L to14 nmol/L) when tested against a panel of 21 cancer cell lines, which was further confirmed in proliferation assays with the NCI-60 panel (Supplementary Tables S1 and S2)
We showed that increase in histone-H3 phosphorylation of proliferating skin cells is quantitatively correlated with anticancer activity of LY2523355, offering a promising surrogate pharmacodynamic biomarker for the evaluation of LY2523355 anticancer activity

Summary

Introduction

During G2–M progression, duplicated centrosomes are separated by the microtubule-based bipolar mitotic spindle through a complex process involving chromosomes, mitotic kinases, and microtubule-associated proteins [1,2,3]. The bipolar mitotic spindle orchestrates the segregation of replicated chromosomes accurately and into two daughter cells to maintain genome stability during cell division. Antimitotic drugs such as antitubulins, including taxanes and vincas, are among the most effective cancer therapies in current clinical use [4]. These antitubulins have severe side effects as they disrupt the normal microtubule functions in resting cells, including neurons, which may lead to neuropathic disorders [5,6,7].

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