Dasatinib Reversibly Disrupts Endothelial Vascular Integrity by Increasing Non-Muscle Myosin II Contractility in a ROCK-Dependent Manner.

Purpose: Dasatinib is a short-acting dual ABL/SRC family tyrosine kinase inhibitor (TKI), which is frequently used to treat chronic myeloid leukemia. Although very effective, patients taking dasatinib often display severe adverse effects, including pleural effusions and increased risk of bleeding primarily in the gastrointestinal tract. The actual causes of these side effects are currently undetermined. We hypothesize that endothelial cells (ECs) that line the inner walls of blood vessels and control the traffic to the underlying tissues might be involved.Experimental Design: The effects of TKIs on ECs were studied by various assays, such as real-time cell impedance measurements, live-cell microscopy, wound healing, Western blot, and an in vivo model.Results: Dasatinib uniquely causes a profound, dose-dependent disorganization of the EC monolayers. Dasatinib promoted the disassembly of cell-cell contacts, altered cell-matrix contacts, and further altered the wound healing. A key observation is that this effect is fully reversible after drug washout. In line with these in vitro observations, intraperitoneal administration of dasatinib to mice caused significant vascular leakage in the intestine. The underlying molecular mechanism of dasatinib-induced reorganization of the actin involves ROCK activation, which increases the amount of the phosphorylation of myosin light chain and consequently activates the non-muscle myosin II.Conclusions: Our data are consistent with a scenario in which dasatinib triggers a transient increase in vascular leakage that probably contributes to adverse effects such as bleeding diathesis and pleural effusions. Clin Cancer Res; 23(21); 6697-707. ©2017 AACR.

Development of high-throughput screens for discovery of kinesin adenosine triphosphatase modulators.

Kinesins are a group of related molecular motor proteins that have great potential as targets for antimitotic drug development. We have developed two novel assays, one end-point and one kinetic, that are useful for the discovery and optimization of kinesin modulators. Both assays measure inorganic phosphate (Pi) generated by microtubule-activated kinesin adenosine triphosphatase activity. The assays were validated using the mitotic Eg5 kinesin-specific inhibitor, monastrol. A panel of nine kinesin motor domain proteins, representing 8 of the 14 classes of kinesins, was screened. The coefficient of variation for both assays was determined to be 4-14% depending on the panel member. Using the Eg5 kinetic assay with monastrol the IC50 value was 12 microM, which agrees well with previously published results. Two other closely related mitotic kinesins (AnBimC and MKLP1) were found to have IC50 values in the millimolar range. The other panel members (kinesin heavy chain, chromokinesin KIF4A, KIF3C, CENP-E, MCAK, and KIFC3) were not significantly inhibited by millimolar levels of monastrol. It is anticipated that screening of the nine-member panel of kinesins in these assays will serve as a platform for the discovery and development of specific kinesin modulators.