AbstractCYC116 is a selective Aurora kinase inhibitor that has been tested in a Phase I study in patients with advanced solid tumors. Although CYC116 has shown desirable preclinical efficacy, the potential for emergence of resistance has not been explored. We established several CYC116 resistant clones from isogenic HCT116 p53+/+ and HCT116 p53−/− cell line pairs. We also generated resistant clones towards ZM447439 (quinazoline derivative), a model Aurora inhibitor. The selected clones were 10-80 fold resistant to CYC116 and cross-resistant to other synthetic Aurora inhibitors including AZD1152, VX-680, and MLN8054. Resistant clones displayed multidrug resistant phenotypes, tested by using 13 major cytostatics. All clones were highly resistant to etoposide followed by other drugs. Interestingly, all CYC116 clones but not ZM447439 became polyploid. ZM447439, but not CYC116 induced three novel mutations in Aurora B. Leu152Ser significantly affected ZM447439 binding, but not CYC116. Gene expression studies revealed differential expression of more than 200 genes. Some of these genes expression profiles were also observed in CYC116 resistant primary tumors. Bcl-xL (BCL2L1) was found to be overexpressed in CYC116 clones and its knockdown resensitized the p53+/+ resistant clone to CYC116. Finally Bcl-xL overexpressing p53+/+ CYC116 clones were highly sensitive to navitoclax (ABT-263) compared to parent cells. The data shed light on the genetic basis for resistance to Aurora kinase inhibitors which could be used to predict clinical response, to select patients who might benefit from therapy and to suggest suitable drug combinations for a particular patient population.
Identification and characterization of drug resistance mechanisms in cancer cells against Aurora kinase inhibitors CYC116 and ZM447439
