Abstract
Mutation-activated Kras in cancer cells is a well-known challenging treatment-resistant factor that plays a critical role in treatment resistance. Human colorectal cancer (CRC) has four major Kras mutations; KrasG12D (34.2%), KrasG12V (21%), KrasG13D (20%) and KrasG12C (8.4%). Here, we report that while FL118 (a novel inhibitor of survivin, Mcl-1, XIAP, cIAP2 and MdmX) exhibits high efficacy to kill CRC cells and eliminate CRC tumors, CRC cells/tumors with different Kras mutation subtypes in the defined p53/APC genetic statuses exhibit different sensitivity to FL118 treatment. Using CRC cell lines, SW620 (KrasG12V, mutant p53, mutant APC), DLD-1 (KrasG13D, wild type p53, mutant APC) and SNU-C2B (KrasG12D, mutant p53, wild type APC), we demonstrated that silencing of KrasG12V and KrasG12D using Kras-specific shRNA significantly increased CRC cell IC50, while silencing of KrasG13D decreased the CRC cell IC50. This finding suggests that both KrasG12V and KrasG12D are required for showing higher FL118 efficacy, while the presence of KrasG13D could somehow decrease FL118 efficacy under the defined p53/APC genetic status. Consistent with this notion, silencing of KrasG12V in SW620 cells decreased FL118-induced apoptosis, while silencing of KrasG13D in DLD-1 cells increased the FL118-induced apoptosis. Furthermore, forced expression of KrasG12V in SW620 cells increased FL118-induced apoptosis, while forced expression of KrasG13D in DLD-1 cells decreased FL118-induced apoptosis. Additionally, FL118 induced differential reactive oxygen species (ROS) production in SW620, DLD-1 and SNU-C2B cells. Our in vivo studies in animal models further confirmed that SW620 tumors are the most sensitive tumor to FL118 treatment; SNU-C2B tumors are the second most sensitive tumor to FL118 treatment; and the DLD-1 tumors are the least sensitive tumor. These findings would be useful for predicting FL118 sensitivity to patients' CRC tumors with the defined Kras mutation subtypes under the defined p53/APC genetic status.