Inhibition of MCL-1 and MEK overcomes MEK inhibitor resistance in triple-negative and inflammatory breast cancers.

The MAPK pathway can drive resistance in highly aggressive breast cancers. Our previous work showed that MEK inhibitor (MEKi) AZD6244 (selumetinib) prevented lung metastasis in a breast cancer xenograft model. In clinical studies, MEKis as single agents have had only modest activity against solid tumors due to the onset of resistance. Using synthetic-lethality siRNA screening, we identified myeloid cell leukemia-1 (MCL-1) as a potential contributor to AZD6244 resistance. We hypothesized that MCL-1 promotes MEKi resistance in highly aggressive breast cancers and that MCL-1 inhibition overcomes AZD6244 resistance. We established two AZD6244-resistant cell lines: MDA-MB-231-R (triple-negative breast cancer) and SUM149-R (triple-negative inflammatory breast cancer). These resistant cells were characterized with respect to different parameters, and a combination of an MCL-1 inhibitor (MCL-1i) together with a MEKi was evaluated in vitro and in vivo to overcome the acquired resistance. Compared with their respective parental cells, MDA-MB-231-R and SUM149-R cells showed increased proliferation, colony formation, stemness, anchorage-independent growth, and MCL-1 expression levels. MCL-1 knockdown in resistant cells decreased cell proliferation and colony formation, increased apoptosis, and was associated with high expression of the pro-apoptotic proteins PUMA, NOXA, BAK, and BAX. MEKi resistance was overcome when resistant cells were treated with MCL-1i and MEKi combined. In an in vivo mouse model, inhibition of MCL-1 restored sensitivity to AZD6244. Our results suggest that MCL-1 is a driver of MEKi resistance and that combining an MCL-1i with a MEKi warrants further investigation in triple-negative and triple-negative inflammatory breast cancer.