Background: The HER2 pathway can be inhibited by potent targeting agents such as lapatinib (L), trastuzumab (T), or their combination (LT), but acquired and de novo resistance still occur. Resistance to these drugs remains a major hurdle in the management of HER2+ breast cancer. Consequently, elucidation of mechanisms of acquired therapeutic resistance to HER2-directed therapies is of critical importance.

Methods: To obtain clues to the mechanisms for resistance we developed a panel of HER2+ breast cancer cell lines resistant to L, T, or LT. Parental cells and resistant derivatives of the HER2+ BT474 cell line were characterized by RNA-seq. Genes that were overexpressed in resistant compared to parental cells were confirmed by RT-PCR, Western blotting, and immunohistochemistry (IHC). Cell growth and cell signaling were assessed in parental and resistant cell lines after down-regulation (by siRNA) or overexpression (via an inducible cDNA) of IRS4 in the presence or absence of treatment. The effect of IRS4 overexpression on L resistance was assessed in a BT474 xenograft model. The proteins that interact with IRS4 were identified by co-immunoprecipitation with IRS4 followed by separation of the associated proteins by SDS-PAGE and microsequencing by mass spectrometry.

Results: RNA-seq analysis revealed that IRS4 was the most up-regulated gene in BT474 L or LT resistant derivatives in which HER2 signaling is effectively inhibited, but not T alone, where HER2 signaling is reactivated. Western blotting and IHC validated this result and identified membrane localization of IRS4. Knockdown of IRS4 in L- or LT-resistant cells reversed resistance and restored growth inhibition. IRS4 knockdown also inhibited downstream signaling, with a reduction in pAKT but not in pMAPK. Induction of the cell cycle regulator p27 and down-regulation of survivin were observed after IRS4 knockdown. Overexpression of IRS4 cDNA in parental BT474 and SKBR3 cells led to resistance to L/LT, increased pAkt, and decreased the apoptotic marker cleaved PARP in the presence of L or the LT combination. The BT474 xenograft model showed that IRS4 overexpression in the absence of treatment had no effect on tumor growth but it significantly reduced the inhibitory effect of lapatinib (p=0.002). A group of proteins that interact with IRS4 in BT474 L-resistant cells were identified by mass spectrometry. The roles of these proteins in IRS4-mediated resistance to lapatinb-containing regimens are under investigation.

Conclusion: IRS4 overexpression is a critical factor in causing resistance to lapatinib-containing regimens in BT474 cells. Investigation of IRS4 and its signaling partners in HER2+ human tumors resistant to lapatinib will be important to determine if this mechanism is also operative in patients.

Citation Format: Lanfang Qin, Maria B Hahn, Xiaoyong Fu, Martin J Shea, Mario Giuliano, Sarmistha Nanda, Xiaowei Xu, Huizhong Hu, Sung Yun Jung, Laura M Heiser, Nicholas Wang, Joe W Gray, Susan G Hilsenbeck, Chad Creighton, Chad A Shaw, Gary C Chamness, Dean P Edwards, Sabrina Herrera, Carolina Gutierrez, C Kent Osborne, Rachel Schiff. Overexpression of insulin receptor substrate 4 can mediate acquired resistance to lapatinib-containing regimens in HER2+ breast cancer cells [abstract]. In: Proceedings of the Thirty-Seventh Annual CTRC-AACR San Antonio Breast Cancer Symposium: 2014 Dec 9-13; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2015;75(9 Suppl):Abstract nr P3-05-13.