Abstract 4757: Targeting the mevalonate pathway in HER2+breast cancer to overcome resistance and enhance anti-HER2 therapy efficacy

Background: Despite the advent of HER2-targeted therapies, including the monoclonal antibody trastuzumab (T) and the HER1/2 inhibitor lapatinib (L), for HER2+ breast cancer (BC), resistance still poses a major challenge. L and L+T resistant (R) HER2+ cells with inhibited HER2 signaling showed upregulation of RNA levels of the mevalonate pathway (MVA) enzymes (which were inhibited by short term treatment of parental (P) cells with L or L+T) and increased sensitivity to MVA inhibition by statins (e.g. simvastatin (Sim)), suggesting MVA’s role as an escape mechanism of resistance. Here we investigated the therapeutic potential of another MVA inhibitor Zoledronate (ZA) and the role of mTOR and YAP/TAZ (Y/T) in mediating this resistance. Lastly, we tested if co-blockade of the MVA or its downstream effectors further sensitizes HER2+ models to anti-HER2 therapies. Methods: SKBR3 and AU565 P cells and their LR and LTR derivatives were used. The effects of MVA perturbations on cell growth and HER2 or MVA signaling were studied by methylene blue staining and Western blot (WB), respectively. Y/T activity was tested by a luciferase reporter assay and functionally validated by siRNA knockdown and dominant-active (DomA) YAP overexpression. YAP target gene expression was assessed by RT PCR. SCID-Beige mice bearing HER2+ BCM-3963 PDX tumors were treated with vehicle, L, Sim, or L+Sim and monitored for time to complete response (CR). Results: ZA, like Sim, showed a selective inhibition of cell growth and mTOR signaling in R vs. P cells, which was rescued only by the downstream metabolite geranyl geranyl pyrophosphate (GGPP), but not by the upstream metabolite mevalonate, indicating the on-target effect of ZA. Increased Y/T activity in R models was confirmed, and both Sim and ZA inhibited TAZ levels and induced phospho-YAP levels, which were rescued by the corresponding downstream metabolites. Y/T knockdown inhibited growth and mTOR signaling in R vs. P cells, and DomA YAP negated the mTOR inhibition by Sim. Sim and ZA also significantly decreased levels of the Y/T target gene survivin in R vs. P cells, and the expression was rescued by the downstream metabolites. Inhibition of MVA by Sim or ZA or its downstream signaling effectors, Y/T (by siRNA) and mTOR (by everolimus), enhanced the L sensitivity in P cells. Conversely, DomA YAP reduced the sensitivity of P cells to L. In the presence of Sim or ZA, L treatment more strongly inhibited levels of phospho-S6, a downstream target of mTORC1, compared to L alone. Preliminary in vivo data showed that treatment with L+Sim vs. L alone shortened the median time to CR and numerically increased CR rates. Conclusions: The MVA pathway mediates anti-HER2 therapy resistance via Y/T, survivin, and mTOR, in some cell models and this resistance can be overcome by Sim and ZA. The potential of MVA pathway inhibition to enhance anti-HER2 therapy efficacy warrants further clinical studies. Citation Format: Vidyalakshmi Sethunath, Huizhong Hu, Carmine DeAngelis, Jamunarani Veeraraghavan, Lanfang Qin, Martin Shea, Tamika Mitchell, Sarmistha Nanda, Resel Pereira, Susan G. Hilsenbeck, Mothaffar F. Rimawi, Kent C. Osborne, Rachel Schiff. Targeting the mevalonate pathway in HER2+breast cancer to overcome resistance and enhance anti-HER2 therapy efficacy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 4757.