Abstract PD6-06: Understanding the complexity of macrophage and mesenchymal stem cell interactions to improve treatment outcome for IBC patients

Abstract Cells within the tumor microenvironment, including but not limited to macrophages and mesenchymal stem cells (MSCs), can promote the phenotype and aggressiveness of inflammatory breast cancer (IBC). For example, co-injection of MSCs with SUM149 IBC cells significantly increased the clinical features of IBC such as skin invasion and metastasis. Our preliminary work showed that MSCs can be educated by co-culture with M1 polarized (anti-tumor) or M2 polarized (pro-tumor) mouse Raw macrophages. Such education of MSCs by M2 Raw macrophages leads to increased IL6 secretion by MSCs, relative to M1-educated or uneducated MSCs. M2-educated MSCs also have increased migration toward IBC cell lines SUM149 and IBC3, effects that can be blocked by an anti-IL6 antibody. Co-culture with M2-educated MSCs also enhances migration and mammosphere formation of IBC cells. Radiation response of IBC cells upon interactions with cells from the tumor microenvironment was also analyzed. Preliminary work shows that co-culture of IBC cells (SUM149 and KPL4) with M2-polarized human THP1 macrophages, prior to ionizing radiation, mediates radiation resistance of IBC cells, and this effect can be decreased by either adding HDL lipoproteins during co-culture period or by STAT6 inhibitors that block IL4/IL13-mediated phosphorylation of STAT6 and M2-polarization in THP1 macrophages. MSCs can also be polarized into either a MSC1 phenotype or a MSC2 phenotype by exposure to toll-like receptor (TLR) ligands TLR4 or TLR3, respectively. Indoleamine-pyrrole 2,3-dioxygenase (IDO) expression in MSCs is a marker of MSC2 polarization that is induced after exposure with TLR3 ligand (PolyIC) relative to MSC1 (TLR4 stimulated; LPS-treated) or parental MSCs. Similar to macrophage polarization, while MSC1 mediates anti-tumor effects, MSC2 are immunosuppressive and thus contribute to tumor growth. Preliminary work also shows that co-culture of IBC cells with MSC2 mediates radioresistance and this can be decreased as well by exposure to HDL during co-culture period prior to radiation. HDL protective effects, in part, can be explained by decreased expression of TLR3-induced IDO mRNA levels in MSC2. In the present work, we extended the above mentioned observations regarding the crosstalk between mouse Raw macrophages and MSCs by analyzing the effect of co-culture of human THP1 macrophages (parental designated as M0, M1- or M2-polarized) with MSCs on the IDO mRNA expression in MSCs, a marker of MSC2 polarization. Surprisingly, co-culture of M1-polarized THP1 with MSCs resulted in a robust increased expression of IDO mRNA in MSC relative to parental MSC (uneducated) or MSCs co-cultured with M2-THP1. Further studies are needed to determine the effects of increased IDO expression in MSC, upon M1-THP1 co-culture, on the aggressive behavior of IBC cells and whether this could be altered with IDO inhibitors. Our results suggest that there could be inter-species differences between mouse and human macrophages on the education of human MSCs. Based on our findings we propose testing a combination of STAT6 inhibitors that reverse M2-polarization of macrophages and IDO inhibitors that can decrease MSC2 phenotype mediated by TLR3 exposure and/or M1-THP1 education. Citation Format: Rahal OM, Wolfe AR, Mandal PK, Larson R, Tin S, Reuben JM, McMurray JS, Woodward WA. Understanding the complexity of macrophage and mesenchymal stem cell interactions to improve treatment outcome for IBC patients [abstract]. In: Proceedings of the 2017 San Antonio Breast Cancer Symposium; 2017 Dec 5-9; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2018;78(4 Suppl):Abstract nr PD6-06.