MEK activation modulates glycolysis and supports suppressive myeloid cells in TNBC
Derek A. Franklin, Joe T. Sharick, Paula I. Ericsson-Gonzalez, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Stefano Cairo, Jean-Gabriel Judde, Michael T. Lewis, Jenny C. Chang, Melinda E. Sanders, Rebecca S. Cook, Melissa C. Skala, Jennifer Bordeaux, Jehovana Orozco Bender, Christine Vaupel, Gary Geiss, Douglas Hinerfeld, Justin M. Balko
Derek A. Franklin, Joe T. Sharick, Paula I. Ericsson-Gonzalez, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Stefano Cairo, Jean-Gabriel Judde, Michael T. Lewis, Jenny C. Chang, Melinda E. Sanders, Rebecca S. Cook, Melissa C. Skala, Jennifer Bordeaux, Jehovana Orozco Bender, Christine Vaupel, Gary Geiss, Douglas Hinerfeld, Justin M. Balko
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Research Article Immunology Oncology

MEK activation modulates glycolysis and supports suppressive myeloid cells in TNBC

Abstract

Triple-negative breast cancers (TNBCs) are heterogeneous and aggressive, with high mortality rates. TNBCs frequently respond to chemotherapy, yet many patients develop chemoresistance. The molecular basis and roles for tumor cell–stromal crosstalk in establishing chemoresistance are complex and largely unclear. Here we report molecular studies of paired TNBC patient–derived xenografts (PDXs) established before and after the development of chemoresistance. Interestingly, the chemoresistant model acquired a distinct KRASQ61R mutation that activates K-Ras. The chemoresistant KRAS-mutant model showed gene expression and proteomic changes indicative of altered tumor cell metabolism. Specifically, KRAS-mutant PDXs exhibited increased redox ratios and decreased activation of AMPK, a protein involved in responding to metabolic homeostasis. Additionally, the chemoresistant model exhibited increased immunosuppression, including expression of CXCL1 and CXCL2, cytokines responsible for recruiting immunosuppressive leukocytes to tumors. Notably, chemoresistant KRAS-mutant tumors harbored increased numbers of granulocytic myeloid-derived suppressor cells (gMDSCs). Interestingly, previously established Ras/MAPK-associated gene expression signatures correlated with myeloid/neutrophil-recruiting CXCL1/2 expression and negatively with T cell–recruiting chemokines (CXCL9/10/11) across patients with TNBC, even in the absence of KRAS mutations. MEK inhibition induced tumor suppression in mice while reversing metabolic and immunosuppressive phenotypes, including chemokine production and gMDSC tumor recruitment in the chemoresistant KRAS-mutant tumors. These results suggest that Ras/MAPK pathway inhibitors may be effective in some breast cancer patients to reverse Ras/MAPK-driven tumor metabolism and immunosuppression, particularly in the setting of chemoresistance.

Authors

Derek A. Franklin, Joe T. Sharick, Paula I. Ericsson-Gonzalez, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Stefano Cairo, Jean-Gabriel Judde, Michael T. Lewis, Jenny C. Chang, Melinda E. Sanders, Rebecca S. Cook, Melissa C. Skala, Jennifer Bordeaux, Jehovana Orozco Bender, Christine Vaupel, Gary Geiss, Douglas Hinerfeld, Justin M. Balko

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Figure 4

Myeloid recruitment to TNBC is mediated by Ras/MEK-dependent CXCL1/2 expression.

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Myeloid recruitment to TNBC is mediated by Ras/MEK-dependent CXCL1/2 exp...
(A) Quantification of Gr1+ myeloid cells in the tumor microenvironment in BCM-2147 (KRASWT) and BCM-2277 (KRASQ61R) tumors after treatment with AC/docetaxel + vehicle (VEHI) or AC/docetaxel + trametinib (MEKi). (n = 8–10.) Identified P values represent Tukey’s post hoc comparisons following 1-way ANOVA (P < 0.0001). (B) Representative images of Gr1+ cells from BCM-2277 VEHI- and MEKi-treated tumors (Scale bar: 50 μm). (C) Quantification of Arg1+ myeloid cells in the tumor microenvironment in BCM-2147 (KRASWT) and BCM-2277 (KRASQ61R) tumors after treatment with AC/docetaxel + vehicle (VEHI) or AC/docetaxel + trametinib (MEKi). (n = 8–10.) One-way ANOVA was nonsignificant. P value represents a 2-sample, 1-tailed t test between the MEKi and control arms of the KRASQ61R model. (D) Representative images of Arg1+ cells from BCM-2277 VEHI- and MEKi-treated tumors. (Scale bar: 50 μm.) (E) Flow cytometry analysis of Ly6C/Ly6G expression in untreated BCM-2277 (KRASQ61R) tumors, gated on DAPICD45+CD11b+. mMDSC, monocytic MDSC. (F) Relative percentages of 3 populations of myeloid cells as defined in E among 3 tumors. (G) Mean fluorescence intensity of PD-L1 and MHC-II (IA-IE) in the 3 myeloid populations in E. (H) T cell proliferation after 72 hours of coculture with Gr1+ cells and CD3/CD28 bead stimulation measured by CellTrace Far Red fluorescence. (I) Distribution of T cell proliferation in 72-hour cocultures with Gr1+ cells across 3 independent experiments. (JM) RNA isolated from tumor dissociates, Gr1+ cells, and Gr1-depleted dissociates was probed for Arg1, INOS, NOX2, and S100A8 by qRTPCR (n = 3).