Browsing by Author "Taylor, Brandie C."

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    Epithelial Expressed B7-H4 Drives Differential Immunotherapy Response in Murine and Human Breast Cancer
    (American Association for Cancer Research, 2024) Wescott, Elizabeth C.; Sun, Xiaopeng; Gonzalez-Ericsson, Paula; Hanna, Ann; Taylor, Brandie C.; Sanchez, Violeta; Bronzini, Juliana; Opalenik, Susan R.; Sanders, Melinda E.; Wulfkuhle, Julia; Gallagher, Rosa I.; Gomez, Henry; Isaacs, Claudine; Bharti, Vijaya; Wilson, John T.; Ballinger, Tarah J.; Santa-Maria, Cesar A.; Shah, Payal D.; Dees, Elizabeth C.; Lehmann, Brian D.; Abramson, Vandana G.; Hirst, Gillian L.; Brown Swigart, Lamorna; van ˈt Veer, Laura J.; Esserman, Laura J.; Petricoin, Emanuel F.; Pietenpol, Jennifer A.; Balko, Justin M.; Medicine, School of Medicine
    Combinations of immune checkpoint inhibitors (ICI, including anti-PD-1/PD-L1) and chemotherapy have been FDA approved for metastatic and early-stage triple-negative breast cancer (TNBC), but most patients do not benefit. B7-H4 is a B7 family ligand with proposed immunosuppressive functions being explored as a cancer immunotherapy target and may be associated with anti-PD-L1 resistance. However, little is known about its regulation and effect on immune cell function in breast cancers. We assessed murine and human breast cancer cells to identify regulation mechanisms of B7-H4 in vitro. We used an immunocompetent anti-PD-L1-sensitive orthotopic mammary cancer model and induced ectopic expression of B7-H4. We assessed therapy response and transcriptional changes at baseline and under treatment with anti-PD-L1. We observed B7-H4 was highly associated with epithelial cell status and transcription factors and found to be regulated by PI3K activity. EMT6 tumors with cell-surface B7-H4 expression were more resistant to immunotherapy. In addition, tumor-infiltrating immune cells had reduced immune activation signaling based on transcriptomic analysis. Paradoxically, in human breast cancer, B7-H4 expression was associated with survival benefit for patients with metastatic TNBC treated with carboplatin plus anti-PD-L1 and was associated with no change in response or survival for patients with early breast cancer receiving chemotherapy plus anti-PD-1. While B7-H4 induces tumor resistance to anti-PD-L1 in murine models, there are alternative mechanisms of signaling and function in human cancers. In addition, the strong correlation of B7-H4 to epithelial cell markers suggests a potential regulatory mechanism of B7-H4 independent of PD-L1. Significance: This translational study confirms the association of B7-H4 expression with a cold immune microenvironment in breast cancer and offers preclinical studies demonstrating a potential role for B7-H4 in suppressing response to checkpoint therapy. However, analysis of two clinical trials with checkpoint inhibitors in the early and metastatic settings argue against B7-H4 as being a mechanism of clinical resistance to checkpoints, with clear implications for its candidacy as a therapeutic target.
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    NKG2A Is a Therapeutic Vulnerability in Immunotherapy Resistant MHC-I Heterogeneous Triple-Negative Breast Cancer
    (American Association for Cancer Research, 2024) Taylor, Brandie C.; Sun, Xiaopeng; Gonzalez-Ericsson, Paula I.; Sanchez, Violeta; Sanders, Melinda E.; Wescott, Elizabeth C.; Opalenik, Susan R.; Hanna, Ann; Chou, Shu-Ting; Van Kaer, Luc; Gomez, Henry; Isaacs, Claudine; Ballinger, Tarah J.; Santa-Maria, Cesar A.; Shah, Payal D.; Dees, Elizabeth C.; Lehmann, Brian D.; Abramson, Vandana G.; Pietenpol, Jennifer A.; Balko, Justin M.; Medicine, School of Medicine
    Despite the success of immune checkpoint inhibition (ICI) in treating cancer, patients with triple-negative breast cancer (TNBC) often develop resistance to therapy, and the underlying mechanisms are unclear. MHC-I expression is essential for antigen presentation and T-cell-directed immunotherapy responses. This study demonstrates that TNBC patients display intratumor heterogeneity in regional MHC-I expression. In murine models, loss of MHC-I negates antitumor immunity and ICI response, whereas intratumor MHC-I heterogeneity leads to increased infiltration of natural killer (NK) cells in an IFNγ-dependent manner. Using spatial technologies, MHC-I heterogeneity is associated with clinical resistance to anti-programmed death (PD) L1 therapy and increased NK:T-cell ratios in human breast tumors. MHC-I heterogeneous tumors require NKG2A to suppress NK-cell function. Combining anti-NKG2A and anti-PD-L1 therapies restores complete response in heterogeneous MHC-I murine models, dependent on the presence of activated, tumor-infiltrating NK and CD8+ T cells. These results suggest that similar strategies may enhance patient benefit in clinical trials. Significance: Clinical resistance to immunotherapy is common in breast cancer, and many patients will likely require combination therapy to maximize immunotherapeutic benefit. This study demonstrates that heterogeneous MHC-I expression drives resistance to anti-PD-L1 therapy and exposes NKG2A on NK cells as a target to overcome resistance.