Linking erythropoietin to Treg-dependent allograft survival through myeloid cells
Julian K. Horwitz, Sofia Bin, Robert L. Fairchild, Karen S. Keslar, Zhengzi Yi, Weijia Zhang, Vasile I. Pavlov, Yansui Li, Joren C. Madsen, Paolo Cravedi, Peter S. Heeger
Julian K. Horwitz, Sofia Bin, Robert L. Fairchild, Karen S. Keslar, Zhengzi Yi, Weijia Zhang, Vasile I. Pavlov, Yansui Li, Joren C. Madsen, Paolo Cravedi, Peter S. Heeger
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Research Article Transplantation

Linking erythropoietin to Treg-dependent allograft survival through myeloid cells

Abstract

Erythropoietin (EPO) has multiple nonerythropoietic functions, including immune modulation, but EPO’s effects in transplantation remain incompletely understood. We tested the mechanisms linking EPO administration to prolongation of murine heterotopic heart transplantation using WT and conditional EPO receptor–knockout (EPOR-knockout) mice as recipients. In WT controls, peritransplant administration of EPO synergized with CTLA4-Ig to prolong allograft survival (P < 0.001), reduce frequencies of donor-reactive effector CD8+ T cells in the spleen (P < 0.001) and in the graft (P < 0.05), and increase frequencies and total numbers of donor-reactive Tregs (P < 0.01 for each) versus CTLA4-Ig alone. Studies performed in conditional EPOR-knockout recipients showed that each of these differences required EPOR expression in myeloid cells but not in T cells. Analysis of mRNA isolated from spleen monocytes showed that EPO/EPOR ligation upregulated macrophage-expressed, antiinflammatory, regulatory, and pro-efferocytosis genes and downregulated selected proinflammatory genes. Taken together, the data support the conclusion that EPO promotes Treg-dependent murine cardiac allograft survival by crucially altering the phenotype and function of macrophages. Coupled with our previous documentation that EPO promotes Treg expansion in humans, the data support the need for testing the addition of EPO to costimulatory blockade-containing immunosuppression regimens in an effort to prolong human transplant survival.

Authors

Julian K. Horwitz, Sofia Bin, Robert L. Fairchild, Karen S. Keslar, Zhengzi Yi, Weijia Zhang, Vasile I. Pavlov, Yansui Li, Joren C. Madsen, Paolo Cravedi, Peter S. Heeger

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Figure 3

EPO ligation of myeloid cell EPOR expression expands peripheral donor-reactive CD4+Foxp3+ T cells.

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EPO ligation of myeloid cell EPOR expression expands peripheral donor-re...
(A and B) Numbers of splenic donor-reactive IFN-γ–producing CD8+ T cells (top) and CD4+Foxp3+ T cells (bottom) by flow cytometry, and calculated ratios of CD8+ IFN-γ–producing CD8+ and CD4+Foxp3+ T cells (Tregs) in each animal (B) on day 14 after transplanting BALB/c hearts into B6 EPORfl/fl, EPORfl/fl LysM-Cre, and EPORfl/fl CD4-Cre recipients (all treated with a single dose of CTLA4-Ig plus EPO as in Figure 1A). (C) Schematic of experimental design. (DF) Representative flow plots showing Foxp3 expression gated on CD4+Vα2+ cells (D), quantified frequencies of splenic CD4+Foxp3+Vα2+ TEa T cells (E), and absolute numbers of splenic CD4+Foxp3+Vα2+ TEa T cells (F) on day 14 after adoptive transfer into EPORfl/fl or EPORfl/fl LysM-Cre recipients of BALB/c heart grafts treated with CTLA4-Ig with or without EPO as indicated. Each symbol represents the mean of n = 2 to 3 replicate assays from each animal. Comparisons performed using 1-way ANOVA corrected for multiple comparisons among paired groups. *P < 0.05; **P < 0.01; ***P < 0.001; NS, not significant. Teff, effector T cell.