G-CSF-Induced Suppressor IL-10+ Neutrophils Promote Regulatory T Cells That Inhibit Graft-Versus-Host Disease in a Long-Lasting and Specific Way.

Acute graft-versus-host disease (aGVHD) is the main complication of allogeneic hematopoietic stem cell transplantation, and many efforts have been made to overcome this important limitation. We showed previously that G-CSF treatment generates low-density splenic granulocytes that inhibit experimental aGVHD. In this article, we show that aGVHD protection relies on incoming IL-10+ neutrophils from G-CSF-treated donor spleen (G-Neutrophils). These G-Neutrophils have high phagocytic capacity, high peroxide production, low myeloperoxidase activity, and low cytoplasmic granule content, which accounts for their low density. Furthermore, they have low expression of MHC class II, costimulatory molecules, and low arginase1 expression. Also, they have low IFN-γ, IL-17F, IL-2, and IL-12 levels, with increased IL-10 production and NO synthase 2 expression. These features are in accordance with the modulatory capacity of G-Neutrophils on regulatory T cell (Treg) generation. In vivo, CD25+ Treg depletion shortly after transplantation with splenic cells from G-CSF-treated donors blocks suppression of aGVHD, suggesting Treg involvement in the protection induced by the G-Neutrophils. The immunocompetence and specificity of the semiallogeneic T cells, long-term after the bone marrow transplant using G-Neutrophils, were confirmed by third-party skin graft rejection; importantly, a graft-versus-leukemia assay showed that T cell activity was maintained, and all of the leukemic cells were eliminated. We conclude that G-CSF treatment generates a population of activated and suppressive G-Neutrophils that reduces aGVHD in an IL-10- and Treg-dependent manner, while maintaining immunocompetence and the graft versus leukemia effect.

Mature Naive B Cells Regulate the Outcome of Murine Acute Graft-versus-Host Disease in an IL-10-Independent Manner.

Graft-versus-host disease (GVHD) is the main complication of bone marrow transplantation (BMT). CD4+ T lymphocytes are the main effector cells for disease development, but other cell types can determine disease outcome through cytokine production and antigen presentation. B cells are abundant in BMT products and are involved in chronic GVHD immunopathogenesis. However, their role in acute GVHD is still unclear. Here we studied the role of donor resting B cells in a model of acute GVHD. Animals receiving transplants depleted of B cells developed more severe disease, indicating a protective role for B cells. Mice undergoing transplantation with IL-10 knockout B cells developed GVHD as severe as those receiving wild-type B cells. Moreover, mice that received MHC II-deficient B cells, and thus were unable to present antigen to CD4+ T cells, developed as severe GVHD as animals receiving transplants without B cells. This result suggests that the protection provided by mature naive B cells depends on antigen presentation and not on IL-10 production by B cells. Mice who underwent transplantation in the absence of donor B cells exhibited disorganized lymphoid splenic tissue. In addition, donor B cell depletion diminished the follicular T (Tfh)/effector T (Teff) cell ratio, suggesting that protection was correlated with a shift to Tfh differentiation, reducing the number of Teff cells. Importantly, the Tfh/Teff shift impacts disease outcome, with observed proinflammatory cytokine levels and tissue damage in target organs consistent with disease protection. The role of transplanted B cells in the outcome of BMT and the development of acute GVHD merits careful study, given that these cells are abundant in BMT products and are potent modulator and effector cells in the allogeneic response.