Preformed antibody, not primed T cells, is the initial and major barrier to bone marrow engraftment in allosensitized recipients.

Multiply-transfused individuals are at higher risk for BM rejection. We show that whereas allosensitization resulted in the priming of both cellular and humoral immunity, preformed antibody was the major barrier to engraftment. The generation of cross-reactive alloantibody led to rejection of BM of a different MHC-disparate strain. Imaging studies indicated that antibody-mediated rejection was very rapid (<3 hours) in primed recipients, while T-cell-mediated rejection in nonprimed mice took more than 6 days. Antibody-mediated BM rejection was not due to a defect in BM homing as rejection occurred despite direct intra-BM infusion of donor BM. Rejection was dependent upon host FcR+ cells. BM cells incubated with serum from primed mice were eliminated in nonprimed recipients, indicating that persistent exposure to high-titer antibody was not essential for rejection. High donor engraftment was achieved in a proportion of primed mice by mega-BM cell dose, in vivo T-cell depletion, and high-dose immunoglobulin infusion. The addition of splenectomy to this protocol only modestly added to the efficacy of this combination strategy. These data demonstrate both rapid alloantibody-mediated elimination of BM by host FcR+ cells and priming of host antidonor T cells and suggest a practical strategy to overcome engraftment barriers in primed individuals.

L-Selectin(hi) but not the L-selectin(lo) CD4+25+ T-regulatory cells are potent inhibitors of GVHD and BM graft rejection.

Graft-versus-host disease (GVHD) is a major cause of morbidity and mortality after bone marrow transplantation (BMT). CD4(+)CD25(+) immune regulatory T cells (Tregs), long recognized for their critical role in induction and maintenance of self-tolerance and prevention of autoimmunity, are also important in the regulation of immune responses in allogeneic bone marrow (BM) and solid organ transplantation. Published data indicate that ex vivo activated and expanded donor Tregs result in significant inhibition of lethal GVHD. This study provides a direct comparison of LSel(hi) and LSel(lo) Tregs for GVHD inhibition and for the promotion of allogeneic BM engraftment. Imaging of green fluorescent protein-positive effectors in GVHD control mice and LSel(hi) and LSel(lo) Treg-treated mice vividly illustrate the multisystemic nature of GVHD and the profound inhibition of GVHD by LSel(hi) Tregs. Data indicate that LSel(hi) Tregs interfere with the activation and expansion of GVHD effector T cells in secondary lymphoid organs early after BMT. Either donor- or host-type LSel(hi), but not LSel(lo), Tregs potently increased donor BM engraftment in sublethally irradiated mice, an event occurring independently of transforming growth factor beta signaling of host T cells. These data indicate that Treg cellular therapy warrants clinical consideration for the inhibition of GVHD and the promotion of alloengraftment.