Martin J. White

Inhibition of alloreactivity in vitro by monoclonal antibodies directed against restricted isoforms of the leukocyte-common antigen (CD45).

The leukocyte common antigen (LCA) is a protein tyrosine phosphatase and is identified by the CD45 cluster of monoclonal antibodies. CD45 is expressed in high-density on cells of hematopoietic lineage and generally is immunoprecipitated as 4 bands (220, 205, 190, and 180 KDa). Genetic studies have shown that a single gene produces additional forms of the molecule by alternate splicing including CD45RA (220, 205), CD45RO (180), and CD45RB (220, 205, 100). We have prepared a CD45RB Mab termed “MT3” that binds to a sialic acid dependent epitope. Since the LCA is one of the major targets of antilymphocyte globulin, we assessed a panel of CD45 and CD45R Mab for their ability to inhibit alloreactivity in vitro. MT3 (CD45RB) inhibits the allogeneic MLR and inhibits CD4* T cells from expressing interleukin 2 receptors, and prevents CD4* CD45RA“ T cells from entering the proliferative phase of the cell cycle. Mem 93 (CD45RA) inhibits the generation of cytotoxic T cells. These data suggest that the CD45RB and CD45RA iso-forms of the LCA may be appropriate targets for in vivo immunotherapy.

Prolongation of xenograft survival using monoclonal antibody CD45RB and cyclophosphamide in rat-to-mouse kidney and heart transplant models.

BACKGROUND Intrigued by the finding that a monoclonal antibody (mAb) directed against the B exon of restricted CD45 (CD45RB mAb) induced renal allograft tolerance in the mouse model, we hypothesized that CD45RB mAb may prevent xenograft rejection. We explored the role of CD45RB mAb in preventing xenograft rejection in rat-to-mouse kidney and heart transplant models. METHODS Mice with rat kidney and heart xenografts were treated with a short course of mAb, cyclosporine, cyclophosphamide, or mAb + cyclophosphamide combination therapy. Untreated heart and kidney xenografts served as controls. RESULTS Untreated controls developed acute vascular and cellular rejection rapidly with a median survival time of only 6 days. Long-term kidney (median survival time = 70 days) and heart xenograft survival (median survival time = 65 days) was achieved using the combination therapy of mAb + cyclophosphamide. One-third of the kidney recipients with combination therapy survived 100 days. Immunohistochemistry and xenospecific-antibody analysis demonstrated that combination therapy remarkably reduced IgG and IgM deposition and also inhibited CD4+, CD8+, and Mac-1+ cell infiltration at early stages. This therapy, however, did not induce tolerance in this model as evoked xenoreactive antibodies and cellular responses may be the cause of late xenograft failure. CONCLUSION A short course of CD45RB mAb combined with cyclophosphamide effectively inhibits cellular and humoral immunoresponses and remarkably prolongs xenograft survival in rat-to-mouse heart and kidney transplant models.

Mechanisms of rejection during OKT3 therapy: Propagation and characterization of CD3 resistant allospecific cytotoxic T cells from a rejecting liver allograft☆

Allograft rejection remains the single largest impediment to success in the field of transplantation. While OKT3 therapy has proven to be a significant advancement, many grafts are still lost. Late treatment, subtherapeutic OKT3 levels, anti-OKT3 antibodies, and OKT3-induced class II antigen expression are possible explanations. To determine the mechanism of OKT3 resistant rejection we propagated and characterized infiltrating T cells from the biopsy of a liver transplant patient who was rejecting while on prophylactic OKT3. The T lymphocytes demonstrated allospecific proliferation and interleukin 2 (IL2) production and showed a high degree of cytolysis of donor splenocytes. CD3 epsilon monoclonal antibodies (Mab) in concentrations up to 100 micrograms/ml did not inhibit lysis. In contrast, T lymphocytes derived from rejecting allografts of patients receiving cyclosporine and prednisone were readily inhibited from killing by CD3 epsilon Mab at doses of 1 microgram/ml. Furthermore, allospecific proliferation and IL2 production were not inhibited in the OKT3-treated patient by the addition of CD3 epsilon MaB. Incomplete modulation of the CD3-TCR complex was noted after a 72-hr incubation with CD3 epsilon Mab. The T cells did demonstrate other intact CD3-mediated functions such as a rise in intracellular calcium and CD3-dependent cytotoxicity. These results should alert clinicians that CD3 resistant cytotoxic T cells can emerge during OKT3 therapy and may cause rejection. Immunotherapy that targets additional cell surface structures may be of benefit.