Showing papers by "Yolonda L. Colson published in 1995"

A nonlethal conditioning approach to achieve durable multilineage mixed chimerism and tolerance across major, minor, and hematopoietic histocompatibility barriers.

Abstract: Reconstitution of lethally irradiated mice with a mixture of syngeneic and allogeneic (A+B-->A) bone marrow results in multilineage mixed allogeneic chimerism, donor-specific transplantation tolerance, superior immunocompetence and resistance to graft-vs-host disease However, the morbidity and mortality associated with lethal irradiation would be a major limitation to the clinical application of chimerism to induce tolerance for solid organ grafts or treat other nonmalignant hematologic diseases We report here that durable multilineage mixed allogeneic chimerism and donor-specific transplantation tolerance for skin and primarily vascularized allografts can be achieved across multiple histocompatibility barriers using a nonmyeloablative radiation-based approach The percentage of B10 mouse recipients that engrafted directly correlated with the degree of disparity between donor and recipient and the dose of total body irradiation administered Although the occurrence of engraftment following conditioning with doses of total body irradiation of > or = 600 cGy was similar for animals receiving bone marrow disparate at MHC or MHC, minor and hematopoietic (Hh-1) loci (67% vs 78%), the level of donor chimerism was significantly less when multiple histocompatibility barriers were present (946 +/- 38% vs 375 +/- 125%) Treatment of the recipient with cyclophosphamide 2 days following allogeneic bone marrow transplantation reduced the dose of radiation sufficient for reliable engraftment to only 500 cGy of total body irradiation, regardless of MHC and Hh-1 disparity Donor chimerism was stable and present in all lineages, with production of lymphoid (T and B cell), NK, and myeloid (erythrocyte, platelet, granulocyte, and macrophage) cells Mixed chimeras exhibited donor-specific tolerance in vitro, as assessed by mixed lymphocyte culture (MLR) and cytotoxicity (CML) assays, and in vivo to skin and primarily vascularized cardiac allografts The observation that engraftment and tolerance can be achieved across multiple histocompatibility barriers using nonmyeloablative recipient conditioning may allow allogeneic bone marrow transplantation to be applied to nonmalignant disease states in which lethal conditioning cannot be justified, including the induction of donor-specific tolerance for solid organ transplantation and the treatment of hemoglobinopathies and enzyme deficiency states

Mixed allogeneic chimerism in the rat. Donor-specific transplantation tolerance without chronic rejection for primarily vascularized cardiac allografts.

Abstract: Graft loss secondary to chronic rejection remains a major source of morbidity and mortality in solid organ transplantation. Mixed chimerism has been suggested as one potential approach to overcome this limitation. Until now, whether long-term tolerance for primarily vascularized allografts can be achieved with mixed chimerism has not been adequately assessed due to technical limitations in the mouse and the inability to establish a reliable model of mixed chimerism in the rat. We now report that stable multilineage mixed hematopoietic chimerism can be achieved following the transplantation of a mixture of T cell-depleted syngeneic and allogeneic bone marrow cells into myeloablated rat recipients using a number of MHC plus minor antigen-disparate donor and recipient strain combinations (F344+WF-->F344, F344+ACI-->F344, WF+F344-->WF, and WF+ACI-->WF). Ninety-one percent of animals engrafted with a level of lymphoid chimerism ranging between 12% and 93% (73.3 +/- 4.8%). Peripheral blood lymphocyte chimerism remained stable for up to 13 months after reconstitution. Multilineage chimerism for lymphoid (T and B cells) and myeloid (granulocyte and macrophage) lineages was present, which suggests that engraftment of the pluripotent rat stem cell had occurred. There was no clinical or histologic evidence of graft-versus-host disease. Donor-specific skin (mean survival time [MST] > or = 177 days) and primarily vascularized cardiac (MST > or = 213 days) grafts were accepted without evidence for acute or chronic rejection. In contrast, MHC-disparate third-party skin (MST = 14 days) and cardiac grafts (MST = 13 days) were rapidly rejected. The tolerance was systemic, since donor-specific tolerance was present in vitro as assessed by the mixed lymphocyte proliferation assay. These data suggest that mixed chimerism prevents graft loss secondary to chronic rejection in skin as well as primarily vascularized grafts. Furthermore, a rat model for mixed allogeneic chimerism may provide insight into the mechanisms involved in tolerance induction for a variety of allografts (lungs, small bowel, limb, etc.) not readily transplantable in mouse recipients.

Mixed allogeneic chimerism achieved by lethal and nonlethal conditioning approaches induces donor-specific tolerance to simultaneous islet allografts.

Abstract: We previously reported that donor-specific, but not third party, skin allografts were permanently accepted if mixed allogeneic (B10+BR-->B10) reconstitution and skin graft placement were performed sequentially or simultaneously in lethally conditioned (950 cGy) recipients. The purpose of the present study was to examine whether a similar outcome would occur if islets were placed coincident with the time of bone marrow infusion and to establish the minimum dose of cytoreduction sufficient to achieve chimerism and tolerance for simultaneous islet allografts. B10 (H-2b) mice were rendered diabetic using streptozotocin. After sustained hyperglycemia (> 300 mg/dl), diabetic B10 mice were irradiated (950 cGy) and reconstituted with 5 x 10(6) T cell-depleted (TCD) B10 + 15 x 10(6) TCD B10.BR bone marrow cells. Islet allografts genetically matched or disparate to the bone marrow donor were placed under the renal capsule within 24 hr following infusion of bone marrow cells. All donor-specific B10.BR mouse (H-2k) islet allografts were permanently accepted (n = 8; MST > or = 173 days), while 7 of 9 MHC-disparate third-party BALB/c mouse (H-2d) islet grafts were rejected. The other 2 allografts remained functional over 200 days posttransplantation. We recently established a nonlethal conditioning strategy to achieve multilineage mixed chimerism. We applied this model to examine whether simultaneous islet grafts matched to the donor would be permanently accepted if the donor was incompletely myeloablated. Diabetes was induced in B10 mouse recipients. Animals with hyperglycemia were conditioned with 500 cGy of TBI followed by an infusion of 15 x 10(6) untreated B10.BR bone marrow cells. A simultaneous islet allograft matched or MHC-disparate to the bone marrow donor was performed the same day. Two days following bone marrow transplantation, a single dose of cyclophosphamide (200 mg/kg) was injected via the intraperitoneal route. Islet allografts matched to the bone marrow donor were significantly prolonged (n = 9; MST > or 226 days) and showed no evidence for chronic rejection, while MHC-disparate grafts were rejected (n = 5; MST = 34 days). Animals that received islet grafts but no bone marrow also rejected their grafts with a similar time course. These data suggest that permanent donor-specific tolerance to islet allografts placed coincident with bone marrow transplantation can be achieved after lethal as well as incompletely myeloablative conditioning.