Donor DNA can be detected in recipient tissues during rejection of allograft.

The main source of donor DNA in recipients of allograft are "passenger" cells. It is claimed that they are responsible for the posttransplantation microchimerism and prolongation of allograft survival. We have observed that besides cellular microchimerism, donor DNA can be found in the recipient tissues at the time of rejection of the allograft. In this study, we provide evidence for the presence in the recipient of both DNA in "passenger cells" and free DNA in tissues at the terminal stage of rejection. Male BN (RT1 n) rat heart or skin was transplanted to female LEW (RT1 l) rats followed by a vascularized bone marrow in a hindlimb transplant. In another group, heart and skin were transplanted followed by immediate i.v. infusion of donor-type bone marrow cells. CsA was given in a dose of 17 mg/kg body weight for 30 days, then the rats were followed up until day 100 unless rejection occurred earlier. LEW blood, spleen, mesenteric node and bone marrow cells were stained with moAb OX27 specific for BN but not LEW. Genomic male DNA was isolated and amplified with SRY oligonucleotide. At day 30 and day 100 cellular microchimerism was detected in blood, spleen, nodes and bone marrow cells. Donor DNA was detected in recipient skin, liver and heart extracts, as well as lymphoid organs, at the time of rejection of allograft, but not when the rats were maintained on CsA. Taken together, donor DNAwas detected in recipient tissues at the time of heart or skin rejection. It appeared to be released from cells of rejecting grafts and not from "passenger" cells, representing only a minor cellular mass compared with the graft.

Vascularized bone marrow transplanted in orthotopic hind-limb stimulates hematopoietic recovery in total-body-irradiated rats.

Hematopoietic recovery after bone marrow transplantation (BMT) is reported to be slow with long-lasting immune deficiency. This may be attributable to lack of a proper microenvironment for hematopoietic cell proliferation and differentiation. We have designed a model in which complete hematopoietic reconstitution of lethally irradiated rats can be achieved by vascularized bone marrow transplantation (VBMT) in an orthotopic hind-limb graft. The aim of the study was to investigate the process of repopulation of bone marrow cavities and peripheral blood of irradiated rats after VBMT and, in particular, to follow the contribution of grafted BM cells and residual recipient BM cells in hematopoietic regeneration. Lewis hind-limbs were transplanted orthotopically to totally irradiated (8 Gy) syngeneic sex-mismatched recipients (VBMT). In the control group 8 x 10(7) BM cells in suspension were injected intravenously (BMCT). After 10 days BM and peripheral blood (PB) cells were collected from the recipient. For cell subset analysis cytomorphological evaluation of BM smears and flow cytometry of PB cells were performed. Additionally, PCR was performed using specific primers for rat Y chromosome (sex-determining region Y-Sry) to detect male (donor or recipient) cells in sex-mismatched BM graft recipients and the products were analyzed by electrophoresis. VBMT brought about much faster replenishment of nucleated cells in BM and PB than did BMCT. Cytometry analysis of PB cells revealed more lymphocytes in VBMT than in BMCT recipients. The amount of donor DNA of bands corresponding to Y-Sry was also higher in PB cells of VBMT than of BMCT recipients. The presence of host DNA was observed in PB cells of VBMT rats but was not detected in PB population of BMCT recipients. VBMT is highly effective in hematopoietic reconstitution of irradiated recipients. The fast cell maturation and repopulation may be due to the presence of stromal cells transplanted in a normal spatial relationship with donor hematopoietic cells in hind-limb graft. Self renewal of radioresistant host cells was seen after VBMT but not after BMCT.

Kinetics of bone marrow repopulation in lethally irradiated rats after transplantation of vascularized bone marrow in syngeneic hind limb.

Grafting of the recipient with bone marrow cell suspension provides only few stromal cells and no autologous environment for cooperation between hemopoietic and stromal cells. Vascularized bone marrow grafts provide the recipient with bone marrow hemopoietic and stromal cells in their natural spatial relationship. It is expected that such a graft will resume its function soon after transplantation and almost immediately repopulate bone marrow cavities of the irradiated recipient as well as supply the sites of cytopoiesis with the necessary growth factors. The aim of the study was to investigate the process of repopulation of bone marrow cavities and lymphoid organs of irradiated recipient by bone marrow cells from syngeneic hind limb transplant. Lewis rats received total body irradiation of 8 Gy followed by orthotopic transplantation of syngeneic limb or i.v. infusion of equivalent amount of bone marrow cells. In control experiments the hind limb was shielded with lead plate during total body irradiation. Ten days after irradiation and hind limb transplantation the yield of nucleated cells from tibia was reaching values of normal animals. In rats receiving i.v. bone marrow cell infusion it was 40% of control values and in rats repopulated from shielded own hind limb it was 60% of controls. In all groups a higher percentage of early and immediate normoblasts and a reduced pool of juvenile and segmented neutrophils was observed. Thirty days after irradiation and repopulation procedures all parameters were returning to normal levels in each group. The results indicate that bone marrow cell transplantation in hind limb graft is highly effective in lethally irradiated animals in reconstituting bone marrow.

Fast lymphoid reconstitution after vascularized bone marrow transplantation in lethally irradiated rats.

BACKGROUND: Bone marrow (BM) transplantation for treatment of hematological and solid malignancies is routinely carried out in conjunction with radio- and chemotherapy. Many patients achieve complete remission of the malignant process; however, their lymphohematopoietic recovery remains in most cases incomplete. This is probably due to the functional changes in the recipient BM stromal cells subsequent to myeloablative therapy. Transplantation of BM hematopoietic cells in a spatial relationship with stromal cells would give an insight into the kinetics of hematological repopulation of the recipient. The aim of this study was to investigate the lymphopoietic reconstitution of irradiated rats after vascularized bone marrow transplantation (VBMT) in comparison with i.v. bone marrow cell (BMC) infusion. METHODS: Lewis rats were totally irradiated with 8Gy and repopulated with syngeneic BMC introduced i.v. or in orthotopic hind limb graft. Ten days after irradiation and BMC graft BM, peripheral blood (PB) and mesenteric lymph nodes (MLN) were collected. The yield and the phenotype of cells were analyzed. RESULTS: VBMT brings much higher cell repopulation of BM cavities of lethally irradiated rats than BMC infusion. Orthotopic hind limb graft promotes also rapid lymphocyte replenishment of PB and MLN of lethally irradiated syngeneic recipients. The population rate of BMC, PB lymphocytes, and MLN lymphocytes was higher after VBMT than BMC injection in suspension. The percentage of T and B lymphocytes in PB and MLN on day 10 after VBMT was comparable with control values. Reconstituted PB lymphocytes showed two subsets of CD4+ cells: "bright" and "dull." All CD4+ cells in PB lymphocytes of i.v. BMC infused recipients expressed low level of these molecules ("dull" subset). CONCLUSIONS: The results of our studies indicate that the presence of stromal cells in their close relationship with stem cells is essential for the fast lyphohematopoietic repopulation of irradiated recipients. The population of CD4+dull cells may represent immature cells. These cells were not found in MLN of VBMT rats. All MLN CD4+ cells represented the "bright" subset, what suggests that the process of cell maturation may occur in the lymphoid organs.

DNA from rejecting allografts can be detected in recipient nonlymphoid tissues.

The main source of donor DNA in recipients of allograft are "passenger" cells. They are claimed to be responsible for the posttransplantation microchimerism and prolongation of allograft survival. We have noticed that beside of the cellular microchimerism, donor DNA can be found in the recipient tissues at the time of rejection of allograft. In this study we provide evidence for presence in the recipient of both, DNA in "passenger cells" and free DNA in tissues at terminal stage of rejection. Male BN (RTIn) rat heart or skin were transplanted to female LEW (RTII) rats followed by a vascularized bone marrow in hind-limb transplant. CsA was given in a dose of 17mg/kg b.w. for 30 days, then rats were followed until day 100 unless rejection occurred earlier. LEW blood, spleen, mesenteric node and bone marrow cells were stained with moAb OX27 specific for BN but not LEW. Genomic male DNA was isolated and amplified with SRY oligonucleotide. At day 30 and 100 cellular microchimerism was detected in blood, spleen, nodes and bone marrow cells. Donor DNA was detected in recipient skin, liver and heart extracts, beside of lymphoid organs, at the time of rejection of allograft but not when rats were maintained on CsA. Taken together, donor DNA can be detected in recipient tissues at the time of heart or skin rejection. It seems to be released from cells of rejecting grafts and not from "passenger" cells representing only a minor cellular mass compared with the graft.

Microchimerism following allogeneic vascularized bone marrow transplantation--its possible role in induction of posttransplantation tolerance.

We have noticed that bone marrow transplanted in a vascularized limb graft providing a continuous supply of donor BMC may prolong the survival time of skin graft from the same donor. The question arises whether the raised microchimerism plays a role in the prolonged survival of skin allograft. The aim of the study was to follow the development of microchimerism after allogeneic vascularized bone marrow transplantation (VBMTx) concomitantly with the rejection processes of transplanted skin. The BN rats served as donors and LEW rats as recipients of VBMTx and free skin flap allograft. Hind limb was transplanted followed by a full-thickness skin graft on the dorsum. Cellular microchimerism was investigated in recipients of VBMTx and skin grafts in blood, spleen, mesenteric lymph node and bone marrow with monoclonal antibody OX27 directed against MHC class I polymorthic RTI on BN cells and quantitatively analysed in FACStar. In VBMTx group free skin flap survived 70 days after weaning of CsA. Intravenous infusion of BMC in suspension equivalent to that grafted in hind limb did not prolong skin graft survival after cessation of CsA therapy. Donor-derived cells could be detected in VBMTx recipients as long 70 days after wearing of CsA but not in recipients of i.v. suspension BMC grafting.

Cyclosporin A decreases lymphocyte migration to the heart allograft through suppression of their L-selectin expression.

Cyclosporin A (CsA) changes the distribution of the circulating pool of lymphocytes and decreases their traffic to organ allograft. The mechanism of this process is complex and includes, among others, inhibition of induction of nuclear factor of activated T cells and suppression of GM CSF and E-selectin expression. We studied the expression adhesion molecules CD11a, CD18, CD44, CD54 and CD62L on the thoracic duct lymphocytes of rats treated with CsA. The 7-day administration of CsA evidently decreased the expression of CD62L but did not affect the other adhesion molecules. Lower concentration of CD62L molecules on the surface of circulating lymphocytes may influence their migration to allograft and distribution in host lymphoid tissues.

Tolerance induction following allogeneic vascularized bone marrow transplantation--the possible role of microchimerism.

We have noticed that bone marrow transplanted in a vascularized limb graft, providing a continuous supply of donor bone marrow cells (BMC), may prolong the survival time of a skin graft from the same donor. The question arises whether the microchimerism raised plays a role in the prolonged survival of skin allografts. The aim of the study was to follow the development of microchimerism after allogeneic vascularized bone marrow transplantation (VBMTx) concomitantly with the rejection process of transplanted skin. Brown Norway (BN) rats served as donors and Lewis rats as recipients of VBMTx and free skin flap allografts. A hind limb was transplanted, followed by a full-thickness skin graft on the dorsum. Cellular microchimerism was investigated in recipients of VBMTx and skin grafts in blood, spleen, mesenteric lymph node, and bone marrow with the monoclonal antibody OX27 directed against MHC class I polymorphic RT1 on BN cells and quantitatively analyzed in a FACStar. In the VBMTx group, the free skin flap survived 70 days after weaning off cyclosporine A (CsA). An intravenous infusion of BMC in suspension equivalent to that grafted in the hind limb did not prolong skin graft survival after cessation of CsA therapy. Donor-derived cells could be detected in VBMTx recipients as long 70 days after weaning off CsA but not in recipients of i.v. suspension BMC grafting.