Lympho-myeloid chimerism achieved by spleen graft of green fluorescent protein transgenic rat in a combined pancreas transplantation model (TI03-029)

BACKGROUND: Multilineage chimerism is a promising strategy to induce donor-specific tolerance. Because the beneficial effect of splenic grafting on tolerance induction is well known, we studied long-term hematopoietic chimerism and the fate of donor-derived cells after allogenic pancreas/spleen transplantation. METHODS: Green fluorescent protein (GFP) transgenic (Tg) Wistar rats were donors and combined pancreas/spleen transplantation (PST) or pancreas transplantation (PT) alone was performed on recipient LEW rats. Graft survival was compared between these two groups and the fate of donor-derived GFP(+) cells was analyzed by flow cytometry. In this system, the donor-derived cells were clearly defined as having lymphocytic or granulocytic lineage by cell size. T-cell subsets of GFP(+) and GFP(-) cells in long graft-surviving rats were also characterized. RESULTS: The survival period of the grafted pancreas in PST rats was significantly longer than that of PT rats (P<0.001). Three of seven PST rats survived >250 days. The chimeric level of donor-derived GFP(+) cells in the recipient peripheral blood was markedly higher in PST rats. In rats with long-surviving grafts, overall peripheral blood chimerism was more than 5%, and both lymphocytes and granulocytes generated from the grafted spleen were stable. T-cell subsets in the recipient LEW rats varied according to the type of cells. CD4(+)CD8(+) subsets decreased in the GFP(+) cells and CD4(-)CD8(+) subsets increased in the GFP(-) (LEW) cells. CONCLUSION: We confirmed the combination effect of the grafted spleen on pancreatic graft survival. Donor lymphocytic and granulocytic lineages were generated in the recipients with long-surviving graft. It suggested that multilineage chimerism was often induced by the spleen graft and protected the pancreatic graft against rejection for a long period.     

Generation of donor hematolymphoid cells after rat-limb composite grafting

BACKGROUND: Composite tissue allografts are unique because they provide the vascularized bone marrow with stroma, which is the supportive microenvironment. In this study, we investigated the beneficial effect of donor-derived bone marrow cells within the long-surviving recipient rats after limb transplantation. METHODS: Green fluorescent protein (GFP) transgenic rats developed for paramount cell marking were donors, and wild Wistar rats were recipients. Orthotopic hind-limb transplantation was performed using a microsurgical technique. Tacrolimus (1.0 mg/kg) was intramuscularly injected for 14 days postoperatively. The skin graft from GFP donor onto the GFP recipient was performed as a control. Flow cytometric analyses of recipient peripheral blood and bone marrow were carried out at 4 to 6 days, 18 to 21 days, 6 weeks, and 2, 4, 6, 9, and 12 months after transplantation. RESULTS: The rats that received tacrolimus therapy achieved prolonged composite graft acceptance more than 12 months, whereas GFP skin grafts were rejected at 47 days under the same immunosuppressive protocol. Numerous GFP lymphocytes and granulocytes were detected within the recipient bone marrow for the first 6 weeks post limb transplantation. These cells remained relatively stable for more than 12 months. CONCLUSIONS: The results showed that donor-derived hematopoietic stem cells engrafted in recipient bone marrow and differentiated to lymphocytes and granulocytes after limb transplantation. The vascularized bone marrow, transplanted as a part of the hind limb, could have contributed to mixed chimerism and worked as the bone-marrow source in the recipients.     

Transmigration of donor cells involved in the sciatic nerve graft

INTRODUCTION: Recently, human hand transplantation in Europe has shown that motor function may be recovered in some cases. However, little is known about cell trafficking involved the graft nerve. We have succeeded to use green fluorescent protein transgenic (GFP-Tg) rats with various cells strongly expressing GFP in a model a long-term survival of limb graft. In this model, we found retrograde migration of GFP-positive donor cells through the sclatic nerve anastomosis. It is well known that cellular components in the peripheral nerve graft especially Schwann cells, play an important role in the axonal regeneration promoted by nerve grafting. However, it was difficult to distinguish the cellular component of the nerve graft from recipient cells. The purpose of this study was to evaluate the migration of donor origin cells to the recipient's nerve and to examine the contribution of these cells in axonal regeneration using a simplified model of sciatic grafting. METHODS: Nerve defects were created in recipient rats, using three experimental combinations: group 1: wild-type rats from GFP Tg rats; group 2: GFP Tg rats from wild-type rats; group 3: wild-type rats from GFP Tg rats whose nerve grafts had been pretreated by freeze-thawing cycles (representing an acellular graft). The sciatic nerve specimens were examined under excitation light at 1, 2, and 3 weeks after transplantation. RESULTS: GFP-positive area expanded clearly beyond the anastomosis both proximally and distally in group 1 and infiltrated into the middle of the null graft in group 2. On the contrary, freeze-thawing grafts donated GFP Tg rats lost GFP expression completely. Columns of GFP-positive cells were formed in the degenerated graft migrated into the recipient's nerve both ante- and retrograde. The S100-positive GFP-positive cells were considered to be graft-origin Schwann cells. The regenerating axons were accompanied with these double-positive cells in the recipient nerve. In conclusion, we have visualized the contribution of graft cells to axonal regeneration beyond a peripheral nerve anastomosis.     

Mobilization of host stem cells enables long-term liver transplant acceptance in a strongly rejecting rat strain combination

Careful examination of liver, kidney and heart transplants in human recipients has revealed small numbers of host bone marrow derived stem cells in the graft. If the limited recipient repopulation of a donor graft that is currently observed could be facilitated, it is possible that conversion to a predominantly host phenotype would permit long-term graft function without immunosuppression. We proposed to "engineer" repopulation after transplant in a strain combination (dark agouti [DA] to Lewis green fluorescent protein+[LEW GFP+]) which rejects liver grafts strongly, a model that more closely resembles the situation in humans. Treatment on days 0, 1, 2, 3 and 7 after transplantation with low-dose (0.1 mg/kg) tacrolimus (T) designed to blunt rejection combined with plerixafor (P) to mobilize host stem cells resulted in greater than 180 days graft survival with extensive albeit spotty conversion of a small (50%) DA graft to the recipient LEW GFP+ genotype. Subsequent skin grafting revealed donor-specific graft prolongation. The T plus P treatment resulted in higher levels of Lin-Thy1+CD34+CD133+ stem cells and Foxp3+ regulatory T cells in the blood and liver at day 7. Thus, pharmacological mobilization of host stem cells sustains liver allografts by two mechanisms: repopulation of injured donor cells and regulation of the immune response.     

Adult endothelial progenitor cells retain hematopoiesis potential

Hematopoietic stem cells (HSCs) are derived from endothelium in the aortic-gonado-mesonephric (AGM) region during embryogenesis. But little is known about whether endothelial progenitor cells (EPCs) retain hematopoiesis potential after birth. In this study, we isolated adult EPCs from the bone marrow of C57BL/6 mice and identified them with an endothelial functional assay and by the CD31(+) CD133(+) CD45(-/dim) VEGFR2(+) phenotype. EPCs isolated from green fluorescence protein (GFP) transgenic C57BL/6 mice were cotransfused with bone marrow cells from wild-type C57BL/6 mice into lethally irradiated BABL/c mice. One month after transplantation, granulocytes (25.73 ± 5.43%) and lymphocytes (12.68 ± 3.26%) in peripheral blood showed GFP(+), referred to as donor EPC-derived blood cells. After an additional month, the percentage of GFP(+) granulocytes decreased to (3.69 ± 1.43%), whereas the percentage of GFP(+) lymphocytes showed no significant difference. Most of the GFP(+) elements showed a diffuse distribution in the spleen; but some were present as aggregates forming lymphoid nodules. GFP(+) endothelial cells were observed in the liver sinusoids, intestinal villi, and lung of recipient mice. These results indicated that adult EPCs not only took part in vasculogenesis, but also retained hematopoietic ability.     

Impact of graft length on surgical damage after intestinal transplantation in rats

BACKGROUND: Intestinal grafts greatly affect nutrition and immunology in the host. The growth of the recipient and incidence of graft-versus-host disease depend on graft length. A larger graft may affect the host immune system, but little is known about how the length of the intestinal graft severely affects surgical intervention. We developed a cervical small bowel transplantation (SBT) rat model that minimized technical variations using a cuff method and studied the effects of graft length on surgical damage in SBT. MATERIALS AND METHODS: We transplanted a whole (70 cm) or partial (15 cm) intestine into a syngeneic rat combination of LEW (MHC haplotype: RT1(l)) to LEW and evaluated changes in perioperative hemodynamics and the endogenous endotoxin level. Natural killer (NK) cell activity in the peripheral blood and the immunologic response of the recipient spleen were also studied. RESULTS: In the whole SBT model, body weight loss was more severe than in the segmental SBT model; the rats in the former model often died, while all in the latter survived indefinitely. The systemic blood pressure markedly decreased in the whole SBT group immediately after reperfusion. The proliferative activity of splenic lymphocytes stimulated by concanavalin A was also more severely inhibited in the former model than in the latter postoperatively. NK cell activity in the whole SBT rats declined more severely than the segmental SBT rats 3 days postoperatively. CONCLUSION: The longer graft severely induced surgical intervention; and influenced host immunosuppression, resulting in the higher mortality in rats undergoing whole SBT.     

Acute Graft Versus Host Disease Following Liver Transplantation: The Enemy Within

This article reviews acute graft vs. host disease (GVHD) as a complication of orthotopic liver transplantation (OLT). The incidence, presentation, clinical course and outcome of GVHD after OLT are summarized and the pathogenesis is discussed, drawing parallels with GVHD after allogeneic haematopoietic stem cell transplantation. Risk factors for GVHD after OLT are examined and the potential role of donor lymphocyte macrochimerism in the recipient peripheral blood as a diagnostic aid for GVHD is discussed. Finally, treatment of GVHD after OLT is reviewed with particular emphasis on the potential role of some of the newer biological agents.     

The impact of portal infusion with donor-derived bone marrow cells and intracellular cytokine expression of graft-infiltrating lymphocytes on the graft survival in rat small bowel transplant model

BACKGROUND: Intraportal administration of alloantigen is reported to reduce antigen-specific immune responses, although the underlying mechanisms for the reduced immunological reactions, especially those of the graft, are poorly understood. We examined intracellular cytokine production by graft-infiltrating lymphocytes (GILs) and peripheral blood lymphocytes (PBLs) to elucidate the underlying mechanisms of beneficial effects on intraportal infusion of donor cells in rat small bowel transplantation (SBT). METHODS: Recipient rats (Lewis) were transplanted with small bowel from ACI rats. Tacrolimus (Tac) was injected daily from days 0 to 4. Bone marrow cells of ACI rats were infused via the portal or tail vein on the day of surgery. On day 5, both GILs and PBLs collected from SBT graft and peripheral blood, respectively, were analyzed for intracellular cytokine production of recipient-derived alphabeta-T cells. The Th1/Th2 balance in each group was designated as the ratio of the percentage of GILs or PBLs staining positive for intracellular IL-4 or IFN-gamma, respectively. The total cell numbers of GILs from SBT graft were also counted. RESULTS: Survival of recipients was markedly prolonged by the combination of Tac and donor-specific bone marrow infusion via the portal vein (DSBMI-PV-Tac) compared with the untreated control, Tac alone, or DSBMI tail vein plus Tac. DSBMI-PV-Tac significantly decreased the total cell numbers of GILs and also induced remarkable Th2-type response in GILs. CONCLUSIONS: Our results indicate that DSBMI-PV-Tac decreased GILs and enhanced Th2-type response in SBT graft, both of which are associated with a significant prolongation of graft survival in SBT.     

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

Abstract 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 × 10⁷ 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.     

Little evidence for cell fusion between recipient and donor-derived cells

Despite recent advances in immunosuppressive therapy, accelerated coronary atherosclerosis remains a major problem in the long-term survival of cardiac transplant recipients. However, the pathogenesis of the transplant-associated atherosclerosis remains largely unknown. Here, we investigated the origin of the vascular cells that contribute to graft vasculopathy. We performed heterotopic heart transplantation using genetically modified mice that express LacZ or green fluorescent protein (GFP) ubiquitously and constitutively. At 4 weeks after transplantation, the graft coronary arteries developed neointimal hyperplasia, expressing several smooth muscle cell markers. Most of the neointimal cells were composed of recipient cells but not graft medial smooth muscle cells. We seldom detected neointimal cells that were positive for both LacZ and GFP. When we transplanted wild-type cardiac allografts into the chimeric mice whose bone marrow cells had been replaced with those of LacZ-mice or GFP-mice, we observed that most of the neointimal cells were derived from the bone marrow. These findings suggest that recipient bone marrow-derived cells contribute to the pathogenesis of graft arteriosclerosis. Spontaneous cell fusion between recipient and donor-derived cells seems to be a rare event, if it occurs at all.     

Recipient bone marrow engraftment in donor tissue after long-term tolerance to a composite tissue allograft

BACKGROUND: An important component of a composite tissue limb allograft (CTA) is the vascularized bone marrow and bone marrow stroma, which when transplanted could create immediate marrow space and engraftment. We have previously demonstrated that tolerance to musculoskeletal allografts can be achieved with a 12-day course of cyclosporine without the presence of long-term peripheral donor cell chimerism. The objective of this study was to determine the fate of the donor bone marrow after transplantation of a limb allograft in a miniature swine model. METHODS: CTAs from donor swine were heterotopically transplanted into six MHC-matched, minor-antigen-mismatched recipients, and a 12-day course of cyclosporine was given. Previous animals transplanted without cyclosporine rejected their grafts in less than 42 days. A non-MHC-linked marker, pig allelic antigen (PAA), was used to distinguish host and donor cells. Three PAA- animals received PAA+ CTAs, and three PAA+ animals received PAA- CTAs. Bone marrow was harvested from the donor limb grafts and the recipient and analyzed by flow cytometry and histology. Thymus, spleen, and mesenteric lymph nodes were also harvested from the recipient swine and evaluated for the presence of donor cells by flow cytometry. RESULTS: All animals receiving cyclosporine demonstrated permanent tolerance to their allografts. Donor bone marrow cells were present in all grafts at the time of transplantation and during the immediate postoperative period. By 48 weeks, donor cells were no longer detectable within the marrow space of the allograft. In long-term animals host bone marrow cells replaced donor cells in the graft marrow space. No evidence of donor cell engraftment was found in recipient animals. CONCLUSION: This study demonstrates that in long-term tolerant recipients of musculoskeletal allografts there is no evidence of persistent donor bone marrow cells in the hematopoietic tissues of the graft or the host. Rather, the recipient's bone marrow cells and lymphocytes repopulate the donor marrow space of the graft.     

Thymic microchimerism correlates with the outcome of tolerance-inducing protocols for solid organ transplantation.

This study found that pretransplant infusion of donor peripheral blood leukocytes, either total leukocytes (peripheral blood leukocytes) or peripheral blood mononuclear cells (PBMC), under appropriate immunomodulating conditions was more effective than donor bone marrow (BM) in prolonging the survival of rats that received kidney grafts. A higher percentage of MHCII(+) cells was found in donor PBMC than in BM cells, and depletion of MHCII(+) cells from donor PBMC abolished their tolerogenic potential. By the analysis of microchimerism in rats infused with donor cells and killed at different time points thereafter, the better tolerogenic potential of leukocyte infusion related to a higher capability of these cells to engraft the recipient thymus. PCR analysis on OX6-immunopurified cells revealed the presence of donor MHCII(+) cells in the thymus of these animals. The role of intrathymic microchimerism was reinforced by findings that thymectomy at the time of transplant prevented tolerance induction by donor leukocytes. Donor DNA was found in the thymus of most long-term graft animals that survived, but in none of those that rejected their grafts. The presence of intrathymic microchimerism correlated with graft survival, and microchimerism in other tissues was irrelevant. PCR analysis of DNA from thymic cell subpopulations revealed the presence of donor MHCII(+) cells in the thymus of long-term surviving animals. Thus, in rats, donor leukocyte infusion is better than donor BM for inducing graft tolerance, defined by long-term graft survival, donor-specific T cell hyporesponsiveness, and reduced interferon gamma production. This effect appears to occur through migration of donor MHCII(+) cells in the host thymus.     

"Firefly rats" as an organ/cellular source for long-term in vivo bioluminescent imaging

BACKGROUND: Transplantation research involving the use of stem cells demands an appropriate in vivo visualization system to monitor cellular fate over an observation period. The new field of in vivo imaging is being developed with fluorescent and luminescent biotechnology, and involves the real-time visualization of complex cellular processes in living animals. METHODS.: Following our recent development of inbred green fluorescent protein (GFP)-transgenic (Tg) rats, we created the establishment of inbred (Lewis) Tg rats with firefly luciferase. The immunogenicity against luciferase was evaluated by the skin grafting test, and the fate of grafts was monitored by in vivo luminescent technique. RESULTS.: The luciferase-Tg rats ubiquitously expressed the marker gene. Conventional skin grafting apparently showed the long-term acceptance of luciferase-Tg rat skin on wild-type rats (>100 days), compared with grafting of GFP-Tg-derived skin (<10 days). This suggests less cellular immune responsiveness against the luciferase protein than GFP. Strikingly, organ transplants with heart and small bowel, and bone marrow cell transplantation showed viability and graft acceptance, demonstrating that cells and organs from luciferase-Tg rats are transplantable and their fate can be tracked for a sufficient time. Taking advantage of less immunogenic luciferase, cellular fate of transplanted mature hepatocytes was also examined. Transplanted hepatocytes proliferated and were monitored selectively in damaged liver, but not in healthy liver, for over 60 days. CONCLUSIONS: We propose on the basis of these findings that the luciferase-Tg rat system with modern optical imaging offers a new platform for a better understanding of stem cell biology and transplantation.     

Emergency living related liver transplantation for fulminant reactivation of hepatitis B virus after unrelated marrow transplantation

We report a unique case of emergency living related donor orthotopic liver transplantation (OLT) for late fulminant reactivation of hepatitis B virus (HBV) after matched unrelated bone marrow transplantation (BMT) for chronic myeloid leukemia (CML). Cessation of lamivudine after BMT for HBV positive patients may carry risks of late fatal HBV reactivation. Similar to fulminant HBV reactivation in the general population, OLT under resumption of lamivudine can be life saving. In our case, concomitantly molecular relapse of CML at the time of liver failure was also cleared by OLT, possibly via a 'liver-graft vs. leukemia' effect. Liver rejection (graft vs. graft disease) was mild due to inherent immunocompromise of the marrow graft. Hence BMT recipients in stable remission should not be denied the opportunity for life-saving solid organ transplantation. A choice of marrow and liver donors with innate HBV immunity may be needed to give the additional advantage of long-term HBV clearance.     

Bone marrow transplantation in the rat. B lymphocyte activation in acute graft-versus-host disease

We have isolated the white cells from the bone marrow, spleen, and blood of a rat recipient of a bone marrow allograft and the inflammatory leukocytes from the recipient skin, lung, gut, and liver (the parenchymal target organs for acute graft-versus-host disease (aGVHD)) and compared the number of immunoglobulin-synthesizing and releasing cells in these cell populations to corresponding compartments of a syngeneic graft recipient. Bone marrow transplantation was associated in the early phase with marked immunoglobulin production in the cells of bone marrow, spleen, and blood of the allograft recipient; as, however, a similar response occurred in the syngeneic graft recipient we conclude that this is related to reconstitution rather than to aGVHD. Later, during aGVHD, the number of immunoglobulin releasing cells decreased significantly in the spleen and bone marrow of the allografted animal. In clear contrast, in the liver--but not in skin, lung, or gut--very few immunoglobulin-releasing cells were observed in the syngeneic graft recipient, whereas in the allograft recipient a very strong and significantly higher immunoglobulin synthesis and release was seen coinciding with the inflammatory episode of aGVHD in the liver.     

Bone marrow transplantation in the rat. V. Lymphoid cell subclasses in the target organs during acute graft-versus-host disease

The distribution of white cell subclasses in different lymphoid (bone marrow, spleen, and blood) and parenchymal (liver, skin, lungs, and gut) target organs was studied after bone marrow transplantation in the rat. BN rats were irradiated and transplanted with 60-80 X 10(6) Lew (allogeneic) or BN (syngeneic) bone marrow cells. The recovery of lymphocytes was somewhat elevated in the bone marrow and spleen, slightly decreased in the blood, and markedly higher in the liver and skin in the allograft compared with the syngeneic graft recipient. A mild lymphocytic bronchitis was present in the lungs of the allografted animal, and the gut was hypocellular throughout the observation period. The total recovery of different lymphocyte subclasses; pan T, T helper, T suppressor-killer, class-II-positive cells, and surface-Ig-positive B cells in the different lymphoid organs--i.e., bone marrow, spleen, and blood--was similar in allogeneic compared with syngeneic graft recipients. In the liver and skin, which are the major target organs of acute graft-versus-host disease (aGVHD) in the rat, there was a massive infiltration of different T cell subclasses; high numbers of B cells were also seen in the liver. There was no difference in the T helper/T suppressor-killer ratio in the lymphoid organs or the liver of allograft compared with syngeneic graft recipients; in the skin and lungs the ratio was reduced more in the allograft compared with syngeneic graft recipient, whereas in the gut the situation was the opposite. These observations emphasize regional differences in the structure of inflammation in the different parenchymal target organs of aGVHD in the rat.     

A study of tolerance induced by liver transplantation on intestinal graft in the rat]

In some strain combinations of rats, orthotopic liver transplantation (OLT) permits long-term donor-specific survival of fully allogeneic kidney, heart or skin grafts. The difficulties encountered in the clinical situation to obtain tolerance of small-bowel transplantation (SBT), in spite of massive non-specific immunosuppression, led us to study possible liver-induced tolerance in SBT. Inbred DA (RTIa) and PVG (RT1c) rats were used respectively as donors and recipients and divided in two groups: group 1: SIT alone (n = 6); group 2: combined OLT/SBT (n = 6). SIT was performed 17 days after OLT. No immunosuppressive treatment was given to the recipients. Biopsies of small-bowel grafts were performed in both groups at various times after small bowel engraftment. All animals in group 1 showed evidence of acute rejection of the graft between days 6 and 9 post-graft. The histologic pattern of rejection associated lamina propria (LP) mononuclear cell infiltration, crypt lesions and villous atrophy at the end-point of rejection. In group 2, long-term survival (> 100 days) of small bowel grafts was achieved in five of the six animals in spite of strong mononuclear cell infiltration in the LP, which peaked two months after small bowel grafting but then disappeared partially. This striking mononuclear cell infiltrate contrasted with only minor epithelial damage. These data demonstrate that liver grafting can enhance the survival of a small-bowel graft from the same donor in a rat model. Histological findings show that an intense immunological reaction takes place within liver-induced tolerated small-bowel grafts.     

Detection of chimerism following vascularized bone allotransplantation by polymerase chain reaction using a Y-chromosome specific primer.

Chimerism following allogeneic organ transplantation is a phenomenon known to occur and be associated with development of immunologic tolerance in allotransplantation. However, little is known about graft cell migration following vascularized bone allografting. In this study, chimerism was assessed following vascularized tibia transplantation from male DA or PVG donors to female PVG rat recipients using a semi-quantitative polymerase chain reaction for the Y-chromosome. FK-506 (Tacrolimus) was administered after transplantation for immunosuppression. All immunosuppresssed PVG rat recipients of PVG bone grafts showed a high level of chimerism (1%) in the thymus, spleen, liver and cervical lymph nodes at 18 weeks post-transplant. Donor cells were also detected in the contralateral tibia and humerus. In non-immunosuppressed PVG rat recipients of DA bone grafts, donor cells were detected in the spleen in three of five rats within 2 weeks post-transplant. In these animals the bone grafts were severely rejected. In immunosuppressed PVG rat recipients of DA bone grafts, two of five, four of eight and eight of 10 rats showed low level chimerism (0.1%) in peripheral blood at 1, 12, and 18 weeks post-transplant. Six rats showed a high level of chimerism in the spleen and thymus. Histological studies revealed no rejection findings through 18 weeks post-transplant. Our results indicate that chimerism, or the presence of graft cells in host tissue, may occur in the face of acute rejection and be demonstrable following vascularized isograft and allograft living bone transplantation when chronic immunosuppression is maintained. Graft vascular patency during the short-term likely allows cellular migration, even in the face of acute rejection. Long-term survival and proliferation of graft marrow elements in host tissue may be possible with adequate immunosuppression.     

Repopulation of donor heart by recipient bone marrow-derived dendritic cells prior to transplantation causes acute rejection by both the allogeneic and syngeneic recipient

Experimental studies on allogeneic transplantation have shown that recipient dendritic cells (DC) play a role in peripheral tolerance as well as in rejection of allografts. It is not known whether DC exert their tolerogenic function in recipient lymphoid tissue, and whether they process shed alloantigen in the graft itself. To answer this question we created a chimeric heart model deprived of its own DC and repopulated by recipient DC. The rationale for this model was to observe whether recipient DC located in the graft attenuate recruitment and stimulation of recipient lymphocytes, subsequently prolonging graft survival. Vascularized bone marrow transplants (VBMTx) from the prospective recipient to the lethally irradiated heart donor, which function for a period of 14 days, were used to replace donor DC with prospective recipient DC. Hearts from chimeric LEW rats (with BN DC) were transplanted to untreated BN rats. Also, hearts from chimeric LEW rats (with BN DC) were returned to untreated LEW rats. Replacement of the donor heart with recipient DC did not prolong graft survival. Rather, it initiated a rejection reaction that was already present in the donor. Recipient DC retained their immunogenic properties also when the graft was returned back to a donor strain animal.     

Cytotoxic T-cell elimination during anti-CD4-induced rat liver acceptance and rapid replacement of functional graft antigen-presenting cells.

In previous studies, we showed that primed T cells were eliminated in long-term survival Wistar Furth (WF) recipient rats with spontaneously accepted Lewis (LEW) liver graft and that the grafted liver lost the ability to elicit rejection reaction early after liver transplantation. We hypothesized that the same phenomenon may be observed in tolerant animals after immunosuppression in a rejector rat strain combination (WF-->LEW). Furthermore, we proposed the repopulation of liver allograft with host antigen-presenting cells rapidly after transplantation. Recipient LEW rats that underwent anti-CD4 therapy accepted the WF liver allografts after a transient rejection reaction. In tolerant animals, alloreactive CD8 T cell precursors were present, but primed T cells were absent. Intraperitoneal challenge with grafted WF liver homogenates obtained from recipient LEW rats on day 4 after transplantation did not induce transient rejection responses in long-term survival recipient LEW rats, a finding that differed from the results of experiments using normal WF liver homogenates. However, challenge with grafted WF liver homogenates, similar to those of normal LEW liver homogenates, induced rejection responses in long-term survival recipient WF rats with LEW liver allograft. Flow cytometric analysis confirmed that most of nonparenchymal cells in the grafted WF liver were recipient (LEW) genotype. These observations showed that the deletional mechanism of effector T cells also is observed in this setting, and professional donor antigen-presenting cells are replaced by those of recipient genotype within the graft during the early phase of transplantation.