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.     

Long-lasting donor passenger leukocytes after hepatic and intestinal transplantation in rats

BACKGROUND: Donor passenger leukocytes (DPLs) that migrate after organ transplantation stimulate the recipient immune system and normally cause rejection and graft vs. host reaction. However, DPLs also contribute to the unresponsiveness to the donor organ. The quantity and quality of these migrating cells are considered dependent on individual transplanted organs. We compared the DPLs of the liver, which might contain somatic stem cells, with those of intestinal grafts that have highly immunogenetic cells. To study DPLs over a long period, we used green fluorescent protein (GFP) transgenic (Tg) rats developed by us as donors. METHODS: We performed orthotopic liver transplantation (OLT) and small bowel transplantation (SBT) from GFP Tg rats to wild recipients. A short course of tacrolimus (0.64 mg/kg, intramuscularly) was used to prevent antigenicity of the GFP. The fate of the DPLs in the peripheral blood and the recipient bone marrow was monitored by flow cytometry. Using long-surviving recipients, the GFP(+) cells in the graft and various host immunologic organs were measured and characterized by immunohistochemical staining. RESULTS: In both groups, the numbers of the GFP(+) cells in the peripheral blood increased transiently and then gradually decreased to undetectable levels. While no GFP(+) cells were identified in the long-surviving-recipient bone marrow, there were a few GFP(+) cells in the graft liver, graft mesenteric lymph nodes and the recipient spleen. These cells showed major histocompatibility complex (MHC) class II antigen. There was no significant difference in the migration patterns of the GFP(+) cells in the OLT and SBT rats. CONCLUSIONS: In both the OLT and SBT groups, the DPLs migrated transiently in the recipient peripheral blood. A small numbers of MHC class II-positive DPLs were present at the graft site and in the host spleen, but not in the bone marrow. There were no significant differences in the migration patterns of the DPLs between the OLT and SBT rats over the long term.     

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.     

Immunologic consequences of combined pancreas-spleen transplantation in the rat

A rat model of combined pancreas-spleen transplantation (PST) was used in order to characterize the immunologic consequences of PST when compared to pancreas transplantation (PT) alone. Weakly MHC disparate Fischer (F344) PST grafts survived significantly longer in LEW recipients than did F344 PT grafts (17.6 +/- 3.4 vs 12.1 +/- 1.0 days, respectively, P less than 0.001). However, graft versus host disease (GVHD) occurred regularly in the PST recipients. Similarly, in haploidentical LBN to LEW donor-recipient pairs, PST graft survival was also modestly but significantly increased over that of the PT controls (10.6 +/- 1.0 vs 8.5 +/- 0.8 days, respectively, P less than 0.001). Conversely, in the ACI to LEW combination where MCH differences are very strong, PST graft survival was not longer than PT controls (7.5 +/- 0.8 vs 7.0 +/- 0.6 days, respectively, P greater than 0.2). GVHD was not observed in either of the latter two experiments. Short-term immunosuppression with cyclosporine further improved the outcome in LEW recipients of F344 grafts by inducing long-term graft survivals in approximately one-fourth of the PST recipients. Host splenectomy did not improve graft survival in PST recipients but did increase the risk of GVHD in LEW recipients of F344 PST grafts. Graft irradiation prior to transplantation with 500 rad not only abrogated the GVHD potential of the F344 PST graft but also eliminated the graft survival prolonging effect of the donor spleen. Donor spleen cells injected at the time of PT in F344 to LEW transplants resulted in graft prolongation not different from spleen intact PST recipients.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-dose tacrolimus and lengthy survival of the combined rat pancreas/spleen graft in a high-responder combination.

Pancreas grafts do not survive for lengthy periods, especially in a high-responder rat combination. Recent data indicated that a combined spleen/pancreas graft protects against acute graft rejection and induces donor-specific tolerance. In this study, we performed a combination spleen/pancreas transplantation using high-dose tacrolimus in a high-responder rat combination of DA (RT1a) to LEW (RT1) and induced permanent survival in the few recipient rats. In these recipients, there was no difference in the mixed lymphocyte reaction (MLR) of the recipients when compared with that of the naive LEW splenic cells, but MLR inhibition by the serum from the recipients was significantly decreased. We also performed immunoblotting and detected a protein that has an affinity for the anti-DA class antibody. This protein may be an anti-idiotypic antibody and contribute to donor- and tissue-specific tolerance.     

负向免疫调节树突状细胞对心脏移植大鼠免疫状态的影响

目的 探讨经体外光化学法(PUVA)处理的供者脾淋巴细胞与受者树突状细胞(DC)共培养后,对移植受者体液免疫、细胞免疫及移植物排斥反应的影响.方法 以DA大鼠为供者,LEW大鼠为受者,建立大鼠腹部异位心脏移植模型.分离供者脾淋巴细胞(SP),制备经PUVA处理的供者脾淋巴细胞(PUVA-SP).在体外分别将供者PUVA-SP和SP与受者骨髓来源的未成熟DC共培养,得到PUVA-SP-DC及SP-DC,流式细胞仪检测上述DC表型.根据受者心脏移植术前1周静脉输注成分的不同,将受者随机分为3组:(1)对照组(n=7):单纯输注磷酸盐缓冲液(PBS);(2)SP-DC组(n=8):输注Sp-DC 5×106个;(3)PUVA-SP-DC组(n=8):输注PUVA-SP-DC 5×106个.每日观察各组移植心的存活状况.移植后第6天,检测受者血清中抗供者特异性IgG水平;通过混合淋巴细胞反应(MLR)检测受者脾脏T淋巴细胞对供者抗原刺激的增殖反应;比较各组受者脾脏体积的大小.结果 供者脾淋巴细胞经PUVA处理后细胞凋亡率为81.93%.正常LEW大鼠DC共刺激分子CD80和CD86阳性率分别为(3.5±0.27)%和(13.0±0.58)%,受者DC与供者SP混合培养后,其CD80和CD86的表达水平为(16.6±0.72)%和(36.5±0.87)%,后者明显高于前者(P<0.01);受者DC与供者PUVA-SP混合培养后,其CD86和CD80的表达率分别为(3.9±0.12)%和(13.4±0.59)%,与正常LEW大鼠DC相当(P>0.05).PUVA-SP-DC组的受者抗供者特异性IgG水平明显低于SP-DC组及对照组(P<0.01).PUVA-SP-DC组受者T淋巴细胞对供者抗原的刺激反应指数为1.66±0.29,明显低于SP-DC及对照组(7.28±0.38、4.19±0.16,P<0.01);而其对无关供者抗原的刺激反应指数为4.37±0.11,与SP-DC及对照组相当(4.51±0.40、4.36±0.14,P>0.05).PUVA-SP-DC组的移植心存活时间比其他两组明显延长(P<0.01),而且其脾脏体积最小.结论 PUVA-SP-DC能够特异性的下调移植受者对供者抗原的细胞免疫及体液免疫反应,从而明显延长移植物存活时间.     

Donor-derived alloantigen-presenting cells persist in the liver allograft during tolerance induction

The predictive value of chimerism was evaluated in three different transplantation models in the rat without immunosuppression: small bowel- (SBTx), liver- (LTx), and liver/small bowel transplantation (LSBTx) were performed in the Brown Norway (BN)-to-Lewis- (LEW) strain combination. Immunohistochemistry and flow cytometry were used to identify donor cells in the recipient's spleen. Their number did not change significantly during transient rejection or tolerance after LTx and LSBTx. However, the amount of donor-derived nonparenchymal cells within the liver allograft including antigen-presenting cells (APCs), such as dendritic and Kupffer cells, clearly mirrored the recipient's immune status: as expected, their number decreased during rejection, but recovered considerably during and after tolerance induction. We conclude that donor cells in the periphery of the recipient correlate with the presence of the allograft, but do not seem to influence graft acceptance actively. However, the kinetics of the detected donor APC population in the liver suggests their important role in modifying the recipient's immune response towards tolerance. Received: 29 March 1999/Revised: 19 August 1999/Accepted: 3 November 1999     

Donor bone marrow cells play a role in the prevention of accelerated graft rejection induced by semi-allogeneic spleen cells in transplantation

Spleen or spleen plus bone marrow cells from (BALB/cxC57Bl/6)F1 donors were transferred into BALB/c recipients 21 days before skin or cardiac transplantation. Prolonged graft survival was observed on recipients treated with the mixture of donor-derived cells as compared to those treated with spleen cells alone. We evaluated the expression of CD45RB and CD44 by splenic CD4+ and CD8+ T cells 7 and 21 days after donor cell transfer. The populations of CD8+CD45RBlow and CD8+CD44high cells were significantly decreased in mice pre-treated with donor spleen and bone marrow cells as compared to animals treated with spleen cells only, although these cells expanded in both groups when compared to an earlier time-point. No differences were observed regarding CD4+ T cell population when recipients of donor-derived cells were compared. An enhanced production of IL-10 was observed seven days after transplantation in the supernatants of spleen cell cultures of mice treated with spleen and bone marrow cells. Taken together these data suggest that donor-derived bone marrow cells modulate the sensitization of the recipient by semi-allogeneic spleen cells in part by delaying the generation of activated/memory CD8+ T cells leading to enhanced graft survival.     

Beta-galactosidase of ROSA26 mice is a useful marker for detecting the definitive erythropoiesis after stem cell transplantation

BACKGROUND: Hematopoietic reconstitution after stem cell transplantation has been analyzed by using stem cells of Ly5 congenic mice. However, the early erythropoiesis has never been analyzed because this marker is not expressed on all of the erythroid lineage cells. The transgenic mouse expressing beta-galactosidase (beta-gal) or green fluorescent protein (GFP) has been reported. Using these markers, we analyzed the early erythropoiesis after stem cell transplantation. METHODS: The beta-gal activity and GFP were examined in the hematopoietic cells of ROSA26 and GFP transgenic mice, respectively, by flow cytometry. The primitive hematopoietic stem cell fraction (Lin(-)c-kit(+)Sca-1(+)) in bone marrow (BM) cells of ROSA26 mice was transferred into lethally irradiated mice. The kinetics of hematopoietic reconstitution was analyzed in the BM and spleen after transplantation. RESULTS: The beta-gal activity, but not the GFP and Ly5, was detected in all of the erythroid (TER119+) cells. The beta-gal activity was also detected in the donor-derived myeloid (Mac-1+), B lymphoid (B220+), and T lymphoid (Thy-1+) cells in the BM and spleen after stem cell transplantation. The kinetics of the hematopoietic reconstitution demonstrated that early erythroid (TER119(low)CD71(med)) cells were developed in the BM and spleen within 2 days after transplantation before development of proerythroblasts (TER119(+)CD71(high)), and that massive erythropoiesis and myelopoiesis were observed in the spleen until 2 and 4 weeks after transplantation, respectively. Conclusions. The beta-gal of ROSA26 mice can be a useful marker to identify the donor-derived hematopoietic cells, including early erythroid cells, and the first major wave of erythropoiesis occurring in the spleen after stem cell transplantation.     

成年大鼠联体共生诱导肾移植耐受及其机制研究

目的：建立异基因大鼠联体共生的动物模型,探讨其诱导肾移耐受机理,方法对DA和LEW大鼠实施联体手术并诱导耐受,然后进行DA→LEW的肾移植。FACS检测术后脾脏、脾胸中嵌中状态态;检测体内、外过继转移耐受大鼠脾细胞对正常大鼠单向混合淋巴细胞反应（MLR）和迟发性过敏反应（DTH）的抑制作用,以及T细胞克隆不应答在耐受中的作用。结果：联体共生诱导耐受可使DA→LEW的肾移植存活明显延长。耐受组脾脏、胸腺中供体细胞的嵌合比例明显高于排斥组。耐受可通过体内,外过继转移给正常大鼠。外源性IL－2可部分逆转耐受状态。结论嵌合状态态与肾移植耐受存在明显相关性,克隆不应答、抑制细胞参与了耐受的形态。     

Induction of heme oxygenase-1 in the donor reduces graft immunogenicity

There is increasing evidence that the induction of the enzyme heme oxygenase-1 (HO-1) improves both graft function and survival. Although it has been shown that HO-1 promotes graft protection, it remains unknown whether it reduces graft immunogenicity by modulating dendritic cells. In the current experiment, we investigated the impact of HO-1 induction on frequencies and trafficking of donor-derived dendritic cells (DCs). Kidneys from DA rats were transplanted into untreated Lewis recipients. Donor animals were treated with cobalt protoporphyrin (CoPP; 5 mg/kg IP) 24 hours prior to organ harvesting to induce HO-1. Controls remained untreated or received zinc protoporphyrin (ZnPP; 20 mg/kg, IP) to block HO-1 induction. Analyses of grafts, spleens, lymph nodes and blood of Lewis recipients were performed at days 1 and 3 posttransplantation. Donor-specific DCs were determined by flow cytometry using haplotype-specific mAb against RT1(ab) and mAb against OX62(+) antigens. Cell markers (CD4/CD8(+) T cells, ED1(+) monocytes, MHC class II(+) CD86(+) DC) were measured by immunohistochemical staining. T-cell alloreactivity of recipient splenocytes was measured by ELISPOT. Induction of HO-1 reduced frequencies of donor-derived DCs in the graft and recipient compartments, which was associated with reduced frequencies of CD4(+) T cells and CD8(+) T cells and alloreactivity. Expression of costimulatory molecule CD86 and MHC class II antigens were also reduced, although not significantly. Thus, induction of HO-1 reduced graft immunogenicity. These mechanisms may explain the protective effects of HO-1 induction.     

Induction of transplantation tolerance by allogeneic donor-derived CD4(+)CD25(+)Foxp3(+) regulatory T cells

Several studies have shown that recipient-derived CD4(+)CD25(+)Foxp3(+) regulatory T cells (Tregs) are involved in transplantation tolerance. However, it is not clear whether allogeneic donor-derived Tregs are able to regulate T cell alloreactivity after solid organ allograft transplantation. Related studies in experimental bone marrow transplantation have shown that allogeneic donor-derived Tregs are capable of promoting early and long-term allogeneic hematopoietic engraftment, accompanied by tolerance to donor and recipient antigens. However, in these models, donor-derived Tregs are syngeneic with respect to the T responder cells. The role of Tregs in solid organ transplantation models where recipient-derived T responder and donor-derived Tregs are allogeneic has been scarcely studied. In order to determine whether allogeneic Tregs were able to regulate T cell alloreactivity, CD4(+)CD25(-) and CD8(+) T responder cells were cultured with stimulator dendritic cells in several responder-stimulator strain combinations (C57BL/6-->BALB/c, BALB/c-->C57BL/6 and C3H-->BALB/c) in the presence of responder-derived, stimulator-derived or 3rd-party-derived Tregs. Then, the frequency of IFN-gamma+ alloreactive T cells was determined by means of ELISPOT assay. The results of this study demonstrate that, regardless of the responder-stimulator strain combination, both responder-derived and stimulator-derived Tregs, but not 3rd-party-derived Tregs, significantly inhibited CD4(+) and CD8(+) T cell alloreactivity. The effect of allogeneic stimulator-derived Tregs was dependent on IL-10 and TGF-beta and reversed by exogenous IL-2. In vivo experiments in nu/nu recipients reconstituted with CD4(+)CD25(-) T responder and Tregs showed that recipient and donor-derived, but not 3rd-party-derived Tregs, significantly enhanced skin allograft survival. Importantly, T cells from both recipient-derived and donor-derived Treg-reconstituted nu/nu recipients exhibited donor-specific unresponsiveness in vitro. These results show that allogeneic donor-derived Tregs significantly inhibit T cell alloreactivity and suggest their potential use in the induction of transplantation tolerance.     

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.     

Adoptive transfusion of ex vivo donor alloantigen-stimulated CD4(+)CD25(+) regulatory T cells ameliorates rejection of DA-to-Lewis rat liver transplantation

BACKGROUND: Adoptive transfusion of splenocytes from long-term survivors of a tolerance model of rat orthotopic liver transplantation can induce acceptance of liver allografts in a rejection model preconditioned with donor gamma-irradiation before liver transplantation. Recent studies suggest that the regulatory T cells (Treg cells) in splenocytes from long-term survivors play an important role in the induction of liver graft tolerance, but this observation was made from a rejection model preconditioned with donor gamma-irradiation; little is known about the role of Treg cells in liver graft rejection using a naive rejection model. In this study, we examined the therapeutic potential of CD4(+)CD25(+) Treg cells in a naive rejection model of rat liver transplantation. METHODS: Freshly isolated or ex vivo alloantigen-stimulated CD4(+)CD25(+) Treg cells (1 x 10(6) cells) from naive Lewis RT(1) (LEW) rats were adoptively transferred into another LEW rat on days 1 and 7 after liver transplantation from a Dark Agouti RT1(a) (DA) rat. Recipients were treated with or without oral tacrolimus (FK506) (0.1 mg/kg/day) from days 1 to 7 after transplantation. For ex vivo alloantigen-stimulation, CD4(+)CD25(+) Treg cells from LEW rats were cocultured with mitomycin C-treated DA (donor alloantigen specific) or Brown Norway (BN)(RT1(n), third party) splenocytes for 72 hours. Ex vivo alloantigen-specific CD4(+)CD25(-) T-cell proliferation responses were assessed with fresh and stimulated CD4(+)CD25(+) Treg cells. RESULTS: Freshly isolated, donor alloantigen-stimulated and third-party alloantigen- stimulated CD4(+)CD25(+) Treg cells suppressed antigen-specific CD4(+)CD25(-) T-cell proliferation ex vivo, and adoptive transfusion of these 3 kinds of CD4(+)CD25(+) Treg cells prolonged survival of the liver allografts. The group transfused with the donor alloantigen-stimulated CD4(+)CD25(+) Treg cells had the greatest mean survival among the 3 groups (fresh Treg cells, 21 +/- 2 days, n = 6; third-party alloantigen-stimulated Treg cells, 20 +/- 2 days, n = 6; donor alloantigen-stimulated Treg cells, 30 +/- 2 days, n = 6). When combined with short-term tacrolimus administration, adoptive transfusion of donor antigen-stimulated Treg cells induced the greatest survival time in recipients (greater than 60 days; n = 6). CONCLUSION: Adoptive transfusion of ex vivo donor alloantigen-stimulated CD4(+)CD25(+) Treg cells combined with short-term tacrolimus treatment may represent a new strategy for preventing rejection after liver transplantation.     

Induction of carbon monoxide in donor animals prior to organ procurement reduces graft immunogenicity and inhibits chronic allograft dysfunction

BACKGROUND: Nonspecific inflammatory damages occurring prior to organ transplantation reduce long-term graft survival. Here, we tested the beneficial effects of carbon monoxide (CO) induction by methylene chloride (MC). METHODS: Fischer-344 (F-344 Rat) or Dark Agouti (DA Rat) donor animals were either treated with MC four hours prior to organ removal or remained untreated. Kidneys were transplanted into Lewis (LEW) recipients. The low responder strain combination (F-344-->LEW) was studied for long-term graft changes. Dendritic cells (DCs) migration and early changes were followed in additional groups of a high responding donor/recipient strain combination (DA-->LEW). Native kidneys of uninephrectomized, age-matched normal animals served as controls. RESULTS: Following MC application COHb peaked within two hours in donor animals. Renal function and morphology improved significantly in renal allografts of CO induced donor animals and were comparable to native controls long-term (24 wks). Early after transplantation (24 hr) donor-derived DCs, CD4+ T-cells and alloreactive T-cells were significantly reduced following the engraftment of organs from treated donors. In addition, a trend towards a Th1/Th2 shift and a significant intragraft reduction of CD3 mRNA expression was observed. CONCLUSION: Donor treatment for the induction of CO reduced graft immunogenicity and inhibited chronic allograft nephropathy.     

Alloreactive T suppressor cells in the rat. I. Evidence of three distinct subsets of splenic suppressor T cells resistant to cyclosporine

In this study we examined the effect of cyclosporine on three distinct subsets of T suppressor (Ts) cells identified in a rat renal allograft model. Ts inducer (Ts1) cells having the CD4 marker are found in the spleens of DA rats undergoing acute rejection of LEW kidneys. Transducer (Ts2) and effector (Ts3) cells both carry the CD8 marker and are found in the spleens of long-term surviving DA rats bearing LEW kidney allografts made tolerant by donor-specific blood transfusions or by cyclosporine (in most cases). These latter cells are distinguished by their susceptibility to cyclophosphamide (CY), Ts2 cells being resistant while Ts3 cells are sensitive to CY. When Ts cells from DA rats undergoing acute graft rejection of LEW kidneys or bearing long-term-surviving LEW kidneys that had been treated with cyclosporine (10mg/kg/day) for 2 or 10 days, respectively, were adoptively transferred into lightly irradiated DA recipients, these cells were still able to specifically induce long-term survival of LEW kidneys. LEW kidney survival was not prolonged in DA rats given no cells or cells from rats treated with cyclosporine for 10 days. Thus it would appear that the three functional subsets of Ts cells demonstrated in this renal allograft model by adoptive transfer of spleen lymphocytes are not inhibited by cyclosporine, suggesting that this resistance of Ts cells to cyclosporine may be partly responsible for the immunosuppressive effect of this agent.     

Mechanism of the immunosuppressive effect in vivo of novel immunosuppressive drug beta-SQAG9, which inhibits the response of the CD62L+ T-cell subset

INTRODUCTION: We synthesized sulfo-glycolipid, beta-SQAG9 (designate square beta-SQAG9 liposome, because it efficiently forms a liposome structure) that possessed immunosuppressive effects such as inhibition of T-cell responses in human allogeneic MLR and skin allograft survival in rats, and bound to CD62L (L-selectin) in vitro. In this study, we further investigated the immunosuppressive mechanism in vivo by beta-SQAG9 liposome in a skin-allografted rat model. METHODS: ACI rats (RT1(a)) were grafted skin of LEW rats (RT1(1)) treated with PBS or beta-SQAG9 liposome IV once a day for 7 days. Subsequently, we investigated the population of T cells and CD62L(+) T-cell subset in the spleen, axillary lymph nodes (ALNs), and peripheral blood of skin-allografted rats by two-color flow cytometry. RESULTS: Five of 11 (45.5%) rats that were treated with 50 mg/kg beta-SQAG9 liposome showed graft survival and another showed moderate rejection in graft. The CD62L(+) T-cell subset population in ALNs of beta-SQAG9 liposome-treated rats decreased in a dose-dependent manner. No significant difference in the T-cell population was observed between the beta-SQAG9 and control groups. These data suggest that beta-SQAG9 could bind to the CD62L(+) T-cell subset in vivo as well as in vitro and affect T-cell migration, which might lead to T-cell tolerance in vivo.     

Donor hematopoietic progenitor cells in nonmyeloablated rat recipients of allogeneic bone marrow and liver grafts

BACKGROUND: Although the persistence of multilineage microchimerism in recipients of long-surviving organ transplants implies engraftment of migratory pluripotent donor stem cells, the ultimate localization in the recipient of these cells has not been determined in any species. METHODS: Progenitor cells were demonstrated in the bone marrow and nonparenchymal liver cells of naive rats and in Brown Norway (BN) recipients of Lewis (LEW) allografts by semiquantitative colony-forming unit in culture (CFU-C) assays. The LEW allografts of bone marrow cells (BMC) (2.5x10(8)), orthotopic livers, or heterotopic hearts (abdominal site) were transplanted under a 2-week course of daily tacrolimus, with additional single doses on days 20 and 27. Donor CFU-C colonies were distinguished from recipient colonies in the allografts and recipient bone marrow with a donor-specific MHC class II monoclonal antibody. The proportions of donor and recipient colonies were estimated from a standard curve created by LEW and BN bone marrow mixtures of known concentrations. RESULTS: After the BMC infusions, 5-10% of the CFU-C in the bone marrow of BN recipients were of the LEW phenotype at 14, 30, and 60 days after transplantation. At 100 days, however, donor CFU-C could no longer be found at this site. The pattern of LEW CFU-C in the bone marrow of BN liver recipients up to 60 days was similar to that in recipients of 2.5x10(8) BMC, although the donor colonies were only 1/20 to 1/200 as numerous. This was expected, because the progenitor cells in the passenger leukocytes of a single liver are equivalent to those in 1-5x10(6) BMC. Using a liquid CFU-C assay, donor progenitor cells were demonstrated among the nonparenchymal cells of liver allografts up to 100 days. In contrast, after heart transplantation, donor CFU-C could not be identified in the recipient bone marrow, even at 14 days. CONCLUSION: effective immunosuppression, allogeneic hematopoietic progenitors compete effectively with host cells for initial engraftment in the bone marrow of noncytoablated recipients, but disappear from this location between 60 and 100 days after transplantation, coincident with the shift of donor leukocyte chimerism from the lymphoid to the nonlymphoid compartment that we previously have observed in this model. It is possible that the syngeneic parenchymal environment of the liver allografts constitutes a privileged site for persistent progenitor donor cells.     

Heart and spleen "twin grafts" in rats: IV. Influence of donor spleen cell mass on allograft survival

Heart and spleen twin grafts from LEW to ACI rats may survive permanently, whereas those grafted from ACI to LEW rats do not. This strain difference in graft acceptance was analyzed quantitatively by transplanting one to three ACI spleens into LEW rats in order to compensate for the relatively small size of ACI spleens (Fig. 1). Under these conditions permanent graft survival was not observed in LEW recipients. However, during host splenectomy 3 days after transplantation, a nonimmunological factor was observed. The transplanted ACI spleens showed congestion and infarctions, while in the LEW to ACI transplant model the LEW spleens did not. This observation could be explained by the size of the vascular pedicle in ACI spleens. Although no problem was encountered immediately after completing the anastomoses, allogeneic spleens react by increasing in size, to such an extent that their size exceeds the capacity of the smaller vascular pedicle in ACI rats and results in congestion. Hence, the concept is formulated that early compromise of hemodynamics on a nonimmunological base may determine the fate of ACI spleen graft before immunological factors have a chance to become effective.     

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.