The role of T suppressor cells in the maintenance of spontaneously accepted orthotopic rat liver allografts.

Orthotopic liver allografts from BN donors to LEW recipients are spontaneously accepted, and the recipients develop donor-specific immunological unresponsiveness. This unresponsiveness may be mediated by suppressor T cells. Immunomagnetically purified splenic T cells from LEW rats bearing BN liver grafts were shown to adoptively transfer suppression of skin, heart, and kidney graft rejection in a donor-specific manner, prolonging the survival of BN but not third-party DA grafts. However, the suppressor T cells were sessile, being resident in the spleen but not present in thoracic duct lymph. The presence of a nonrecirculating suppressor T cell in rats spontaneously accepting liver transplants is strongly suggestive of an important function in the maintenance of donor-specific unresponsiveness, although the contribution of other possible mechanisms of unresponsiveness has not been investigated.     

Regulatory cells develop after the spontaneous acceptance of rat liver allografts

BACKGROUND: After donor-specific transfusion, tolerance to heart transplants is serially passed to naive rats by the adoptive transfer of long-term survivor (LTS)-tolerant splenocytes (SC). We examined whether regulatory cells similarly develop after the spontaneously accepted Lewis (LEW) to Dark Agouti (DA) liver transplants. METHODS: SC from a LTS DA rat with a LEW liver were adoptively transferred to a naive DA 1 day before transplantation of an irradiated (1000 rad) LEW liver. RESULTS: Untreated LEW to DA liver allografts were uniformly accepted; whereas all irradiated LEW liver grafts were rejected. In contrast, when 1.5 x 10 8 DA LTS SC were transferred to a naive DA recipient, all irradiated LEW liver grafts were accepted. When decreased to 1.0 x 10 8 LTS DA SC, only 1 of 4 irradiated LEW grafts was accepted. However, if 1.5 x 10 8 DA SC harvested only 30 days after liver transplantation were transferred, only 2 of 5 irradiated LEW liver grafts were accepted. The serial second and third adoptive transfers of 1.5 x 10 8 DA LTS SC also resulted in the uniform acceptance of irradiated LEW livers. CONCLUSION: Regulatory cells that develop after the spontaneous acceptance of a LEW to DA liver transplant can serially transfer tolerance to new naive LEW liver allograft DA recipients. This "infectious tolerance" is dependent on the time of cell harvest after transplantation and on the cell dose given.     

The effects of perioperative portal venous inoculation with donor lymphocytes on renal allograft survival in the rat. I. Specific prolongation of donor grafts and suppressor factor in the serum

In order to investigate the in vivo functional role of the liver in the immune responses in organ transplantation, effects of perioperative portal venous p.v. administration of donor lymphocytes on renal allograft survival were tested in the rat kidney transplant model. Donor lymphocytes were prepared from BN (BN, RT-1n) or third-party DA (RT1a) rat spleens and lymph nodes and injected p.v. or intravenously to Lewis (LEW, RT-1l) hosts on the day of transplantation (day 0). Untreated LEW hosts rejected BN renal grafts at 7.8 +/- 0.6 days (n = 10). Intravenous administration of 1 x 10(8) BN cells to LEW hosts on day 0 caused a slight, but not significant, prolongation of renal allograft survival (MST = 9.5 +/- 3.0 days, n = 13, NS), whereas portal venous inoculation of 1 x 10(8) BN cells on day 0 remarkably prolonged renal graft survival to 22.2 +/- 5.3 (n = 10, P less than 0.01). The prolongation of graft survival was antigen-specific; the administration of 1 x 10(8) DA cells p.v. to LEW hosts did not prolong the survival of BN renal grafts (MST = 7.4 +/- 0.8, n = 5). Spleen cells from p.v. treated LEW hosts 10 days after transplantation had no suppressor effect on the one-way MLC reaction of normal LEW responder cells toward donor BN or third-party DA stimulators. On the other hand, when serum from p.v.-treated LEW hosts was added to MLC at a concentration of 3 per cent of total volume, it suppressed the MLC reaction toward donor BN cells by 71.6 per cent, but not toward third-party DA stimulators (-8.5 per cent suppression, NS). Histological examination of p.v.-treated LEW hosts at 10 days after transplantation revealed that the liver had normal lobular architecture without expansion of portal tracts and infiltration of inflammatory cells. On the other hand, the transplanted kidney demonstrated a moderate mononuclear cell infiltration around the artery without an interstitial hemorrhage. Moreover, adoptive transfer of the serum from p.v.-treated LEW rats into the virgin secondary LEW hosts significantly prolonged the graft survival of BN kidneys from 7.8 days to 18.9 +/- 5.5 days (P less than 0.01), but not third-party DA graft survivals (MST = 7.5 +/- 0.6 days), indicating that an antigen-specific tolerogenic factor was released into the circulation through the process of allogeneic cells in the liver.     

The persistence of regulatory cells developing after rat spontaneous liver acceptance

BACKGROUND: We have previously reported that the spontaneous acceptance of Lewis (LEW, RT1(l)) to Dark Agouti (DA, RT1(a)) rat orthotopic liver transplant (OLT) is eliminated by donor gamma-irradiation. The acceptance of the irradiated LEW liver is also reestablished in a na?ve rat after the adoptive transfer of T regulatory (T-reg) cells from a LEW to a DA liver-tolerant long-term (>60 days) survivor (LTS) into a na?ve DA rat. However, little is known about the growth conditions required to maintain T-reg function. In this study, we examined the need for continued donor-specific alloantigen stimulation for the maintenance and function of T-reg cells. METHODS: Splenocytes (SCs; 1.5 x 10(8) cells) from a LEW liver allograft-tolerant LTS DA recipient were adoptively transferred fresh or after in vitro stimulation into another naive DA rat on day 1, 4, or 7 before an irradiated (1000R) LEW liver transplant. For in vitro alloantigen stimulation, SCs from LEW to DA LTS were co-cultured with mitomycin-C (MMC)-treated na?ve LEW (donor alloantigen-specific) or Brown Norway (BN) (RT1(n); third party) SCs for 72 hours. Graft rejection, as defined by death of the recipient, was confirmed histologically. RESULTS: All LEW liver grafts were accepted spontaneously by DA recipients for more than 60 days (n=32), while all irradiated LEW livers were acutely rejected (n=9; mean survival time [MST]=12.8 +/- 4.0 days). When LTS DA SCs were adoptively transferred into a naive DA rat 1 day before OLT, all irradiated LEW grafts were accepted greater than 60 days (n=9). However, when fresh LTS DA SCs were transferred to a new na?ve DA rat on 4 or 7 days before OLT, all irradiated LEW liver grafts were acutely rejected (MST=10.2 +/- 0.5 days [n=4] and MST=13.5 +/- 5.0 days [n=4], respectively). When LTS DA SCs were stimulated in vitro before adoptive transfer, irradiated LEW liver grafts after 4 days (n=5) were then accepted. In vitro culture of LTS DA SCs with MMC-treated BN SCs (third-party) for 72 hours before adoptive transfer resulted in 3 of 5 irradiated LEW livers at day 4 being accepted (n=5). CONCLUSIONS: The maintenance of T-reg function requires continuous LEW donor-specific alloantigen stimulation.     

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.     

The extent of immunological privilege of orthotopic corneal grafts in the inbred rat

Corneal grafts are believed to enjoy a degree of "immunological privilege" primarily due to the avascularity of the recipient bed. In this study orthotopic full-thickness corneal grafts were carried out in the inbred rat, using a technique that is a close model of corneal grafting in humans. The survival times of corneal grafts on nonvascularized beds of 28 fully allogeneic strain combinations were determined without the use of immunosuppression. Some combinations were rejected rapidly, e.g. DA (RT1a) into BN (RT1n) with a mean survival time (MST) +/- SD of 7.8 +/- 1.3 days, and some at a moderate rate, e.g. AO (RT1u) into LEW (RT1l) with an MST of 23.1 +/- 10.0 days, whereas in other cases survival was indefinite, e.g. WAG (RT1u) into PVG (RT1c), an MST of greater than 100 days. Orthotopic corneal grafts on nonvascularized beds between DA and AO parents and the F1, followed the basic rules of transplantation genetics. In addition, the rate of graft rejection was significantly faster (P less than 0.001) with corneal grafts from DA into AO placed onto a vascularized compared with a nonvascularized corneal bed (MST of 6.8 +/- 2.4 or 12.1 +/- 4.0 days respectively). The rate of rejection of corneas on a vascularized bed was at a similar rate to that of orthotopic skin or heterotopic auxiliary heart grafts. The results indicate that the fate of a corneal allograft on a nonvascularized bed is dependent upon the particular combination of donor and recipient strain. No consistent association was observed between any donor or recipient RT1 haplotype and survival; this suggests that non-RT1 background genes may play a role in the survival of corneal grafts.     

Infectious tolerance develops after intrathymic alloantigen-induced acceptance of rat heart allografts can be adoptively transferred

BACKGROUND: We have shown that intrathymic (IT) injection of alloantigen with antirat lymphocyte serum (ALS) treatment can induce donor-specific allograft acceptance. The purpose of this study was to investigate whether T-regulatory (T-reg) cells play a role in the maintenance of donor-specific heart graft tolerance that develops after IT injection of Lewis (LEW, RT1(l)) alloantigen into a Dark Agouti (DA, RT1(a)). METHODS: Na?ve DA rats were injected IT with 2.5 x10(7) LEW donor splenocytes and injected intraperitoneally with 1 mL ALS. Twenty-one days after pretreatment, a LEW or Brown Norway (BN, RT1(n)) heart was transplanted into a treated DA recipient. Splenocytes (1 x 10(8) or 5 x 10(7)) from a LEW heart-tolerant long-term survivor (LTS; >60 days) DA recipient were harvested and adoptively transferred (AT) into an irradiated (450 rad) na?ve DA rat 24 hours before transplanting a LEW heart. RESULTS: All LEW heart allografts were rejected by untreated DA rats in a mean survival time (MST) of 7.4 +/- 1.7 days (n=7). In contrast, 66.7% of LEW heart grafts into IT+ALS-pretreated DA recipients were accepted indefinitely (n=24). When either 1 x 10(8) (n=5) or 5 x 10(7) (n=5) splenocytes from a LEW heart graft-tolerant LTS (>60 days) DA recipient were AT into a new na?ve DA rat, all new LEW heart grafts were accepted indefinitely. CONCLUSIONS: The donor-specific tolerance that develops after IT+ALS-induced LEW heart acceptance by DA recipients can be transferred adoptively to new na?ve DA recipients, thus indicating that it is infectious tolerance.     

Intragraft delivery of 16, 16-dimethyl PGE2 induces donor-specific tolerance in rat cardiac allograft recipients

The stable prostaglandin E2 analogue, 16,16-dimethyl PGE2 (di-M-PGE2) was continuously infused by osmotic pump directly into rat heterotopic cardiac allografts. Intragraft delivery of 20 micrograms/kg/day di-M-PGE2 for 2 weeks completely prevented graft rejection for more than 150 days (n = 10), while untreated Buffalo recipients rejected Lewis cardiac allografts within 8 days after transplantation (mean survival time = 7.4 +/- 0.5 days, n = 5). When given for only 1 week, 20 micrograms/kg/day had a partial effect, since 60% of recipients accepted grafts long-term and 40% experienced rejection by day 14 (n = 5). In contrast, systemic intravenous administration of 20 micrograms/kg/day di-M-PGE2 for 2 weeks could not prolong graft survival (MST = 7.0 +/- 0.0 days, n = 3), and the higher dose of 200 micrograms/kg/day resulted in death by day 2 (n = 5). Long-term BUF recipients of LEW cardiac allografts accepted LEW donor strain skin grafts for more than 35 days while rejecting third-party Wistar Furth skin grafts in a normal fashion (MST = 7.3 +/- 0.5 days, n = 3), indicating the induction of donor-specific tolerance. Long-surviving LEW cardiac allografts retransplanted into naive BUF recipients were rejected within 7 days (MST = 6.7 +/- 0.5 days, n = 3), indicating no change in graft immunogenicity. Therefore, a 14-day infusion of di-M-PGE2 directly into a strongly MHC-mismatched cardiac allograft uniformly has resulted in long-term engraftment and the development of recipient donor-specific tolerance.     

Detection of serum-blocking factors by inhibition of allorosette formation in rats with long-surviving renal allografts following short-term postoperative ALS treatment.

Thirty-nine (LEW x BN)F1 kidneys were transplanted to LEW rats. Twenty-four untreated recipients survived for a mean time of 16.1 +/- 1.7 days (group 1). Fifteen recipients received 4 ml of antilymphocytic serum per rat (group 3). In the last group 10 recipients survived for more than 4 months. The spleen cells of these permanently surviving 10 rats were obtained by splenectomy and used in a graft-versus-host assay, and this assay showed that the reactivity of these cells was normal. Following splenectomy the animals were given an (LEW x BN)F1 skin allograft, followed 18 days by a second. After another 18 days (LEW x Buf)F1 "third party" skin allografts were transplanted to the same animals. Animals of group 2 rejected their first grafts with a mean survival time of 12.2 +/- 1.2 days, whereas the second grafts were rejected normally as were the third party grafts. Attempts were made to detect lymphocytotoxic antibodies and haemagglutinins before and after the transplantation of skin grafts and none could be found up to day 53. The sera of group 2 inhibited allorosette formation by 38%. This serum-blocking factor was donor specific. It is probable that the survival of the kidney transplants following antilymphocytic serum treatment was brought about by the development of blocking antibodies.     

Cyclosporine and experimental skin allografts. II. Indefinite survival and development of specific immunologic unresponsiveness

Immunological unresponsiveness toward skin allografts was studied in cyclosporine (CsA)-treated rats. BN skin grafts survive about 22 days and about 34 days in LEW hosts following 7 or 14 days of daily CsA treatment (15 mg/kg/day), respectively; in unmodified hosts grafts are rejected by 9 days. Indefinite (greater than 100 days) survival can, however, be produced by administering maintenance 15 mg/kg CsA every fourth day, following an initial course of the agent for 14 days. Early signs of graft rejection (hair loss, localized epidermal breakdown, and ulcerations) occurring in some animals were reversed by a CsA "pulse" (15 mg/kg/day) for 7 days, reduced gradually to the maintenance dose. CsA was equally effective when started as late as 4 days after grafting, but ineffectual when started after day 4. Once BN grafts were rejected, the agent could not prevent second-set rejection of donor-specific grafts, but significantly prolonged the survival of third-party (WF) skins. Survival of original BN grafts was unchanged by the placement of second BN grafts during both the inductive and maintenance phases; these second grafts survived as long as the original grafts. In contrast, secondary third-party (WF) grafts were promptly rejected; their destruction did not influence survival of the original grafts. Thus, indefinite survival of rat skin allografts is feasible with low maintenance doses of CsA. Graft rejection at later stages can be reversed by resuming daily therapy. Host unresponsiveness is stable and specific both during the early inductive and later maintenance phases.     

Indefinite survival of rat islet allografts following infusion of donor bone marrow without cytoablation

We have tested the effect of donor bone marrow cell (DBMC) infusion on the survival of pancreatic islet allografts in the rat, without the use of cytoablative recipient conditioning. Lewis and diabetic Brown Norway rats were used as donors and recipients, respectively. Donor islets were placed beneath the left renal capsule. Infusion of DBMC and temporary immunosuppression followed by delayed islet transplantation resulted in indefinite survival of all islet grafts (MST >180 days). Control animals demonstrated recurrent hyperglycemia (islet allografts rejection). Donor bone marrow derived cells were detected in the spleen and cervical lymph nodes of BN recipients of LEW bone marrow but not in the recipients of islet transplants alone. Second set full thickness skin grafts were performed in normal BN and in recipients of a previously successful ITX. Donor specific skin grafts were accepted in the animals that had received DBMC 40 days before the islet allograft, while animals receiving DBMC at the time of the islet allograft rejected the donor specific skin graft similarly to the controls. However, these animals did not reject a second set donor-specific islet transplant. The results indicate that radiation conditioning of the recipients was not necessary to induce microchimerism and graft acceptance in this rodent model of islet allotransplantation.     

The use of spleen transplantation and cyclosporine treatment to induce unresponsiveness to pancreatic islet transplantation in rats

One way of achieving permanent survival of allografted islets in the rat has been to first transplant a kidney of the same strain as the islets and induce acceptance of the kidney using cyclosporin A treatment. Rats bearing long-surviving renal allografts will then accept islets of the same strain without further immunosuppression. Such an approach may be effective for combined renal and islet grafting, but transplantation of the kidney as well as islets may not always be desirable, and the question arises as to whether another organ could be used to achieve the same effect. Auxiliary spleen transplants were performed from LEW to DA rats, followed by cyclosporine 10 mg/kg for 14 days. Twelve rats with long-surviving grafts were then made diabetic with streptozotocin and given LEW islets placed under the kidney capsule, 6 rats being given a further course of cyclosporine 10 mg/kg for 7 days after islet transplantation. Rats that did not reject their islets then underwent removal of the spleen transplant, and if this did not result in rejection islet function was proven by removal of the kidney bearing the islets. The results show that spleen allograft rejection can be prevented by cyclosporine treatment and that 50% of animals with long-surviving spleen allografts will accept subsequent islet allografts from rats of the same donor strain. The acceptance of islet allografts can be increased to 100% by a further short course of cyclosporine treatment. It is concluded that spleen allografts can be used to produce unresponsiveness to islets in rats.     

Immunological unresponsiveness in chimeric miniature swine following MHC-mismatched spleen transplantation

BACKGROUND: In rodents, spleen allotransplantation (SpTx) induces tolerance. We investigated the induction of chimerism and donor-specific unresponsiveness following pig SpTx. METHODS: Thirteen pigs underwent splenectomy (day 0); all received a blood transfusion. In 11/13 pigs, SpTx was performed across a MHC class I (n=1) or full (n=10) barrier; two control pigs received no SpTx. All pigs were monitored for chimerism, and anti-donor immune responses, including suppressor assays. Four pigs (two asplenic controls and two with SpTx) underwent delayed donor-matched kidney transplantation without immunosuppression. RESULTS: Six of the 11 spleen grafts were lost from rejection (n=5) or splenic vein thrombosis (n=1), and five remained viable. All 11 SpTx recipients developed multilineage chimerism, but chimerism was rapidly lost if the graft failed. Two control pigs showed <6% blood chimerism for 4 and 11 days only. Pigs with functioning spleen grafts had multilineage chimerism in blood, thymus and bone marrow for at least 2-6 months, without graft-versus-host disease. These pigs developed in vitro donor-specific hyporesponsiveness and suppression. In 2 pigs tolerant to the spleen graft, donor MHC-matched kidney grafts survived for >4 and >7 months in the absence of exogenous immunosuppression; in two asplenic pigs, kidney grafts were rejected on days 4 and 15. CONCLUSIONS: Successful SpTx can result in hematopoietic cell engraftment and in vitro donor-specific unresponsiveness, enabling prolonged survival of subsequent donor-matched kidney grafts without immunosuppression.     

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)     

Mediation of antigen-induced suppression of renal allograft rejection by a CD4 (W3/25+) T cell

The mechanism of induction of specific immunosuppression by preoperative donor-specific blood transfusion in the rodent remains unclear. In a previous study we demonstrated that a single LEW blood transfusion in a DA rat results in the generation of donor-specific suppressor cells in the lymph node and thoracic duct lymph, detectable both in vivo and in vitro 7 days after DST. In contrast, no such activity was found in the splenic compartment. In this study lymphoid cells were harvested from either untreated DA rats or DA rats transfused 7 days previously with LEW blood and purified by rosette depletion using appropriate monoclonal antibodies. The purified lymphocyte subpopulation from transfused rats, of splenic or TDL origin, was adoptively transferred into syngeneic, lightly irradiated (200 rads) DA rats, where the adoptive transfer of 4.25 x 10(7) T (OX12-negative) cells (98.9% pure) or 2.5 x 10(7) CD4 (i.e., W3/25-positive, OX8 and OX12-negative) cells (97.9% pure), both of TDL origin, resulted in the indefinite survival of a LEW kidney (median survival time [MST]greater than 100 days), but not a PVG kidney (MST = 11 days). In contrast lymphocytes of splenic origin, regardless of the phenotype, did not prolong graft survival. Thus we have phenotypically characterized a CD4 (W3/25+) T suppressor cell that is generated after a single DST and is detectable 7 days later in the TDL but not the splenic compartment. Although there was no significant difference in the lymphocyte subset composition of lymphoid organs from transfused and untreated hosts, as determined by flow cytometry, the mean channel fluorescence of the lymphocyte population markers of cells harvested from transfused animals was significantly less than that observed with untreated controls, a finding which remains unexplained.     

Induction of donor-specific tolerance in rat hind-limb allografts under antilymphocyte serum and cyclosporine A protocol

Composite tissue allograft (CTA) transplantation became a clinical reality despite major side effects associated with the administration of chronic immunosuppression. Development of new treatment modalities eliminating life-long immunosuppression is essential for the future of CTA transplantation. In this study, combined use of cyclosporine A (CsA) and antilymphocyte serum (ALS) was tested for the potential to induce tolerance in the rat hind-limb allograft recipients across a major histocompatibility (MHC) barrier (Lewis-Brown-Norway [LBN, RT1(l+n)] to Lewis [LEW, RT1(l)] rats). Thirty transplantations were performed in 5 experimental groups. Animals received CsA and ALS 12 hours before surgery for 21 days thereafter. Although the allograft controls rejected their limbs at day 7 combined treatment of CsA and ALS resulted in indefinite survival (over 420 d) in all allograft recipients. Long-term survivors showed 35% to 42% of donor-specific chimerism in the peripheral blood. Clinical tolerance was confirmed by acceptance of the donor-specific skin grafts and immunocompetence was confirmed by rejection of the third-party grafts. Mixed lymphocyte reaction revealed suppressed response against donor-type antigens and increased response to third-party antigens. Donor-specific tolerance across MHC barrier was induced in CTA allografts under 21 days protocol of ALS/CsA.     

Lack of correlation between the induction of donor class I and class II major histocompatibility complex antigens and graft rejection

The induction of donor major histocompatibility complex (MHC) antigens on nonrejected and rejected rat renal allografts was compared at various times after transplantation in two strain combinations, DA-to-PVG and LEW-to-DA. Graft rejection was prevented by preoperative donor-specific blood transfusion (DST). Quantitative absorption analysis and immunohistology were performed using monoclonal antibodies specific for donor class I and class II MHC antigens. A significant increase in the expression of donor MHC antigens, both class I and class II, was demonstrated on nonrejected as well as rejected kidneys after transplantation. A kinetic analysis showed that induction of donor class I antigens was accelerated on the nonrejected grafts, and by day 5 the nonrejected kidneys showed increased expression of class I antigen when compared with the rejected grafts (a 37- vs. a 25-fold increase in expression). Increased expression of donor class I antigens persisted on the nonrejected grafts and was still detectable on long-term-surviving kidneys, 50 days after transplantation. The magnitude of class II antigen induction was similar on both rejected and nonrejected grafts (8-fold by 5 days after transplantation). Immunohistology demonstrated that class I and class II antigens were induced on identical structures in the kidney in both situations. In particular the vessel endothelia, which do not express class II antigens in normal kidney, become strongly positive in both rejected and nonrejected grafts 5 days after transplantation. Although renal allograft rejection is completely suppressed in rats given a single donor-specific blood transfusion before transplantation, graft survival cannot be explained by the lack of induction of donor MHC antigens. Donor MHC antigens are induced on these nonrejected kidney grafts, and therefore they could act as target molecules for the effector cells that mediate graft destruction. Thus the induction of donor MHC antigens on tissue allografts should not be considered as indicative of a rejection response resulting in graft destruction.     

Humoral presensitization in rat heart allotransplantation

In these experiments an attempt was made to create a rat model of the past-positive, current-negative lymphocyte crossmatch (PPCNCx) phenomenon currently of concern in clinical renal transplantation. Lewis rats were sensitized with three to four serial ACI heart fragment (HF) or skin grafts. Subsequent ACI heart graft survival in the presence of high titer LEW-anti-ACI antibody was markedly shortened with 4 of 10 surviving for 24 hr or less in HF-sensitized rats and 11 of 11 surviving less than 24 hr following skin graft sensitization. Thirteen sensitized LEW rats were transplanted with ACI hearts 18 months later when their anti-ACI antibody was nil. Control rats (N = 5) had graft survival of 4.4 +/- 0.6 days; cyclosporine (CsA) therapy prolonged this to 8.0 +/- 3.6 days (N = 4), while combined cyclosporine and cyclophosphamide (Cy) resulted in an MST of 4.3 +/- 0.4 (N = 3). LEW-anti-ACI antibody was present on Day 3 or 4 in the control rats but was absent at the time of rejection in the CsA-Cy treated rats. Adoptive transfer of splenocytes from sensitized LEW rats into naive LEW hosts produced animals with humoral immune memory but no anti-ACI antibody at the time of transplantation. Nonimmunosuppressed adoptively transferred LEW recipients of ACI hearts rejected their grafts in an accelerated fashion (MST of 4.5 +/- 0.5 days) and displayed an anamnestic antibody production with first appearance on Day 3 or 4. Immunosuppression with CsA or Cy prolonged graft survival (greater than 30 days) in all cases and Cy prevented an anamnestic humoral response.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Prolongation of renal allograft survival in the rat treated with amniotic fluid.

To assess the role of amniotic fluid (AMF) in the maintenance of pregnancy, immunosuppressive effects of AMF were studied in vivo, and the mechanisms of suppressor activity were analyzed immunologically in vitro in the rat. Female Lewis (LEW, RT-1l) rats mated with Brown-Norway (BN, RT-1n) rats for 14 days were sacrificed and cell-free AMF was obtained. AMF was diafiltered with PBS (PH 7.2) and reconstituted to 2 OD units measured at 280 nm. Untreated LEW hosts rejected BN renal grafts at 7.8 +/- 0.2 days (n = 10). Five days of intravenous inoculation of AMF into LEW hosts remarkably enhanced BN graft survivals (MST = 20.3 +/- 4.4 days, n = 12) compared with controls (P less than 0.01), and slightly prolonged third-party DA (RT-1a) graft survivals (MST = 9.4 +/- 0.8 days, n = 7) compared with control LEW hosts engrafted with a DA kidney (MST = 7.6 +/- 0.2 days, n = 6). Five days of intravenous inoculation of pregnant sera into LEW hosts had no effect on BN graft survival. The AMF suppressed the proliferative response of LEW lymphocytes against not only irradiated BN stimulator cells but also irradiated third-party DA stimulators. The AMF also suppressed allokiller T cell generation of normal LEW lymphocytes against BN cells by 70.1% and 51.3%, and against DA cells by 64.9% and 38.9% at concentrations of 25% and 12.5%, respectively (P less than 0.01). To dissect the immunosuppressive activity of AMF, the effect of AMF on cytokine production and interleukin 2 (IL-2) receptor expression of concanavalin A-stimulated lymphocytes were investigated. AMF suppressed interferon and IL-2 production. Interestingly, however, AMF did not suppress interleukin 3 (IL-3) and interleukin 6 (IL-6) production, as well as IL-2 receptor expression. These results demonstrated that rat AMF displayed a strong immunosuppression in vivo as well as in vitro, and that AMF might play an important role in the maintenance of pregnancy.