Spontaneous long-term acceptance of RT-1-incompatible liver allografts in inbred rats. Analysis of the immune status

In several combinations of inbred rats, liver allografts are spontaneously tolerated, and after a few weeks liver tolerant rats are in a state of donor-specific transplantation tolerance. In vivo and in vitro experiments were conducted to analyze the immunological status of LEW or BN rats with spontaneously tolerated (LEW X BN) F1 liver allografts several months after transplantation. Acute rejection of secondary donor-specific heart allografts retransplanted from liver-tolerant rats to normal syngeneic hosts suggests that the state of tolerance in liver-tolerant rats is related to an active modification of the immune system of the rat and not to a reduced immunogenicity of the graft. No cytotoxic antibodies or cells were found in liver-tolerant rats. Reactivity in mixed lymphocyte culture was normal or slightly reduced. Arguments for the presence of splenic suppressor cells were found in LEW tolerant rats using a local graft-versus-host assay, but these could not be found in BN rats, or when attempting to transfer or to break the tolerance state. A nonspecific humoral blocking factor was found in vitro in liver-tolerant rats but transfer of serum from liver-tolerant rats to normal syngeneic hosts did not permit a significant prolongation of donor-specific heart allografts. These results suggest that more than one mechanism may be involved at the maintenance phase of liver allograft tolerance.     

Specific unresponsiveness to fully allogeneic kidney allografts in rats induced by procarbazine hydrochloride and antilymphocyte serum

A short course of procarbazine hydrochloride (PCH; 50 mg/kg) and antilymphocyte serum (ALS; 5 ml/kg), administered to Lewis (LEW;RT1(1] rats in the first week following transplantation of Brown Norway (BN;RT1n) kidneys, substantially prolonged allograft survival and induced long-term survival in 62% of the grafts. The two agents acted synergistically, in that neither of them administered alone had much effect. Graft recipients did not produce detectable cytotoxic antibodies and antigen-reactive cells injected i.v. were not diverted to the liver, thus showing that neither antibodies nor immune complexes are likely to mediate the unresponsiveness. Spleen cells from graft-bearing recipients failed to cause graft-versus-host responses (GVHR) in both (LEW X BN)F1 and (LEW X DA)F1 hybrids, but they specifically suppressed the GVHR given by normal syngeneic cells to donor strain (BN) antigens. This suppression was specific because the response against third-party antigens (DA; RT1a) was unaffected. Adoptive transfer of spleen and thymus cells from PCH-ALS-treated LEW rats bearing healthy BN kidneys caused a profound prolongation of BN graft survival in sublethally irradiated LEW recipients. This transfer was specific and mediated by W3/13+ (T) lymphocytes. It is concluded that a limited regimen of PCH and ALS given in the first postoperative week incites the generation of specific suppressor T lymphocytes and that this form of immunosuppression, even without preoperative donor antigen, is an effective way of prolonging kidney allograft survival.     

Development of donor-specific immunoregulatory T-cells after local CTLA4Ig gene transfer to pancreatic allograft

BACKGROUND: CTLA4Ig gene transfer directly to graft tissue might have the potential to avoid the need for systemic immunosuppression. In our previous studies of bio-breeding (BB) rats, local adenovirus-mediated CTLA4Ig gene transfer protected the pancreas from autoimmune and alloimmune responses. This study investigated the potency of local CD28/B7 costimulatory blockade for induction of donor-specific tolerance and further examined the existing mechanisms. METHODS: Brown Norway (BN; RT1)-pancreaticoduodenal grafts transfected with Ad.CTLA4Ig via intraarterial ex vivo perfusion were transplanted into streptozotocin-induced diabetic Lewis (LEW; RT1) rats. RESULTS: Ad.CTLA4Ig transduced grafts combined with a short course of FK506 resulted in indefinitely prolonged survival (>156 days vs. 19.5 days with FK506 alone). CTLA4Ig was predominantly expressed in grafts on day 4. The expression was gradually diminished and was only slightly detectable at day >100. The proliferative responses against BN antigen were remarkably enhanced among recipients with rejected grafts, but the T-cells from tolerant recipients (>100 days) showed poor cytotoxic responses. On adoptive transfer assay, the splenic T-cells of tolerant recipients were able to suppress the rejection of BN, but not third-party Wistar Furth (WF; RT1) hearts in irradiated (480 cGy) LEW recipients. The percentage of CD4CD25 splenic T-cells was significantly increased in tolerant recipients (13.53 +/- 4.06% vs. 6.06 +/- 0.56% in naive rats). CONCLUSION: CTLA4Ig gene transfer to the pancreaticoduodenal allograft combined with a short course of FK506 induces donor-specific tolerance. The mechanism of maintaining tolerance could be explained by development of splenic T suppressor cells.     

Suppression of antibody response and prolongation of skin graft survival by multiple blood transfusions in the rat

The effect of blood transfusions (BT) on antibody response and skin graft survival was studied in the strongly MHC-incompatible BN and LEW combination. One-to-three BT induced high titer antibodies. Additional BT, however, led to a decrease of antibody titers. After 15 BT the recipients either had no detectable antibodies, or they had very low antibody titers. This suppression of response was shown to be distinct from a simple loss of antibody activity caused by lack of further antigenic challenge. In multiple transfused rats, humoral nonreactivity persisted in spite of rechallenge with antigen; in animals that lost their antibodies as a result of lack of further stimulation, an additional BT boosted strong antibody production. In LEW recipients of multiple BN transfusions, not only the specific anti-BN response but also reactivity to third-party BUF blood was suppressed. However, whereas the donor-specific response (anti-BN) was largely inhibited after a ten-week interval, the response to third-party BUF blood recovered. The state of humoral nonreactivity could be transferred by spleen cells to nontransfused syngeneic animals. In LEW rats that received three injections of 5 X 10(7) "suppressor" spleen cells, the antibody response to BN blood was strongly impaired as compared with animals that received normal spleen cells. BN or (BN X LEW)F1 skin grafts survived significantly better in multiple transfused LEW rats than in nontransfused controls. This was even more pronounced when ALS was given additionally. Third-party grafts (BUF) survived only slightly better than controls. It is concluded that multiple BT (1) result in humoral anti-donor nonreactivity secondary to an initial antibody response, (2) induce strong specific and weak nonspecific suppressor cell activity, and (3) increase skin graft survival.     

Synergistic effect of donor-specific blood transfusion and a short course of deoxyspergualin in rat kidney transplantation

Deoxyspergualin (DSG), an analogue of spergualin produced by B. laterosporus, has a strong immunosuppressive effect in various transplantation models. We have investigated the mechanism of donor-specific prolongation of survival time in rat kidney grafting by donor-specific blood transfusion (DST) and a short course of DSG. Lewis (LEW) kidney allografts were transplanted into fully allogeneic BN rats. Fresh, whole LEW blood 1.0 ml, was injected i.v. into BN rats 2 days prior to transplantation. Then, DSG, 6 mg/kg per day, was administered by i.m. injection on days 0, 1, and 2 after transplantation. The recipients were divided into five groups: group 1 (n=6) no treatment: group 2 (n=6) DST only; group 3 (n=7) DSG only; group 4 (n=7) DST and DSG; and group 5 (n=6), third party (ACI rats) blood transfusion and DSG. Lymphocytes (cervical lymph nodes) and serum were harvested from BN recipients on day 7 postgrafting. For suppressor cell assays, lymphocytes from BN recipients in each group were added as a third cell to the mixed lymphocyte reaction (MLC) between nontransplanted BN lymphocytes (responder) and LEW or other third party (PVGC, ACI, WKA rats) lymphocytes (stimulator). Antidonor lymphocytotoxic antibody (ADLA) was checked by microcytotoxicity assays. Median survival times (MST) for each group were: group 1, 10 days; group 1, 10 days; group 3, 13 days; group 4, 75 days; and group 5, 13 days. Remarkable prolongation of MST was only noted in group 4. In the suppressor cell assay, group 4 showed significant suppression (40%; P<0.05); the other groups did not show any suppression. This suppressive activity in group 4 was effective only during the MLC between BN and LEW, not during the MLC of third party-BN combinations. Thus, suppressor cells from DST/DSG-treated BN recipients appear to be donor-specific. In the microcytotoxicity assay, the only group that showed any ADLA was group 2, which was not treated with DSG. These results clearly show that both induction of donor-specific suppressor cells and inhibition of ADLA production are associated with the remarkable donor-specific prolongation of kidney allograft survival in DST/DSG-treated recipients.     

Effects of portal venous administration with allogenic cells on renal allograft survival in the rat

The effects of administration of donor lymphocytes via portal vein (PV) on capacity of alloreactivity and renal allograft survival were investigated in comparison with those of intra-venous (IV) administration in the rats. Orthotopic renal transplantations were performed from Brown-Norway (BN, RT-In) to Lewis (LEW, RT-11) male rats. Donor lymphocytes were prepared from BN or third party DA(RT-1a) rat spleens and lymph nodes and injected via PV or IV to LEW rats on the day of transplantation (day 0). Untreated LEW hosts rejected BN grafts at 7.8 +/- 0.6 days (n = 10). IV administration of 1 x 10(8) BN cells to LEW rats caused a slight prolongation of BN graft survival to 10.4 +/- 3.1 days (n = 9, p less than 0.05), whereas PV inoculation of the same number of BN cells further prolonged graft survival to 28.9 +/- 9.2 days (n = 9, p less than 0.01). This effect was antigen specific; the administration of 1 x 10(8) third party DA cells via PV to LEW rats did not prolong survival of BN graft (MST = 7.4 +/- 0.8, n = 6). Serum from tolerant recipients had significant antigen specific suppressor effect (70.6%) on the MLR proliferative reaction of LEW responder cells toward donor BN cells, but not third party DA cells. Spleen cells from these recipients did not show any suppressive effect. These results demonstrate that PV administration of donor lymphoid cells to recipients results in rapidly inducible and long-lasting immunologic tolerance specific to donor alloantigen, and that this tolerance is mediated by serum factor induced in hosts, but not by suppressor cells.     

Cyclosporin A spares selectively lymphocytes with donor-specific suppressor characteristics

The effect of cyclosporin A (Cy A) on the host responses to heart allografts have been examined in rats following administration of the drug for 7 days after grafting. All grafts functioned greater than 100 days without rejection episodes in animals of major histocompatibility differences. Thymic or splenic lymphocytes (1 X 10(8) from LEW recipients of (LEW X BN)F1 hearts were transferred at varying periods into untreated LEW rats transplanted with (LEW X BN)F1 test hearts 24 hr later. Test grafts survived 12 to 16 days significantly (P less than 0.001) longer than in untreated animals (MST +/- SD = 7 +/- 0.3 days). Cells from normal LEW animals, Cy A-treated but ungrafted, and grafted but not treated animals, all failed to prolong test graft survival. Specificity of the effect was tested in vivo, using hearts from donor and third-party rats, and in vitro, using the mixed lymphocyte response (MLR). In vivo, thymocytes from treated LEW recipients of (LEW X WF)F1 grafts failed to prolong (LEW X BN)F1 test grafts; conversely, transferred thymocytes from LEW recipients of LEW X BN)F1 grafts failed to prolong (LEW X WF)F1 grafts. The MLR of lymphocytes from Cy A-treated rats was significantly decreased against donor lymphocytes but not against third-party lymphocytes. Additionally, both cellular and humoral immunity mounted by Cy A-treated recipients was depressed throughout the entire follow-up period. Prolonged heart graft survival after 7 days of Cy A treatment suggests emergence of cells with specific suppressor activity, which in turn may cause profound abrogation of host effector responses against vascularized organ allografts.     

Suppressed alloreactivity and mixed chimerism in rats with accepted cardiac allografts by intrathymic injection of donor bone marrow cells

Intrathymic injection of donor bone marrow cells (ITBMCs) at the time of transplantation and treatment with antilymphocyte serum (ALS) permitted the indefinite survival of Brown Norway (BN, RT1ⁿ) rat heart grafts in 6 out of 8 Lewis (LEW, RT1^l) rat recipients. LEW recipients with long-surviving BN heart grafts (LSGs) also accepted additional BN heart grafts without further immunosuppression, though they rejected Piebald Virol Glaxo (PVG, RT1^c) rat heart grafts in the usual fashion. In the in vitro study, the proliferative response of the lymphocytes from LEW recipients with LSGs remained suppressed when they were stimulated by BN spleen cells, but not when stimulated by PVG cells. Bone marrow cells (BMCs) from LEW rats with LSGs showed strong, nonspecific, suppressive effects on the proliferative response in the mixed lymphocyte culture reaction, suggesting that one of the possible explanations for tolerance might be the involvement of a suppressor mechanism. Received: 7 August 1996 Received after revision: 12 February 1997 Accepted: 17 February 1997     

Role of antibody in rat renal allograft rejection. II. Failure to enhance renal allografts by sensitization to donor class I antigens presented by donor strain erythrocytes

BN rats were immunized with one or three doses of 1 X 10(8) highly purified LEW erythrocytes (LEW-E) yielding IgM antibody (IgM-BN rats) and IgG antibody (IgG-BN rats) to LEW class I antigens, respectively. LEW kidneys transplanted into IgM-BN rats elicited cytotoxic T cell responses and lymphocytotoxic antibody responses comparable to those elicited by LEW renal grafts in unmodified BN rats. However, LEW kidneys were rejected by IgM-BN hosts in a slightly delayed fashion compared with controls (mean rejection times (MRTs), 9.4 versus 7.1 days); delayed rejection was associated with the absence of anti-LEW IgG hemagglutinins from the recipients' blood and the absence of vasculonecrotic lesions from rejected renal grafts. LEW kidneys inserted into IgG-BN rats were rejected in a slightly accelerated fashion compared with controls (MRT, 6.6 days). Lymphocytotoxins developed in IgG-BN recipients of LEW kidneys in a fashion similar to that of controls, but cytotoxic T cell responses were delayed up to the 6th day after transplantation. These observations confirm our previous finding that cytotoxic T cells do not play a decisive role in acute rejection in this model. The association observed between delayed or accelerated rejection of LEW kidneys by BN rats sensitized with LEW-E and the absence or presence of anti-donor IgG hemagglutinins in the blood of these recipients after transplantation suggests an important role for IgG anti-donor class I antibodies in the rejection of LEW renal allografts by BN rats.     

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.     

The effects of perioperative administration of donor lymphocytes via portal vein in rat skin transplant model]

The effects of perioperative portal venous (P.V.) administration of donor lymphocytes on skin allograft survival were investigated in rat skin transplant model. Heterotopic skin transplantations were performed form Brown-Norway (BN, RT-1n) to Lewis (LEW, RT-1(1] male rats. P.V. administration of donor BN lymphocytes (1 x 10(8] resulted in significant prolongation of BN skin graft survival (MST = 13.4 +/- 3.9 days, p less than 0.05) compared with I.V. administration of same number of donor lymphocytes (8.6 +/- 1.2 days) or with PV administration of third party DA (RT-1a) rat's lymphocytes (7.4 +/- 0.8 days) or with untreated controls (9.0 +/- 1.4 days). These results suggested that this effect was antigen specific. P.V. administration of donor lymphocytes prevented recipient which received BN skin graft form developing delayed-type hypersensitivity responses to donor antigen. Serum from LEW recipients which induced unresponsiveness by PV administration with donor BN lymphocytes had significant antigen specific suppressor effect (77.0 +/- 5%) on the MLR proliferative reaction of LEW responder cells toward donor BN cells, but not third party DA stimulation. Moreover, this immunological unresponsiveness was transferable by the serum in kidney transplant model. These results indicate that PV administration of donor lymphocytes induces recipient's unresponsiveness to donor alloantigen in rat skin transplant model, and this effect is transferable by the suppressor factor in the serum.     

Ex vivo and systemic transfer of adenovirus-mediated CTLA4Ig gene combined with a short course of FK506 therapy prolongs islet graft survival

Adenovirus-mediated CTLA4Ig gene transfer has been reported to enhance graft survival in several rodent transplantation models. In this study, we investigated the efficacy of ex vivo and systemic transfer of the CTLA4Ig gene by adenoviral vectors in pancreatic islet allo-transplantation. Islet grafts from BN rats were transplanted to chemically induced diabetic LEW rats. First, ex vivo CTLA4Ig gene transfer into isolated islets was performed prior to transplantation. Survival of transduced grafts under the kidney capsule was slightly prolonged (8.6+/-1.3 days) compared with survival of untransduced grafts (6.7+/-1.2 days); when combined with a short course of FK506, graft survival was further extended (32.6+/-10.7 days vs. 13.7+/-1.0 days with FK506 alone). Secondly, systemic gene transfer was accomplished by intravenous administration immediately after the transplantation procedure. In these animals, islet grafts under the kidney capsule survived longer (15.2+/-3.3 days) than in controls (6.7+/-1.2 days), and when FK506 was administered perioperatively, all the islet grafts survived for more than 100 days. In systemically transduced recipients, the survival of islet grafts transplanted into the liver was not significantly different from that of the grafts placed under the kidney capsule. In order to examine organ-specific immunogenicity, heterotopic BN cardiac grafts were transplanted to LEW rats intra-abdominally, with the virus transferred systemically as in the islet model. In contrast to the islet grafts, all the cardiac grafts were accepted for longer than 100 days, even without FK506 therapy. Finally, the LEW recipients with long-surviving islet or cardiac grafts were re-transplanted with islet grafts from the same donor strain (BN) on day 100. The second islet grafts survived longer than 100 days in half of the cardiac recipients, but consistently failed in the islet recipients. We conclude that in this transplant model, CTLA4Ig gene transfer and FK506 treatment synergistically improved islet graft survival, systemic transfer of the gene was more effective than ex vivo transfer to the islets, and donor-specific tolerance could not be achieved for islet transplantation but was achieved for cardiac transplantation.     

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.     

Prolongation of cardiac allograft survival by selective injection of donor liver leukocytes in non-immunosuppressed rats

Liver grafts are spontaneously accepted in several animal combinations and are able to induce acceptance of another organ originating from the same donor, which would be rejected when transplanted alone. However, the exact mechanism of this unique tolerance induction capability remains unclear. The aim of our study was to investigate the ability of nonparenchymal liver cells to induce tolerance when they were separated from their parenchymal environment. In the murine combination we used (BN --> LEW), heart transplants were constantly tolerated after combined liver plus heart grafting, but rejected when transplanted alone. Nonparenchymal liver cells were isolated from BN rat livers by enzymatic digestion and injected, at different times, to LEW rats, which were recipients of BN heart transplants. The average number of mononuclear cells obtained after isolation was 20 x 10(6)/5 g of rat liver. Immediate trypan-blue exclusion test showed more than 95% of viable cells. Phenotypic studies showed a predominant (47%) lymphocyte population, 7% were monocytes and 46% were cellular debris. Among the lymphocyte population, the majority of cells were bearing the NKR-P1 receptor and about 30% CD3 receptors. Inoculation of nonparenchymal liver cells 7 and 30 days prior to heart transplantation significantly prolonged graft survival compared to controls (14.6 and 12.7 vs. 8.1 days; p = 0.0008 and 0.0059, respectively), whereas simultaneous injection (day 0) had no effect. Injection of donor splenocytes or nonparenchymal liver cells from a third party, at any time, had no effect on rejection. These results provide some more evidence about the specific role of liver lymphocytes in allogenic unresponsiveness. They also suggest that the hepatic parenchymal environment is necessary for the optimal development of this phenomenon.     

Enforcement of specific unresponsiveness by the long-term presence of allogeneic heart grafts

Mechanisms underlying the maintenance of long-term heart allografts were analyzed in rats treated with Cyclosporine. It was shown that acceptance of allografts after cyclosporine did not involve the attenuation of immunogenicity of the grafts. This conclusion was drawn from two observations: (1) Pretreatment of the donors with cyclosporine did not cause prolongation of graft survival time; and (2) cyclosporine stabilized allografts were normally rejected by secondary recipients when retransplanted on day 30. Studies of the acceptance of skin grafts from the heart donor strain indicated the existence of a mechanism to maintain donor-specific unresponsiveness in the presence of a stable allograft in a time-dependent manner. Thus, the mean rejection time of F344 skin grafts on WKA rats bearing F344 hearts was more than 80 days when transplanted on day 210, but it was 32 days when they were transplanted on day 30. Active participation of specific suppressor cells in the maintenance of unresponsiveness was suggested because data obtained in the cell transfer experiments was statistically significant. Transfer of lymphocytes from rats bearing long-term grafts showed a tendency to delay rejection of skin grafts by sublethally irradiated hosts, but it failed to delay the rapid rejection by normal lymphocytes cotransferred to the same recipients.     

Long-term survival of cardiac allografts in lethally irradiated rats repopulated with host-type hemopoietic cells.

To test the hypothesis that hemopoietic cells within a tissue graft are responsible for its immunogenicity, two experimental protocols were followed. LEW hearts were grafted into (LEW X BN)F-1 host rats and LEW or F-1 lymphocytes were injected into the apex of the grafted heart. The LEW but not the F-1 cells induced a local reaction, apparently because the circulating F-1 cells were the necessary immunogens. The second protocol took advantage of the knowledge that lethally irradiated LEW rats were able to reject WF Ag-B-incompatible hemopoietic cells (but not tissue allografts) within a few days. LEW rats were lethally irradiated and grafted with WF hearts on day 0. A mixture of LEW marrow, thymus, spleen and lymph node cells, or marrow cells only were infused either on day 0 or day 2. Cardiac allografts in hosts repopulated with the mixture of lymphoid cells survived a mean of 11.3 days in hosts infused on day 0, but survived indefinitely if the lymphoid cells were infused on day 2. The 2-day interval also prolonged the survival of allografts in rats infused with only marrow cells. The long-term recipients, without any further treatment, rejected WF skin grafts as first-set reactions 1 year later but did not reject second WF cardiac allografts. Lymphoid cells from long-term recipients imparied the rejection of WF cardiac allografts by LEW host rats. The lack of rejection of the original cardiac allograft supported the hypothesis tested. Certain hemopoietic cells responsible for the immunogenicity of cardiac allografts were probably eliminated in the 2-day interval at least in part by host effector cells capable of rejecting allogeneic hemopoietic cells. However, the mechanism of long-term "unresponsiveness" to WF hearts could have been caused by loss of accessory cells during the 2-day interval followed by infusion of immunocompetent cells. Skin rejections in these recipients may have been attributable to reactions against skin differentiation-specific antigens.     

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.     

Examination of the mechanisms responsible for tolerance induction after intrathymic inoculation of allogeneic bone marrow.

OBJECTIVE: This study examined the immunologic mechanism(s) responsible for the induction of transplantation tolerance in rats pretreated with intrathymic inoculation of donor strain bone marrow. SUMMARY BACKGROUND DATA: Induction of unresponsiveness may involve deletion and/or inactivation of donor-reactive T-cell precursors maturing in a thymus harboring donor alloantigen or generation of regulatory/suppressor cells. It was reasoned that, if unresponsiveness is caused by deletion of alloreactive clones, the presence of additional thymic tissue devoid of donor alloantigen permits normal maturation of T-cells and, thus, prevents induction of tolerance. However, if unresponsiveness were primarily mediated by regulatory/suppressor cells, the presence of noninoculated thymic tissue should not affect the induction of tolerance. METHODS: Three strategies were used to define the cellular basis of cardiac and islet allograft survival in WF recipients of intrathymic LEW donor bone marrow as follows: (1) inoculation of bone marrow either into the native thymus and/or into an ectopic thymus, (2) limiting dilution analyses of the frequency of precursor cytotoxic T-lymphocytes (CTLp), and (3) adoptive transfer to syngeneic secondary hosts. RESULTS: Inoculation of bone marrow into only one lobe of the native thymus and/or into an ectopic thymus did not promote consistent survival of subsequent LEW cardiac allografts. Tolerant hosts displayed significant reductions in CTLp frequencies against donor alloantigens. Adoptive transfer of spleen cells from tolerant WF hosts harboring long-standing cardiac allografts led to permanent survival of LEW cardiac allografts in all secondary recipients. However, transfer of spleen cells from WF animals that received intrathymic LEW bone marrow (but no cardiac allograft) did not promote survival of LEW cardiac allografts in naive secondary hosts. CONCLUSIONS: These results indicate that the unresponsive state after intrathymic inoculation of bone marrow cells is primarily mediated by deletion and/or inactivation of donor-specific T-cell precursors maturing in a chimeric thymus. The demonstration by adoptive transfer studies of putative regulatory/suppressor cells suggested an important role for the persistence of donor alloantigen (supplied by a vascularized allograft) in the maintenance of the unresponsive state.     

The role of class I major histocompatibility complex antigens in prolonging the survival of hepatic allografts in the rat

In an attempt to study the role of class I major histocompatibility complex antigens in inducing immunological unresponsiveness, the survival rates of hepatic allografts were compared in rats pretreated with blood taken from various rat strains. A single intravenous injection of 1 ml fresh heparinized whole blood seven days before transplantation significantly prolonged the survival of subsequent donor-specific hepatic allografts in the fully allogeneic ACI(RT1a)-to-LEW(RT1l) rat combination. However, pretreatment with blood taken from the third-party strain BN(RT1n) did not produce suppression of rejection, attesting to the specificity of the pretransplant transfusion effect. Interestingly, pretransplant transfusion of PVG.r1 blood, sharing only the RT1.A MHC region with ACI, significantly prolonged the survival of ACI-to-LEW hepatic allografts. In addition, no lymphocytotoxic antibodies could be detected at 30 or 100 days after transplantation in animals with long-surviving hepatic allografts pretreated with either PVG.r1 or ACI whole blood. On the other hand, pretreatment with PVG(RT1c) blood increased the survival of ACI-to-LEW hepatic allografts only moderately compared with controls. This finding may be consistent with a partial effect of some third-party blood transfusion. The experimental data suggest that the class I MHC antigens can be immunosuppressive in rat hepatic allografts. Adoptive transfer of 5 x 10(7) splenocytes taken from long-term-surviving hepatic allografts pretreated with donor ACI whole blood or PVG.r1 blood into irradiated (750 rads) LEW rats prolonged the survival of donor-type skin grafts, whereas third-party strain (BN) grafts were rejected. This finding suggests the presence of donor-specific suppressor cells.     

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.