IgG alloantibody responses to donor-specific blood transfusion in different rat strain combinations as a predictor of renal allograft survival.

Donor-specific blood transfusion prolongs the survival of fully allogeneic ACI (RT1a) renal allografts in PVG (RT1c) recipients from 7-10 days to greater than 100 days. We have observed significant differences in the alloantibody (Ab1) responses to ACI renal allografts in control and DSBT-treated PVG recipients: DSBT is associated with decreased IgG and IgM alloantibody circulating in serum, deposited in the allograft, and produced in culture by splenocytes. In the present studies the effects of DSBT on alloantibody production and renal allograft survival were extended to examine other recipient strains: F344 (RT1lv1), BN (RT1n), W/F (RT1u) and LEW (RT1l). Animals of each recipient strain were injected i.v. with 0.5 ml of ACI blood alone or followed by a renal allograft. Studies on the kinetics of IgM and IgG alloantibody responses were performed by flow cytometry on lymphocytes from donor ACI, PVG, and PVG.R1 (RT1.Aa class I MHC antigen on PVG background) rats. In F344 and PVG rats, DSBT from ACI rats elicited a transient IgM response that peaked at day 7 and was not followed by a switch to IgG. In control PBS transfused F344 recipients, an ACI renal allograft stimulated both IgM and IgG alloantibody production. DSBT pretreatment significantly decreased circulating IgG alloantibody following ACI renal transplantation and prolonged graft survival in F344 recipients. In DSBT-treated F344 recipients that rejected ACI renal allografts acutely, small amounts of IgG (5-12 mode channel shift) were detected in sera harvested 7 days after transplantation, whereas almost no IgG was detected in the sera from DSBT treated F344 rats that accepted their renal allografts indefinitely. In contrast, DSBT alone from ACI to BN, W/F, or LEW strains elicited a transient IgM response that peaked at day 7 and was followed by a strong IgG response that peaked on days 10-14 and remained high through day 21. DSBT failed to prolong ACI renal allograft survival in any of these strains (survival less than 11 days in control and DSBT rats). The alloantibody response to DSBT in all five recipient strains examined was directed primarily to RT1.Aa class I MHC antigens, as determined by binding studies on lymphocytes from ACI, PVG and PVG.R1 rats and alloantibody blocking studies using biotinylated rat monoclonal antibodies to distinct epitopes of the RT1.Aa antigen. The relative magnitude of blocking of R2/10P and R2/15S binding by sera from BN, W/F, and LEW rats was: control allograft recipients greater than DSBT pretreated allograft recipients greater than DSBT alone.(ABSTRACT TRUNCATED AT 400 WORDS)     

Posttransplant infusion of donor-specific blood induces immunological unresponsiveness in rat hepatic allografts

BACKGROUND: We previously reported that pretransplant donor-specific blood transfusion (DST) induces CD45RC-CD4+ T cells, Th2-like effector cells, and prolongs rat hepatic allograft survival. Our study investigated the effects of posttransplant DST on rat hepatic allograft survival. METHODS: Three days after transplantation, LEW (RT1(1)) recipient rats with ACI (RT1a) livers were injected i.v. with freshly heparinized donor-specific blood. The time kinetics of CD45RC-CD4+ and CD45RC+CD4+ T cell subsets in hepatic infiltrates were examined. RESULTS: Posttransplant DST significantly prolonged rat hepatic allograft survival. Interferon (IFN)-gamma, interleukin (IL)-12, and IL-18 mRNA levels in hepatic allografts of untreated recipients were significantly greater than in recipients treated with posttransplant DST. However, hepatic allografts of recipients treated with posttransplant DST showed significantly higher IL-4, IL-10, and transforming growth factor (TGF)-beta mRNA levels than untreated recipients. The ratio of CD45RC-CD4+ T cells to CD45RC+CD4+ T cells was significantly higher in hepatic allografts treated with posttransplant DST than in untreated animals. Immunostaining with anti-rat dendritic cell (OX-62) monoclonal antibody revealed that OX-62+ cells were distributed to the splenic red pulp of animals treated with posttransplant DST and to the splenic white pulp in untreated animals. Most OX62+ cells isolated from the spleen of recipients treated with posttransplant DST expressed donor RT1Ba class II major histocompatibility complex antigens, suggesting that OX-62+ cells were of donor origin. CONCLUSION: Posttransplant DST was associated with persistent infiltration of CD45RC-CD4+ T cells, Th2-like effector cells, in rat hepatic allografts, causing immunologic unresponsiveness and establishment of microchimerism in the spleen.     

Induction of indirect donor-specific hyporesponsiveness by transportal RT1-peptide pulse in rat skin transplantation

In the present study, we examined whether transportal pulse of class I major histocompatibility complex (MHC) allopeptides can induce indirect (non-chimeric) donor-specific hyporesponsiveness, using a high-responder rat skin transplantation model. Two donor-specific 8-amino acid peptides corresponding to residues 58-65 and 70-77 in the alpha(1) helical region of RT1.A(a) were synthesized. In order to test immunogenicity of these peptides, mixed lymphocyte reaction (MLR) was performed. Then, 100-microg portions of peptides were injected into recipient Lewis (LEW, RT1.A(l)) rats via the portal vein 14 days before skin transplantation. Skin allografts from August Copenhagen Irish (ACI, RT1(a)) or Wistar King A (WKA, RT1(k), third-party) donors were transplanted to LEW (RT1(l)) recipients. Transportal pulse of residues 58-65 and 70-77 prolonged graft survival significantly in ACI-to-LEW skin transplantation (17.6+/-0.40 and 18.0+/-0.45 days) compared with control (14.2+/-0.37 days). However, pulse of residues 106-113, a non-donor-specific control, did not prolong graft survival time (14.6+/-0.40 days) in the same combination. Regarding the third-party donor, residues 58-65 injected into LEW recipients had no effect on survival time of skin grafts (19.0+/-0.84 days) derived from WKA donors compared with the untreated WKA-to-LEW control (19.4+/-0.93 days). Transportal pulse of RT1.A(a) peptides induced donor-specific hyporesponsiveness even in a high-responder rat skin transplantation model. Our results suggest that graft enhancement by transportal exposure to donor cells may not be induced by a chimeric process but, instead, by an indirect mechanism not involving intervention of viable donor cells.     

Requirement for both MHC and non-MHC antigens residing on the same erythrocyte for donor erythrocyte-mediated prolongation of rat renal allograft survival

Transfusions of highly purified LEW erythrocytes (E) administered to BN recipients prior to insertion of LEW kidneys markedly prolonged the survival of these allografts (greater than 35 days). Administration of E from syngeneic (BN), third-party (PVG), and MHC-congenic LEW.1N or BN.1L rats did not improve LEW kidney graft survival to the same extent (less than 14 days). BN.1L E were shown to carry at least the same quantity of LEW MHC antigens on their surface as LEW E, thus the failure to prolong LEW kidney graft survival is due to the absence of LEW non-MHC antigens from BN.1L E. Attempts to substitute for this deficiency by mixing LEW.1N E to BN.1L E prior to transfusion failed to restore the beneficial effect, demonstrating that donor E-mediated prolonged renal allograft survival requires the presence of both MHC and non-MHC alloantigens on the same E.     

Association of donor-specific blood transfusion enhancement of rat renal allografts with accelerated development of antiidiotypic antibodies and reduced alloantibody responses

Pretransplant donor-specific blood transfusion (DSBT) has been shown to enhance renal allograft survival in man and indefinitely prolong renal transplants among various MHC-disparate rat strains. Using PVG (RT1c) recipients and ACI (RT1a) donor-strain rats, DSBT alone was found to elicit complement-dependent cytotoxic IgM antibody (Ab) to donor class I (RT1.Aa) alloantigens that peaked at 7 days. An enzyme-linked immunosorbent assay was developed to measure host Ab against allospecific (idiotypic) determinants on the anti-RT1.Aa monoclonal Ab R2/10P, R2/15S, and YR1/100. Following DSBT alone, antiidiotypic Ab were detected in the circulation within 7-11 days after transfusion. Transplantation of a donor strain kidney in the presence of antiidiotypic Ab at day 7 or 11 post-DSBT resulted in enhanced graft survival and a rapid decline in circulating alloantibody, such that by days 4-6 posttransplantation little IgM or IgG alloantibody was detected. In contrast, all 6 PVG rats that were transplanted 4 days after DSBT (prior to development of detectable antiidiotypic Ab) rejected their grafts within 30 days, and 4 of 6 showed elevated alloantibody titers within 3 days posttransplantation. Control PVG rats receiving autologous blood transfusion (ABT) alone developed no alloantibody response but developed high titers of donor-specific alloantibody by 6 days posttransplantation, at the time of irreversible rejection. ABT alone did not elicit antiidiotypic Ab and ABT pretreated graft recipients developed antiidiotypic Ab only after the onset of rejection at day 4. In both DSBT and ABT groups, the antiidiotypic Ab were primarily IgM, IgG1, and IgG2c. These findings indicate that DSBT induces production of cytotoxic alloantibodies followed by an antiidiotypic Ab response at days 7-11, during which time transplanted renal allografts are not rejected and there is a reduction in circulating alloantibody. In contrast, renal allografts placed in DSBT-treated rats prior to antiidiotypic Ab development (less than or equal to 4 days) or in ABT-treated rats that do not develop any antiidiotypic Ab, elicit a rapid rise in alloantibody and are rejected.     

The transfusion effect is influenced by the nature of MHC antigen presentation

We designed a study to determine whether the mode of presentation of major histocompatibility antigens is important for the ability of donor-specific blood transfusions to prolong organ allograft survival. Donor BN rat whole blood, isolated RBC, RBC ghosts, RBC membrane fragments, or whole blood lysates were administered to Lewis rat recipients 7 days before heterotopic allotransplantation of BN hearts. Only allogeneic whole blood or RBC significantly prolonged cardiac allograft survival in this histoincompatible donor-recipient pair. Whole blood lysates or RBC ghosts and membrane fragments transfused pretransplant did not prolong cardiac allograft survival when compared with syngeneic, transfused control rats. These results suggest that the immunosuppressive effects of donor-specific pretransplant blood transfusion may depend on a three-dimensional spatial relation between cells bearing donor major histocompatibility antigens and recipient responder cells responsible for the transfusion effect.     

Variable allograft responses to pretreatment with donor splenocytes treated with mitomycin C in the rat

In an attempt to investigate the nonspecificity of the effect of administration of donor splenocytes treated with mitomycin C (MMC) 7 days before transplantation in inducing immunological unresponsiveness, the survival rates of liver, heart, small bowel, and skin allografts were compared in the RT1-incompatible ACI(RT1a) to LEW(RT1l) rat combination. ACI donor splenocytes (3 x 10(6)) treated with MMC were administered i.p. or i.v. via the penile vein 7 days before transplantation. Both routes of administration prolonged the survival of hepatic allografts (greater than 87.2 +/- 22.2 days and greater than 78.9 +/- 28.2 days, respectively), compared with controls (10.6 +/- 0.5 days). Cardiac allograft survival in untreated controls was 6.0 +/- 0.4 days. A single i.v. injection of 3 x 10(6) donor splenocytes resulted in significantly prolonged survival (10.0 +/- 4.3 days), whereas i.p. injection showed rejection at a mean of 6.0 +/- 1.2 days. A single i.p. injection of 3 x 10(6) splenocytes did not increase survival of small bowel allografts (10.3 +/- 4.8 days), compared with controls (8.8 +/- 1.8 days). On the other hand, a single i.v. injection of donor splenocytes prior to transplantation significantly prolonged survival of small bowel allografts (13.4 +/- 3.5 days). No signs of graft-versus-host reaction (GVHR) were observed during these experiments. Neither a single i.p. nor a single i.v. injection of donor splenocytes resulted in prolonged survival of ACI-to-LEW skin allografts (6.3 +/- 0.8 days and 6.6 +/- 0.9 days, respectively), compared with controls (5.7 +/- 0.5 days). Interestingly, we confirmed the relative ease with which survival of hepatic allografts can be prolonged in the rat by donor antigen treatment alone, even in a strongly rejecting RT1-incompatible rat strain combination, in contrast to other organ allografts such as heart, small intestine, and skin. The discrepancy in survival of different organ allografts following pretreatment with donor splenocytes treated with MMC may be explained by a difference in the immunogenicity of the organs transplanted or other factors.     

Evidence that pretransplant donor blood transfusion prevents rat renal allograft dysfunction but not the in situ cellular alloimmune or morphologic manifestations of rejection

The effects of preoperative donor-specific blood transfusion (DSBT) on the physiologic, morphologic, and immunologic aspects of allograft responsiveness were evaluated in a rat renal transplant model, using the ACI (RT1a) into PVG (RT1c) high-responder strain combination. Indefinite graft survival (mean greater than 63 days) could be induced by DSBT administration alone. In comparison, animals receiving autologous blood transfusion (ABT) all died within 7 days posttransplantation. As assessed by clearance of inulin and paraaminohippurate, renal allograft function in DSBT-pretreated recipients at 6 days was equivalent to that of isograft recipients, and in contrast to the significant reduction seen in ABT treated rats. Likewise, thromboxane B2 (TXB2) production by ex-vivo-perfused allografts from DSBT-treated recipients was comparable to that of isografts, and significantly lower than that of allografts from ABT-treated rats. A significant inverse correlation was found between renal TXB2 production and inulin clearance. Despite these substantial differences in renal function and eicosanoid metabolism, morphologic evaluation of renal allografts from DSBT-enhanced and ABT-rejecting recipients at comparable time points showed equivalent histologic manifestations of rejection. In addition, immunohistologic labeling of renal allograft sections and fluorescence-activated cell sorter analysis of cells eluted from allografts showed the same phenotype and pattern of infiltrating T cell subsets in both groups. Specific antidonor cytotoxic T lymphocyte precursor (pCTL) frequencies of cells eluted from kidney grafts were equivalent in DSBT and ABT-pretreated animals, and both groups expressed significantly higher (but equivalent) pCTL frequencies in the kidneys than spleens. Comparisons of the lysis of PVG.R1 (RT1.Aa on a PVG background) and ACI targets indicated that cytotoxic responses from effector cells freshly eluted from DSBT and ABT kidneys were primarily directed against allogeneic class I major histocompatibility complex (MHC) specificities, whereas several long term T cell lines generated from 6-day kidney transplants of both groups expressed a predominant W3/25+ (T helper) phenotype and cytotoxic activity against donor specificities other than RT1.Aa class I MHC. Specific antidonor proliferative T lymphocyte (pPTL) precursor frequencies of cells eluted from renal allografts were also equivalent for both DSBT- and ABT-treated recipients, and the range of pPTL frequencies for allograft cell eluates was similar to that in spleens, regardless of the source of the transfusion.(ABSTRACT TRUNCATED AT 400 WORDS)     

Initiation of rejection of established islet allografts by third-party thyroid allografts and splenic dendritic cells

Due to concerns of cross-reactivity between renal and islet allografts in initiation of rejection, we determined the ability of donor-specific and third-party splenic dendritic cells (DCs) and thyroids (whole-organ transplant) to initiate rejection of established islet allografts. Purified islets from neonatal F-344 (RT1Lv1) rats were transplanted bilaterally under the kidney capsule of Wistar-Furth (W/F, RT1u) rats without immunosuppression. The islet allografts were not rejected by 21 days posttransplantation. On day 22, freshly isolated or cultured DCs were injected intraperitoneally into the host. Both freshly isolated and cultured donor-specific (F-344) and some third-party (Buffalo, RT1b; ACI, RT1a) DCs initiated rejection of the islets as indicated by lymphocyte infiltration and destruction of the allograft. DCs, whether freshly isolated or cultured for 8 days from the recipient strain (W/F) and one third-party rat (Brown Norway, RT1n), did not initiate rejection. Splenic DCs from the Lewis (RT1l) rat, which has the same class I and II antigen haplotype as F-344 islet donor rats, also initiated rejection. Only 10(3)-10(4) DCs isolated from the spleen of donor rats were required to initiate rejection of the allograft. In a parallel series of W/F rats with islet allografts, a thyroid (half lobe) from the islet donor strain (F-344), recipient strain (W/F), or third-party rat (Buffalo, Brown Norway, or ACI) was inserted under the kidney capsule at 22 days post-islet transplantation. At 35 days, all thyroids and most islet allografts exhibited active or complete rejection after thyroid transplant from Buffalo, F-344, or ACI rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

The importance of H2 haplotype sharing in the induction of specific unresponsiveness by pretransplant blood transfusions

BACKGROUND: The beneficial effect on graft survival achieved by pretransplant blood transfusions is well established. Previous studies have shown that the degree of major histocompatibility complex (MHC) (mis)-match between the transfusion donor and the recipient plays a determining role. However, other factors are also involved. In this study, we explored the hypothesis that, in addition to sharing of MHC antigens between the transfusion donor and the recipient, the MHC type of the organ donor is also of importance. METHODS: To mimic the human situation, F1 mice, rather than inbred strains, were pretreated with haplotype-shared allogeneic whole blood transfusions and transplanted with hearts of organ donors with different matched or mismatched H2 haplotypes. RESULTS: When a heart was transplanted 1 week after donor-specific transfusion (DST; blood transfusion donor=organ donor), an excellent prolongation of graft survival was obtained (median survival time: 77 days vs. 9 days in untreated mice). However, this was only the case when a haplotype was shared with the recipient; a DST given with no match between organ donor (=BT donor) and recipient did not induce any prolongation. Furthermore, in order to obtain the optimal beneficial effect of a haplotype-shared blood transfusion, the other haplotype of the transfusion donor had to be mismatched with the recipient. The immunogenetic studies showed that haplotype-shared blood transfusions in combinations where the H2 type of the organ donor differed from that of the transfusion donor are less efficient in inducing prolongation of graft survival. CONCLUSIONS: These results demonstrate that haplotype-shared blood transfusions can induce a significantly prolonged survival of cardiac allografts in F1 mice. The immunogenetic studies suggest that presentation of alloantigen-derived peptides in the context of self MHC (the indirect pathway of allorecognition) is essential for the beneficial effect of haplotype-shared blood transfusions.     

Relative contribution of major histocompatibility complex antigens to the immunogenicity of corneal allografts

The relative contributions made by the major class I (RT1.A) and class II (RT1.B) antigens of the rat major histocompatibility complex (MHC) to the immunogenicity of corneal and skin allografts were investigated using congenic animals. PVG (RT1c) recipients were given skin or heterotopic cornea grafts from congenic PVG.1A (RT1a) or PVG.R1 (RT1r1) donors, which respectively share the entire RT1 complex or only the RT1.A (major class I MHC antigen) region with fully allogeneic ACI (RT1a) rats. Recipient splenocytes were tested at ten days posttransplant for their ability to lyse ACI, PVG.1A, PVG.R1, and PVG target cells in a secondary CML following 6 days in vitro stimulation with irradiated ACI spleen cells. Effector cells from PVG recipients of both RT1.A and B disparate (PVG.1A donor) and RT1.A disparate (PVG.R1) skin or cornea grafts lysed ACI, PVG.1A, and PVG.R1 (but not PVG) targets at levels significantly above controls given syngeneic grafts. However, the level of cytotoxicity against PVG.R1 as well as ACI and PVG.1A allogeneic targets was always significantly higher following PVG.1A grafts than following PVG.R1 grafts, indicating that the addition of a class II MHC antigen difference markedly augmented the immunogenicity of class I MHC antigen disparate cornea and skin grafts. Taken together with other recent evidence confirming the presence of Langerhans cells in the normal rat (and human) cornea, these results suggest that class II MHC-bearing cells make an important contribution to the immunogenicity of corneal allografts.     

Intrathymic injection of donor alloantigens induces donor-specific vascularized allograft tolerance without immunosuppression.

The induction of donor-specific tolerance could prevent the side effects of immunosuppression while improving allograft survival. Male adult Buffalo (RT1b) rats underwent an intrathymic (IT), portal venous (PV), intrasplenic (IS), or subcutaneous (SQ) injection of 25 x 10(6) major histocompatibility complex (MHC) mismatched Lewis (RT1(1)), UV-B-irradiated Lewis (RT1(1)), ACI (RT1a), or syngeneic Buffalo (RT1b) splenocytes. At the completion of the donor alloantigen injection, 1 mL rabbit anti-rat lymphocyte serum (ALS) was administered intraperitoneally to the Buffalo recipients, and 21 days later a heterotopic Lewis or ACI heart was transplanted. Intrathymic injection of donor alloantigen induced a donor-specific tolerance that allowed the cardiac allograft to survive indefinitely (mean survival time [MST] > 140.7 days) in 84% of the recipients without further immunosuppression, whereas groups receiving antigen injections at other sites (PV, IS, and SQ) plus ALS rejected cardiac allografts in normal fashion (MST approximately 8.0 days). Buffalo recipient rats with long-term surviving Lewis cardiac allografts after Lewis IT injection and ALS subsequently rejected a heterotopic third-party ACI cardiac allograft in normal fashion (MST approximately 7 days), whereas a second Lewis cardiac allograft was not rejected (MST > 116 days). Microchimerism is unlikely because Lewis allograft survival was also prolonged (MST > 38.7 days) in rats receiving UV-B-irradiated splenocytes IT, which cannot proliferate. Survival of Lewis renal allografts was also prolonged, but not indefinitely, in Buffalo recipients possessing a long-term surviving Lewis cardiac allograft (MST approximately 17.6 days versus 7 days for control). This model emphasizes the potential role of exposure of immature thymocytes to foreign donor alloantigens during maturation in the thymic environment for the development of unresponsiveness to an MHC-mismatched donor-specific vascularized allograft.     

The role of major and minor histocompatibility antigens in active enhancement of rat kidney allograft survival by blood transfusion

Rats given a blood transfusion do not reject a subsequent kidney allograft from the same donor strain. This effect is strain-specific so that pretransplant blood transfusion from a LEW (RT1l) rat will protect a LEW kidney in a DA (RT1a) recipient but not a PVG/c (RT1c) kidney. The same is true in other combinations. Using DA or PVG.RT1a congenic recipients we have shown that sharing of all or part of the MHC or of minor alloantigens by the blood transfusion and kidney transplant donors is sufficient to prolong allograft survival. Activation of suppression against minor alloantigens appears to require two signals: one is the minor alloantigen and the other may be a major histocompatibility complex alloantigen.     

Effects of pre- and postengraftment donor-specific transfusions and cyclosporine on the enhancement of experimental allograft survival.

The tolerogenic effects of immediate pretransplant donor-specific transfusion (DST) with cyclosporine (CsA) have been well described. The purpose of this study was to determine if these effects could be improved upon by the administration of post-transplant DSTs. When added to a 29-day course of CsA, a single DST given 24 hr pretransplant improved graft survival compared to CsA alone (84.9 +/- 12.3 vs 40.0 +/- 8.8 days; P less than 0.05). The administration of an additional DST on post-transplant Days 7, 14, and 21 further improved this survival to 152 +/- 28 days, with 45% of grafts surviving greater than 200 days, until sacrifice. The donor specificity of this effect was demonstrated by the increased survival of second ACI grafts transplanted into Lewis recipients with existing "tolerant" ACI allografts (long-term survivors, or LTS); third-party Buffalo rat hearts transplanted into LTS rats in a similar manner were rejected normally. Loss of graft antigenicity was not seen, as retransplanted ACI hearts obtained from LTS Lewis rats were rejected in a first-order manner. From this we conclude that (1) the addition of multiple post-transplant DSTs improve the enhancement seen with preoperative DST and CsA, (2) loss of graft antigenicity does not contribute to this improved enhancement, and (3) this effect appears to be donor antigen specific.     

Induction of donor-specific unresponsiveness to rat cardiac allograft by donor leukocytes and cyclosporine

Many recent reports have emphasized the importance of donor antigens in the induction of allograft tolerance. This study examines the effect of pretransplant infusion of 10(8) donor leukocytes (DL) combined with peritransplant cyclosporine (CsA) on W/F cardiac allograft survival in Lewis rats. Peritransplant recipient treatment consisted of CsA 20 mg/kg given i.m. on days 0, +1, and +2 relative to heart transplantation. Lewis recipients, 5-8 per group, were pretreated with 10(8) DL with or without peritransplant CsA. A single DL transfusion on day -3 or day -7 prior to transplantation significantly prolonged the mean survival time (MST) of W/F hearts from 7.0 +/- 0.9 days in controls to 12.2 +/- 4.5 days and 12.4 +/- 1.0 days (P less than 0.01), respectively. Two DL infusions on days -7 and -3 or on days -14 and -7 prolonged the MST to 10.6 +/- 1.3 days (P less than 0.02) and 16.4 +/- 2.8 days (P less than 0.001), respectively. The administration of peritransplant CsA alone significantly prolonged W/F heart allograft survival to 43.1 +/- 2.7 days. When pretransplant DL transfusion on day -3 was combined with CsA treatment, 4/8 animals maintained their grafts indefinitely (greater than 100 days). Similarly, DL infusion on day -7 with peritransplant CsA led to indefinite graft survival in 3/5 animals. Administration of DL on days -7 and -3 combined with CsA resulted in indefinite graft survival (greater than 100 days) in 4/6 animals. Transfusion of DL on day -3 alone or in combination with peritransplant CsA, had no effect on a third-party (ACI) heart allograft survival prolongation compared with appropriate controls. To define the underlying mechanisms responsible for donor-specific unresponsiveness in this model, pooled sera and unseparated spleen cells were passively transferred from recipients of long-term cardiac allografts to syngeneic rats receiving donor-type (W/F) or third-party (ACI) cardiac allografts. Transfer of serum (1 ml on days 0, and 1, 0.5 ml on days +2, +3, and +4) from ungrafted recipients of DL on days -14 and -7 led to significant donor graft survival of 9.8 +/- 0.4 days (P less than 0.02) in unmodified hosts. Similarly, passive transfer of serum obtained at 20 and 100 days after transplantation significantly prolonged the MST of donor-type hearts in syngeneic untreated hosts to 11.3 +/- 0.8 and 10.0 +/- 1.1 days, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Humoral immunity to heterotopic corneal allografts in the rat

Despite indications that humoral immune responses may be involved in corneal allograft rejection, few definitive reports of such responses exist, and the antigens responsible for evoking and targeting these responses remain unknown. We report the development of donor-specific humoral immunity in PVG (RT1c) rats given fully allogeneic ACI (RT1a) corneal grafts heterotopically. PVG anti-ACI cornea serum lysed ACI, but not PVG, target cells in complement-dependent cytotoxic assays. Target cells from PVG.1A or PVG.R1 congenic rats, which respectively share the entire rat major histocompatibility complex (MHC) region (i.e., RT1) or only class I MHC antigens (RT1.A region) with ACI (on PVG backgrounds) were also lysed by this serum. Lysis of PVG.1A targets was significantly more extensive than lysis of PVG.R1 cells, indicating that both RT1.A and non-RT1.A antigens act as targets for cell lysis. Levels of PVG.1A and ACI target lysis were equivalent, suggesting that minor transplantation antigens were not significantly involved in this humoral response.     

The role of passenger leukocyte genotype in rejection and acceptance of rat liver allografts

BACKGROUND: Although graft-resident passenger leukocytes are known to mediate acute rejection by triggering direct allorecognition, they may also act in an immunomodulatory fashion and play an important role in tolerance induction. Our purpose in the current study was to utilize rat bone marrow chimeras to evaluate the role of the genotype of passenger leukocytes in both acute rejection and tolerance of liver allografts. METHODS: The fate of livers bearing donor-type, recipient-type, and third-party passenger leukocytes was evaluated in the MHC class I and II mismatched rejector combination ACI-->LEW and the acceptor combination PVG-->DA. RESULTS: We report that although treatment of ACI liver donors with lethal irradiation does not lead to prolongation of graft survival in the ACI-->LEW strain combination, ACI livers bearing recipient-type (LEW) or third-party passenger leukocytes (BN) are rejected at a significantly slower rate. We confirm that lethal irradiation of PVG donor animals leads to abrogation of tolerance induction with acute rejection of their livers by DA recipients. However, the majority of PVG livers carrying donor-type (PVG), recipient-type (DA), or third-party (LEW) passenger leukocytes are accepted for >100 days. These DA recipients develop immune tolerance to the donor parenchyma (PVG). CONCLUSIONS: Our findings demonstrate that long-term acceptance of liver allografts and tolerance induction is not dependent on the presence of donor-type passenger leukocytes and can be achieved with organs carrying donor-type, recipient-type, or third-party passenger leukocytes. The importance of the MHC framework on the surface of passenger leukocytes as a critical regulator of the immune response after transplantation of chimeric organs is substantiated by the delayed tempo of rejection of ACI livers bearing recipient-type or third-party passenger leukocytes in the ACI-->LEW strain combination.     

IgM and IgG alloantibody production by splenocytes and deposition in rat renal allografts are decreased by donor-specific blood transfusion

Untreated PVG (RT1c) rats reject ACI (RT1a) renal grafts in 6-8 days. Autologous (PVG) blood transfusions (ABT) do not alter ACI allograft rejection, but donor-specific blood transfusions (DSBT) 7 or 11 days prior to transplantation usually results in indefinite graft survival. We have reported previously that DSBT is associated with the development of antiidiotypic antibody and reduced circulating cytotoxic alloantibodies in this model. To further define the effects of DSBT on the alloantibody responses to renal allografts, we examined PVG rats that received DSBT or ABT prior to ACI renal transplantation. Antibody production by cells in the spleen was investigated by tissue culture techniques; circulating antibody titers were measured by antibody binding to target ACI lymphoblasts with flow cytometry; and antibodies bound to the ACI allograft were recovered by hypertonic acid elution and quantitated by flow cytometry and ELISA. Seven days after DSBT alone, circulating IgM alloantibodies to ACI reached peak titers. After renal allografting, serum IgM alloantibody titers decreased in DSBT-pretreated rats and little IgG could be detected. In contrast, renal allografts in ABT-pretreated rats elicited high titers of IgM and moderate titers of IgG in the circulation by 5-7 days posttransplantation. Spleens harvested one week posttransplantation from ABT-pretreated rats produced high titers (16-32) of IgM and IgG antibodies to ACI antigens, but no such antibody production was detected in spleens cultured from DSBT-pretreated rats. In addition, 4-32-fold more IgM and IgG was eluted from kidneys removed 6-7 days after grafting to ABT-treated rats than from allografts in DSBT-treated rats. IgG2a was the predominant subclass of IgG that bound to target ACI cells. No IgA was detected in graft eluates from any rat. Polyacrylamide gel electrophoresis demonstrated that the eluates contained predominantly IgM and IgG without significant contamination by other serum proteins. These data suggest that DSBT decreases the levels of IgM and IgG normally produced in the spleen and deposited in the graft following renal transplantation. Because IgM fixes complement and IgG (especially IgG2a) triggers ADCC, the reduced deposition of IgM and IgG in the graft may be of particular importance in DSBT enhancement.     

The effects of donor-specific blood transfusion enhancement of rat renal allografts on host NK cell responses.

Donor-specific blood transfusion (DSBT) given 1-2 weeks prior to transplantation prolongs the survival of fully allogeneic ACI (RT1a) renal allografts in PVG (RT1c) recipients from 6-8 days to greater than 100 days. We have previously demonstrated that ACI kidneys transplanted to autologous blood transfusion (ABT)- or DSBT-pretreated PVG recipients stimulated an increase in CD8+ (OX8+) cells in the peripheral blood by 6 days after transplantation. To determine whether this increase represents a general expansion of the entire CD8+ population or only a subpopulation of CD8+ cells, subset analysis was performed on peripheral blood lymphocytes depleted of cells reactive with monoclonal antibodies against rat alpha beta T cell receptor (TCR), CD8, or NK cells (R7.3, OX8, or 3.2.3, respectively). Phenotypic studies of PBL depleted of CD8+ cells demonstrated that all 3.2.3+ NK cells coexpressed CD8; depletion of 3.2.3+ PBL revealed a second subpopulation of CD8+3.2.3- cells comprised predominantly of alpha beta TCR+ T cells. In naive PVG rats the prevalence of these two CD8+ subpopulations was approximately equal. Both ABT- and DSBT-pretreated renal allograft recipients demonstrated a significant and equivalent expansion of the CD8+ cell subpopulation that coexpresses the 3.2.3 NK marker. In contrast, the second subpopulation of CD8+3.2.3- cells did not change significantly after allografting. There were also no differences between DSBT and ABT pretreated rats in activity of PBL against the NK targets YAC-1 and Doxie at 6 days after renal transplantation, though the level of activity was modestly increased compared with naive controls. These findings indicate that renal transplantation in the rat is associated with a significant increase in PBL with the NK phenotype (CD8+3.2.3+) and a modest increase of NK activity, but that DSBT enhancement does not affect this NK cell response.     

15AU81, a prostacyclin analog, enhances donor-specific hepatocytes to prolong the survival of rat heart but not small bowel allografts

Prostacyclin analogs have previously been shown to have not only cytoprotective but also independent immunosuppressive effects. The effect of one such analog, 15AU81, to enhance the immunosuppressive effects of liver was investigated. We have previously demonstrated that cyclosporine (CsA) in conjunction with rapamycin (RAPA) potentiates class I+, class II- donor-specific hepatocytes to prolong rat cardiac and small bowel allograft survival. Brown Norway (BN; RT1n) hepatocytes alone (5 x 10(7)/kg, administered intrasplenically) failed to prolong the survival of BN heart allografts in Wistar Furth (WFu; RT1u) recipients, beyond that of untreated controls (MST = 7.2 +/- 0.8 days). Survival of BN hearts was increased to 11.4 +/- 1.7 days in WFu recipients treated with BN hepatocytes and 50 microg/kg/day 15AU81 administered by continuous s.c. infusion for 14 days using osmotic pumps (p < 0.05). The further addition of RAPA 0.0075 mg/kg/day and CsA 0.375 mg/kg/day delivered for 14 days by continuous i.v. infusion (CIVI) using osmotic pumps (a combination that alone prolonged BN heart allografts in WFu hosts to 18.4 +/- 1.3 days and in conjunction with BN hepatocytes prolonged survival to 27.2 +/- 1.9 days) prolonged allograft survival to 35.2 +/- 5.2 days. In contrast, the survival of small bowel allografts was not enhanced by 15AU81 administration. Survival of BN small bowel transplants in LEW recipients treated with hepatocytes alone (MST = 11.6 +/- 1.5 days) or hepatocytes plus 15AU81 (MST = 10.0 +/- 1.0 days) was similar to controls (MST = 10.2 +/- 1.9 days). Treatment with hepatocytes and RAPA/CsA increased survival to 21.2 +/- 1.5 days. The further addition of 15AU81 failed to augment this (MST = 17.0 +/- 1.9 days). In vitro WFu lymphocyte proliferative responses from animals pretreated with BN hepatocytes, 15AU81, or both treatments, for 2 weeks prior to harvesting, exhibited a reduction of at least 50%, compared to untreated controls upon allostimulation with irradiated BN or ACI spleen cells. These findings demonstrate that 15AU81 interacts favorably with hepatocytes either alone or in conjunction with RAPA and CsA to enhance their immunosuppressive effects on rat heart allograft survival. The failure to enhance small bowel allograft survival may be explained by the inability at this low dosage of 15AU81 to influence the intense graft versus host reaction elicited by small bowel transplants.