Elimination of acute GVHD and prolongation of rat pancreas allograft survival with DST cyclosporine, and spleen transplantation

Allogeneic spleen transplantation has been shown to have a tolerizing effect on pancreas allograft survival in rats. In this study we examined the effect of blood transfusions and cyclosporine administration on both rat pancreas allograft survival and acute graft-versus-host disease in BN recipients of Lewis pancreas-spleen allografts. We found that in this strain combination significant pancreas allograft prolongation occurred when the spleen was included en bloc with the pancreas graft. However, 50% of these recipients developed GVHD and died. A single donor-specific transfusion delivered to BN recipients of Lewis pancreas and pancreas-spleen allografts did not extend graft survival, but precluded the development of GVHD. A short, 6-day, and long, 26-day, course of CsA to recipients of pancreas and pancreas-spleen allografts extended graft and animal survival times, although not indefinitely. All pancreas-spleen recipients of both CsA protocols died following acute GVHD. Combined DST and CsA (short and long-course) administration in pancreas-only allograft recipients was deleterious to graft survival, compared with CsA administration alone. However, in pancreas-spleen recipients, combined DST and CsA had an additive effect. Moreover, in DST and long-course CsA-treated pancreas-spleen recipients, indefinite graft survival occurred with no signs of acute GVHD. The beneficial effect of the spleen allograft on pancreas graft survival was not dependent upon GVHD, since splenic-induced prolongation of pancreas graft survival was observed in the F1-donor to parent-recipient combination.     

Chronic rejection of mouse kidney allografts

BACKGROUND: Chronic renal allograft rejection is the leading cause of late graft failure. However, its pathogenesis has not been defined. METHODS: To explore the pathogenesis of chronic rejection, we studied a mouse model of kidney transplantation and examined the effects of altering the expression of donor major histocompatibility complex (MHC) antigens on the development of chronic rejection. RESULTS: We found that long-surviving mouse kidney allografts develop pathological abnormalities that resemble chronic rejection in humans. Furthermore, the absence of MHC class I or class II antigens did not prevent the loss of graft function nor alter the pathological characteristics of chronic rejection. Expression of transforming growth factor-beta (TGF-beta), a pleiotropic cytokine suggested to play a role in chronic rejection, was markedly enhanced in control allografts compared with isografts. However, TGF-beta up-regulation was significantly blunted in MHC-deficient grafts. Nonetheless, these differences in TGF-beta expression did not affect the character of chronic rejection, including intrarenal accumulation of collagens. CONCLUSIONS: Reduced expression of either class I or II direct allorecognition pathways is insufficient to prevent the development of chronic rejection, despite a reduction in the levels of TGF-beta expressed in the allograft. This suggests that the severity of chronic rejection is independent of the level of MHC disparity between donor and recipient and the level of TGF-beta expression within the allograft.     

Evidence for epitope spreading and active suppression in skin graft tolerance after donor-specific transfusion.

BACKGROUND: To clarify the controversial results in the literature regarding the role of donor-specific transfusion (DST) on allograft survival, we have examined the influence of the following on DST-induced allograft survival in a 2C transgenic mouse model: varying the time between DST and transplantation; the role of MHC disparities between donor and recipient; whether tolerance induced by DST spreads to skin allografts expressing other alloantigens; and whether cyclosporine (CsA) treatment could further modulate skin allograft tolerance after DST. METHODS AND RESULTS: The studies were performed in both 2C anti-Ld (MHC class I) transgenic and normal (nontransgenic) mice. Our data demonstrate that a single infusion of Ld-mismatched lymphocytes 7 days before transplantation leads to permanent acceptance of donor-specific skin allografts in both transgenic (58/58) and nontransgenic (8/8) mice in the absence of any other nonspecific immunosuppressive treatment. Pretransplantation DST from donors mismatched for more than one MHC antigen (Ag) has no beneficial effect on subsequent donor skin allograft survival. However, Ld plus multiple minor histocompatibility (mH) Ag-mismatched DST induced permanent acceptance of donor-specific skin allografts. Tolerance induced by one-locus Ld-mismatched DST spreads to skin allografts expressing either two-locus Ld or one-locus Ld plus multiple mH Ags. Administration of CsA after DST diminished skin allograft survival, rather than enhancing it, suggesting that tolerance in this model system is established by an active immunological process sensitive to CsA. CONCLUSIONS: (1) Pretransplantation infusion of Ld-mismatched lymphocytes in the presence or absence of multiple mH mismatches induces permanent survival of donor-specific skin allografts. (2) CsA abrogates DST-induced transplantation tolerance.     

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)     

Alloantibody-associated chronic rejection of MHC class I-disparate heart grafts is modulated by intravenous soluble donor alloantigen

Increasing evidence suggests that there may be a causal relationship between the development of donor-specific alloantibodies and chronic allograft vasculopathy (CAV). PVG.RT1(u) rat heart allografts spontaneously undergo chronic rejection when transplanted into unmodified PVG.R8 congenic recipients that differ only at the classical MHC class I RT1.A locus. Here we show that development of vasculopathy in this experimental model is associated with production of a strong anti-A(u) antibody response. Perioperative intravenous administration of recombinant soluble RT1.A(u) heavy chain that is sequence identical to donor MHC class I, or chimaeric A(u/a) (donor/recipient) protein had a variable effect resulting generally in either sensitisation and accelerated rejection, or abrogation of alloantibody and attenuation of chronic rejection. These findings highlight the potential for soluble donor MHC class I alloantigen given at the time of heart transplantation to influence alloantibody production and graft outcome.     

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.     

The mechanism of the induction of immunologic unresponsiveness to rat cardiac allografts by recipient pretreatment with donor lymphocyte subsets

In continuation of our studies using UV-B-irradiated DST and donor leukocyte (DL) recipient pretreatment to induce specific unresponsiveness to organ allografts, we have examined the relative contributions of splenic lymphocyte populations and T lymphocyte subsets in the induction of immunologic unresponsiveness. Our data show that enriched populations of MHC class II-positive B lymphocytes and the W3/25+ T cell subset obtained from splenic leukocytes using immunoadsorbent columns in conjunction with mAbs led to indefinite graft survival (greater than 100 days) in the Lewis-to-ACI rat cardiac allograft model. In contrast, pretreatment with T lymphocytes or the Ox8+ T subset was relatively ineffective in prolonging cardiac allograft survival. In addition, third-party (W/F) W3/25+ T cell recipient pretreatment did not influence the survival of Lewis cardiac allografts in ACI recipients, thus confirming the specificity of pretreatment with the T cell subset in graft prolongation. Furthermore, we have examined the underlying mechanisms of donor-specific unresponsiveness induced by donor spleen cells, B lymphocytes, and W3/25+ T cells using adoptive transfer assays. Serial adoptive transfer studies demonstrated the presence of 0x8+ suppressor T cells in the spleens of unresponsive recipients bearing well-functioning cardiac allografts and of serum "suppressor factors" that have the capacity for specifically prolonging donor-type test graft survival in naive syngeneic rats. Our findings suggest that the induction of specific unresponsiveness in this model is dependent on a sequential collaboration between the appearance of donor-specific serum factor(s) (humoral phase) and donor-specific suppressor T cells (cellular phase). These results may be potentially useful in planning future strategies for the induction of unresponsiveness to clinical organ allografts by immunologic manipulation of the host with MHC class II-positive B cell and CD4+ T cell clones.     

Donor-specific cellular immunity in rejecting and long-term-surviving class I-disparate rat renal allograft recipients

The effects of pre- and posttransplant immunization on graft survival, infiltrate intensity, and host in situ/systemic cellular immune responsiveness were examined for class I MHC-disparate rat renal allograft recipients. Naive, unsensitized PVG (RT1c) recipients of class I MHC disparate PVG.R1 (RT1.Aa on PVG background) orthotopic kidney transplants displayed long-term (greater than 50 days) survival (LTS) in a majority (41/52) of cases. Pretransplant immunization of recipients with a PVG.R1 skin graft most often resulted in rejection (mean survival greater than 21.3 days) with 8/15 rats surviving less than or equal to 2 weeks and only 3/15 with LTS. Pretransplant immunization with a skin graft from a fully MHC-disparate PVG.1A (RT1a on PVG background) donor resulted in acute rejection (mean = 6.1 days) with 0/8 rats surviving greater than or equal to 2 weeks. Donor-specific class I and II disparate (PVG.1A), and third-party (LEW) skin transplants applied on LTS (greater than 50 days) PVG.R1 kidney graft recipients showed typical 1st- and accelerated 2nd-set skin graft rejection, but had no effect on kidney graft survival. In contrast, 6/7 LTS PVG.R1 kidney graft recipients accepted PVG.R1 skin grafts indefinitely following their transient partial rejection. Histologic analysis of kidney allografts revealed the highest degree of mononuclear cell infiltrates in animals specifically sensitized by PVG.1A skin grafts prior to transplant. Donor class I-specific cytotoxic T lymphocyte precursor (pCTL) frequencies, as determined by limiting dilution assays, were increased and equivalent at 1 week posttransplant in kidney allograft cell eluates from nonrejecting naive recipients (1/127-1/2209) and rejecting presensitized animals (1/470-1/7848). LTS animals had decreased intragraft pCTL at greater than 50 days (1/2969-1/61875), as did LTS at greater than 50 days that received PVG.R1, PVG.1A, or LEW skin grafts posttransplant. In all groups, splenocyte pCTL frequencies were significantly lower than the corresponding values within the allograft. By comparison, no significant differences in intragraft or splenic proliferative T lymphocyte (pPTL) precursor frequencies were observed between any groups. These results indicate that unsensitized recipients of class I-disparate renal cells grafts are capable of maintaining graft survival in the early posttransplant period, despite the presence of significant in situ antidonor class I MHC-specific cellular immune responsiveness. These findings also indicate that long-surviving PVG recipients of class I-disparate renal allografts develop specific functional tolerance to donor class I alloantigens, that may be associated with a diminished frequency of anti-class I cytotoxic (but not proliferative) T cell precursors.     

Effect of recombinant interferon gamma and interleukin-2 and of a monoclonal antibody against interferon gamma on the rat immune response against heart allografts

We studied the effect of rat rec-IFN-gamma, human rec-IL-2, and an IgG1 monoclonal antibody (DB1) directed against rat IFN-gamma on allograft survival in the rat in various experimental conditions. The DB1 monoclonal antibody did not prolong heart allograft survival in the (LEW/BN)F1 to LEW combination, even when used at high doses (2 mg/rat x 9 days). Rec-IFN-gamma induced major histocompatibility antigen expression in vivo, but its administration had no effect on the graft survival either of untreated LEW recipients of (LEW x BN)F1 heart allografts or of donor blood-transfused LEW recipients. In addition, rec-IFN-gamma alone had no effect on graft survival in cyclosporine-treated rats. In contrast, rec-IL-2 shortened heart allograft survival both in untreated and in cyclosporine-treated recipients. Rec-IFN-gamma partially reversed the effects of rec-IL-2 in cyclosporine-treated rats. The data suggest that in vivo administration of IFN-gamma in allograft recipients may have a suppressor effect, in addition to the postulated augmenting effect on the immune response by increasing MHC antigen expression.     

Antibody‐Mediated Rejection of Single Class I MHC‐Disparate Cardiac Allografts

Murine CCR5^?/? recipients produce high titers of antibody to complete MHC‐mismatched heart and renal allografts. To study mechanisms of class I MHC antibody‐mediated allograft injury, we tested the rejection of heart allografts transgenically expressing a single class I MHC disparity in wild‐type C57BL/6 (H‐2^b) and B6.CCR5^?/? recipients. Donor‐specific antibody titers in CCR5^?/? recipients were 30‐fold higher than in wild‐type recipients. B6.K^d allografts survived longer than 60 days in wild‐type recipients whereas CCR5^?/? recipients rejected all allografts within 14 days. Rejection was accompanied by infiltration of CD8 T cells, neutrophils and macrophages, and C4d deposition in the graft capillaries. B6.K^d allografts were rejected by CD8^?/?/CCR5^?/?, but not μMT^?/?/CCR5^?/?, recipients indicating the need for antibody but not CD8 T cells. Grafts recovered at day 10 from CCR5^?/? and CD8^?/?/CCR5^?/? recipients and from RAG‐1^?/? allograft recipients injected with anti‐K^d antibodies expressed high levels of perforin, myeloperoxidase and CCL5 mRNA. These studies indicate that the continual production of antidonor class I MHC antibody can mediate allograft rejection, that donor‐reactive CD8 T cells synergize with the antibody to contribute to rejection, and that expression of three biomarkers during rejection can occur in the absence of this CD8 T cell activity.     

Transfer of "infectious" cardiac allograft tolerance induced by donor-specific transfusion

BACKGROUND: "Infectious tolerance" has been defined as the tolerance induced in a new recipient by the adoptive transfer of cells from a recipient accepting an allograft after anti-CD4 and anti-CD8 monoclonal antibody treatment. A clear understanding of the mechanisms responsible for graft acceptance after donor-specific blood transfusion (DST) has remained elusive. We examined the development and "infectious" nature of immunologic changes resulting in indefinite survival of LEW to DA rat cardiac allografts after DST alone without the need for antibody. METHODS: One hundred x 10(6) LEW splenocytes (SC) as DST were injected intravenously into DA recipients 7 days before LEW cardiac transplantation. Subsequently, 100 x 10(6) SC harvested from a DA recipient 30, 60, or 100 days after graft acceptance were adoptively transferred into lightly gamma-irradiated (450 rad) na?ve DA recipients 24 hours before a second LEW cardiac allograft. Subsequent graft function was determined. RESULTS: Adoptive transfer of SC from the DST-treated DA rats 30 days after LEW heart transplant acceptance into na?ve gamma-irradiated DA rats failed to transfer tolerance to LEW cardiac allografts. However, SC from DA rats bearing LEW hearts for more than 60 days induced indefinite tolerance to all LEW hearts. This infectious tolerance could be adoptively transferred again to a second DA recipient. CONCLUSIONS: DST-generated regulatory cells can downregulate na?ve lymphocytes to promote allograft acceptance. This tolerance can be expanded and serially transferred to a subsequent na?ve cardiac recipient.     

Enhancement of thyroid allograft survival following organ culture. Alteration of tissue immunogenicity

Hyperbaric oxygen (95%, O2, 25 psi, 48-hr culture) resulted in prolonged thyroid allograft (B10.A) survival in both primary and sensitized recipients (B10.AQR). Recipients receiving noncultured thyroid allografts uniformly rejected the graft by 35 days, while 100% of cultured grafts survived. Noncultured thyroid grafts transplanted to skin-graft-primed recipients were rejected by 21 days. In contrast, 86% of cultured grafts transplanted to primed recipients were still functioning at 35 days. Donor spleen cells or peritoneal exudate cells transferred at the time of thyroid transplant were unable to stimulate cultured allograft rejection. Allografts histologically examined 35 days after transplant revealed, in some grafts, focal cellular infiltrates adjacent to normal, uninfiltrated tissue. To determine if tissue modification was the mechanism of prolonged allograft survival, hyperbaric-oxygen-cultured thyroids were examined for MHC class I expression. Immunoperoxidase staining with monoclonal antibody to MHC class I molecules showed that cultured thyroids were unstained in contrast to fresh thyroids that were uniformly stained. Cytotoxic T lymphocytes specific for H-2Kk administered 10 days following thyroid transplant were unable to eliminate cultured grafts (80% survival) but completely destroyed noncultured grafts. These results indicate that hyperbaric oxygen culture altered MHC class I expression such that it was no longer detectable by monoclonal antibody or cytotoxic T lymphocytes. Thus, the mechanism, explaining graft prolongation after hyperbaric culture in addition to passenger cell depletion, may be alteration of graft antigenicity such that the graft is no longer perceived as foreign.     

Mechanism of action of donor-specific transfusion in inducing tolerance: role of donor MHC molecules, donor co-stimulatory molecules, and indirect antigen presentation

Donor-specific transfusion (DST) can synergize with T cell co-stimulatory blockade in inducing tolerance in several transplant models, but the mechanism of action of DST is poorly characterized. This study used genetically altered mice in an established model of cardiac transplantation to study the role of MHC and co-stimulatory molecule expression on DST cells in mediating the immunomodulatory effects of DST. In addition, to examine the role of indirect antigen presentation in the effect of DST, experiments used recipient mice that do not express MHC class II molecules on peripheral antigen-presenting cells, but do have functional CD4(+) T cells (II(-)4(+)). As previously reported, treatment with DST from wild-type donors in combination with CD154 blockade induced tolerance in wild-type recipients of cardiac allografts. Tolerance in this model is also induced despite the absence of MHC class I and II, CD40, or B7 molecules on transfused cells. In contrast, eliminating the indirect pathway using II(-)4(+) recipients blocked the induction of long-term cardiac allograft survival by DST. These results indicate that the indirect antigen recognition pathway mediates the immunomodulatory effect of DST in inducing transplantation tolerance in vivo.     

Allochimeric therapy induces unique regulatory T cells that mitigate chronic rejection

Induction of tolerance to an allogeneic graft without the need for nonspecific immunosuppression is a major goal of transplantation therapy. We have shown that treatment with molecularly engineered, allochimeric [alpha(1h)(1/u)]-RT1.Aa class I MHC antigens bearing donor-type Wistar-Furth (WF, RT1.A(u)) or Lewis (LEW, RT1A(1)) amino acid substitutions for host-type ACI (RTI.A(a)) sequences in the alpha(1)-helical region induces donor-specific tolerance to cardiac allografts in rat recipients. The mechanisms involved in the establishment and maintenance of specific allograft tolerance are still not fully understood. It is now clear that acquisition of transplantation tolerance is an active, highly regulated, multistep process. According to the pool size model of allograft tolerance, the allograft outcome, rejection, or tolerance often depend on the balance between cytopathic and regulatory T cells (T-regs). This study examined mechanisms of chronic rejection (CR) development on a model of cardiac transplant tolerance after adoptive transfer of T-regs followed by allochimeric therapy. Generation of T-regs was demonstrated in vitro by MLR coculture and confirmed by adoptive transfer of T cells from primary recipients to secondary hosts. To confirm the true nature of regulatory cells, we performed a second transfer into tertiary recipients. Unlike T-regs from tolerant hosts, T cells from naive rats did not prolong graft survival. Histological evaluation of T-regs-transfected groups showed absence of visible CR. In contrast, T-regs generated in recipients after high-dose cyclosporine treatment failed to inhibit CR in transferred singeneic recipients. Allochimeric therapy triggers generation of unique regulatory lymphocytes that mitigate development of chronic rejection through regulation of anti-inflammatory mechanisms and down-regulation of alloantibody response.     

The effect of thymectomy on tolerance induction and cardiac allograft vasculopathy in a miniature swine heart/kidney transplantation model.

BACKGROUND: We have previously demonstrated that MHC class I disparate hearts transplanted into miniature swine treated with a short course of cyclosporine developed florid cardiac allograft vasculopathy (CAV) and were rejected within 55 days. However, when a donor-specific kidney is cotransplanted with the heart allograft, recipients become tolerant to donor antigen and accept both allografts long-term without the development of CAV. In the present study, we have investigated the role of the host thymus in the induction of tolerance and prevention of CAV in heart/kidney recipients. METHODS: Total thymectomies were performed in six animals (postoperative day [POD]-21), which on day 0 received either an isolated MHC class I disparate heart allograft (n=3) or combined class I disparate heart and kidney allografts (n=3), followed in both cases by a 12-day course of cyclosporine (POD 0-11). Graft survival and the development of CAV in these thymectomized recipients were compared to the same parameters in non-thymectomized, cyclosporine-treated recipients bearing either class I disparate heart allografts (n=5) or heart and kidney allografts (n=4). RESULTS: In the group of animals bearing isolated class I disparate heart allografts, the thymectomized recipients rejected their allografts earlier (POD 8, 22, 27) than the non-thymectomized recipients (POD 33,35,45,47,55). The donor hearts in both the thymectomized and non-thymectomized animals developed florid CAV. In the group of animals bearing combined class I disparate heart and kidney allografts, the nonthymectomized recipients accepted both donor organs long term with no evidence of CAV. In contrast, none of the thymectomized heart/kidney recipients survived >100 days, and they all developed the intimal proliferation of CAV. CONCLUSION: Thymic-dependent mechanisms are necessary for the induction of acquired tolerance and prevention of CAV in porcine heart/kidney recipients.     

Use of allochimeric proteins to mitigate graft-versus-host and host-versus-graft immune responses to rat small bowel allografts

BACKGROUND: We aimed to identify the polymorphic epitopes that mitigate graft-versus-host disease (GvHD) and host-versus-graft response (HvGR) toward rat small bowel allografts in rats. METHODS: We tailored class I major histocompatibility complex (MHC) allochimeric antigens encoding 10 al-helical (alpha(1h)l58-80-RT1.Aa) or 4 (alpha(1h)l/u62-69-RT1.Aa) polymorphic amino acids. In the GvHD model, ACI (RT1a) donors were pretreated (day -14) with an intrathymic injection of alpha(1h)l58-80-RT1.Aa, alpha(1h)l/u62-69-RT1.Aa, or RT1.Al protein, with or without simultaneous intravenous injection of anti-T-cell receptor R73 monoclonal antibodies. Wistar-Furth (WF; RT1u) donors were tested with a similar protocol. In the HvGR model, ACI recipients were treated with a protocol designed to induce transplantation tolerance toward WF heart allografts: a portal vein injection of alpha(1h)l/u62-69-RT1.Aa protein and cyclosporine (4 mg/kg, intramuscular; days 0-6). RESULTS: GvHD was prevented in all (ACI x LEW) F1 recipients (RT1a/l) by pretreating ACI donors with R73 monoclonal antibody and recipient RT1.Al or alpha(1h)l58-80-RT1.Aa protein. Similarly, pretreatment of WF donors with RT1.Aa protein also prevented GvHD in (ACI x WF) F1 recipients. However, in a combined GvHD/HvGR model, ACI recipient perioperative treatment designed to prevent HvGR only modestly prolonged WF small bowel allograft survival (27.7+/-5.3 days compared to 17.4+/-4.6 days in the cyclosporine-alone group). In contrast, application of the two protocols significantly prolonged WF allograft survival (55.6+/-34.6 days), with two of seven recipients surviving more than 100 days. CONCLUSION: Simultaneous inhibition of GvHD and HvGR significantly prolongs small bowel allograft survival.     

Endothelin-mediated oncofetal fibronectin expression in chronic allograft nephropathy

BACKGROUND: Chronic allograft nephropathy is a sclerotic process characterized by an increased extracellular matrix (ECM) protein deposition. Fibronectin (FN) is a major component of ECM. FN has been reported to undergo alternative splicing and produce several isoforms including the extra domain-B (ED-B) containing embryonic isoform. In the present study, we investigated ED-B FN expression in chronic allograft nephropathy and its relationship with endothelins (ET). METHODS: To establish chronic allograft nephropathy, allografts were performed between Fisher 344 --> Lewis rats. Allograft recipients were then randomly divided into two groups, allografts and allografts treated with ET receptor antagonist bosentan. Lewis --> Lewis recipients were used as isograft controls. Grafts were harvested at 30, 90 and 140 days for histological and gene expression analyses with respect to ED-B FN, ET-1 and transforming growth factor-beta1 (TGF-beta1) mRNA. ED-B FN protein levels were assessed by immunohistochemical analysis. Additionally, we analyzed human renal allograft biopsies. RESULTS: Our data demonstrates that rat chronic allograft nephropathy is associated with progressive upregulation of ED-B FN mRNA and protein. ET-1 and TGF-beta1 mRNA were also upregulated. Treatment of allograft recipient rats with bosentan prevented upregulation of ED-B FN and TGF-beta1. We further show that total FN, ED-B FN, ET-1 and TGF-beta1 mRNA expression were upregulated in human chronic allograft nephropathy specimens. CONCLUSION: Results obtained from both human and rat renal allograft tissues suggest that expression of ED-B FN is upregulated in chronic allograft nephropathy and such upregulation is mediated via ET-1 and its interaction with TGF-beta1.     

Endogenous Memory CD8 T Cells Are Activated Within Cardiac Allografts Without Mediating Rejection

Endogenous memory CD8 T cells infiltrate MHC‐mismatched cardiac allografts within 12–24 h posttransplant in mice and are activated to proliferate and produce IFN‐γ. To more accurately assess the graft injury directly imposed by these endogenous memory CD8 T cells, we took advantage of the ability of anti‐LFA‐1 mAb given to allograft recipients on days 3 and 4 posttransplant to inhibit the generation of primary effector T cells. When compared to grafts from IgG‐treated recipients on day 7 posttransplant, allografts from anti‐LFA‐1 mAb‐treated recipients had increased numbers of CD8 T cells but these grafts had marked decreases in expression levels of mRNA encoding effector mediators associated with graft injury and decreases in donor‐reactive CD8 T cells producing IFN‐γ. Despite this decreased activity within the allograft, CD8 T cells in allografts from recipients treated with anti‐LFA‐1 mAb continued to proliferate up to day 7 posttransplant and did not upregulate expression of the exhaustion marker LAG‐3 but did have decreased expression of ICOS. These results indicate that endogenous memory CD8 T cells infiltrate and proliferate in cardiac allografts in mice but do not express sufficient levels of functions to mediate overt graft injury and acute rejection.