Chronic renal allograft rejection: the significance of non-MHC alloantigens

We studied the role of polymorphic endothelial antigens other than MHC in antibody-mediated chronic renal allograft rejection in two models. In the first model, donor Lewis rat kidneys were transplanted into BN recipients that had been made tolerant for donor class I antigens at the B cell (antibody) level. In this setting Lewis kidney grafts were chronically rejected with stable renal function but increasing proteinuria (> 100 mg/24 h). Rejected graft tissue showed mononuclear cell infiltration and the presence of glomerular vasculonecrotic lesions with fibrinoid material, associated with IgG and IgM deposition, but with absent or weak C3 binding. Graft endothelium showed no expression of MHC class II antigens. Serum antibodies were not reactive with donor class I antigens, but did react with endothelial non-MHC alloantigens. In the second model, more direct information on the role of endothelial non-MHC alloantigens in renal allograft rejection was obtained by transplanting Lewis 1 N kidneys into unmodified BN recipients (MHC-matched transplants). Here, similar to the first model, the animals developed severe proteinuria with stable renal function. Histopathological examination showed mononuclear cell infiltration and deposition of IgM and IgG along the glomerular vasculature, but this time in the presence of strong C3 reactivity. However, glomerular vasculonecrotic lesions with intense fibrin deposition were not observed. The data showed that although clinically the two kidney transplantation models used gave similar chronic rejection phenomena, histopathologically some striking differences were observed in the glomeruli. The precise mechanisms effecting chronic rejection of the grafts is still a puzzle. However, immune reactivity against graft (endothelial) non-MHC antigens may play a significant role.     

The relative roles of MHC and non-MHC genes in heart and skin allograft survival

Although the role of the major histocompatibility complex (MHC) of the rat (RT1) in graft rejection has been established, the role of non-RT1 genes is not well understood. To investigate the influence of MHC and non-MHC genes in graft rejection, various combinations of congenic and inbred strains of rats were used as donors and recipients of skin grafts and perfused abdominal heart grafts. In addition, hemagglutinating and cytotoxic antibody responses were evaluated to assess loci that were serologically active in transplantation. Our results demonstrate that: (1) RT1 antigens are the most important determinant in heart and skin rejection; (2) antigens controlled by non-MHC genes also play a major role in rejection because they cause disparate heart grafts to be rejected by day 18 and skin grafts by day 26; (3) RT2 cell antigens alone do not cause graft rejection; and (4) allogeneic differences at the RT1, RT2, RT3, and RT6 loci elicit an antibody response in heart transplantation.     

Effects of antibody reactivity to major histocompatibility complex (MHC) and non-MHC alloantigens on graft endothelial cells in heart allograft rejection

BACKGROUND: To gain insight in the pathogenesis of vascular lesions in heart allograft rejection, we investigated effects of allosera reactive with major histocompatibility complex (MHC) or non-MHC alloantigens on graft endothelial cells (EC) in a rat transplantation model. METHODS: Anti-MHC and anti-non-MHC allosera were obtained from Brown Norway (RT.1(n)) recipients of a Lewis (RT.1(1)) or congenic LEW.1N (RT.1(n)) heart allograft respectively. Reactivity with endothelial alloantigens was studied in vitro using a series of three rat heart endothelial cell (RHEC) lines of Lewis origin. Phenotypic studies of MHC and non-MHC alloantigen expression, and adhesion molecule induction on EC were performed by immunostaining and fluorescence-activated cell sorting analysis. Complement-mediated cytotoxicity of allosera was studied using a 51Cr release assay. RESULTS: Both anti-MHC allosera and anti-non-MHC allosera showed reactivity with all three RHEC lines. EC stimulation with tumor necrosis factor-alpha and interferon-y resulted in increased reactivity of anti-MHC but not of anti-non-MHC allosera. Anti-MHC allosera showed complement-mediated cytotoxicity for EC, which was strongly increased when cytokine-stimulated EC were used. With anti-non-MHC allosera, only minor cytotoxicity was measured, irrespective of the activation of EC. Anti-MHC and anti-non-MHC allosera from the day of rejection (days 7-8 and days 29-35, respectively) had similar subclass profiles of allospecific IgG, except for allospecific IgM, which was only detected in anti-MHC allosera. Complement-mediated cytotoxicity of anti-MHC allosera from the day of rejection was effected mainly by IgM alloantibodies, whereas, in allosera taken 4 days after rejection, a predominance of cytotoxic alloantibodies of the IgG class was observed. No indications were found that either alloantibody reactivity alone or in combination with complement activation led to EC activation processes relevant to intercellular adhesion molecule-1 or vascular cell adhesion molecule-1 induction. CONCLUSIONS: Our data show that, in heart allograft rejection, MHC but also non-MHC alloantigens on EC are target structures in the alloantibody response. Alloantibodies reactive with endothelial MHC, but not those reactive with non-MHC alloantigens, may significantly contribute to vasculopathy by complement-mediated cytotoxicity. Although no evidence was found that alloantibodies reactive with graft EC induce adhesion molecule expression, they may trigger other EC mechanisms relevant to graft vasculopathy.     

Complement activation by anti-endothelial cell antibodies in MHC-mismatched and MHC-matched heart allograft rejection: Anti-MHC-, but not anti non-MHC alloantibodies are effective in complement activation

Classical complement activation is a major effector mechanism in the development of vascular lesions contributing to allograft rejection. We investigated complement activation by alloantibodies reactive with graft endothelial cell (EC) alloantigens in settings of MHC-mismatched and MHC-matched (non-MHC-mismatched) rat heart transplantation (Tx). Allosera and heart allografts were collected at the day of rejection (day 7–8 and day 28–35 in MHC-mismatched and non-MHC-mismatched Tx respectively) or earlier. Allosera reactivity was studied in vitro using rat-heart-endothelial-cell (RHEC) lines expressing the appropriate donor MHC and non-MHC alloantigen profile. Immunohistochemical analysis of rejected heart allografts showed deposition of alloantibodies in both MHC-mismatched and MHC-matched heart allografts, but expression of C3 was only seen in the vasculature of MHC-mismatched grafts. FACS analysis showed that anti MHC as well as anti non-MHC allosera were reactive with donor EC cell surface antigens. Both sera had similar IgG subclass profiles of anti-endothelial cell antibodies. Complement activation by anti MHC and anti non-MHC alloantibodies on EC was measured by FACS analysis of C3 and C5b-9 (MAC) expression. Distinct expression of C3 was noticed for EC incubated with anti-MHC allosera, but hardly for EC incubated with anti non-MHC allosera. C5b-9 was low but showed no difference between the two allosera. However, complement-mediated cytotoxicity experiments showed that functional (lytic) MAC was induced with anti MHC allosera but hardly with anti non-MHC allosera. Our data show that in settings of MHC-matched heart transplantation alloantibodies against endothelial non-MHC alloantigens are generated, but, in contrast to alloantibodies to MHC alloantigens, these alloantibodies have only poor complement-activating and lytic potentials. Whether anti non-MHC allolantibodies effect other biological processes relevant for heart allograft vasculopathy, including development of graft arteriosclerosis, needs further elucidation. Received: 5 November 1999/Accepted: 17 May 2000     

Treatment of chronic renal allograft rejection in rats with a low-molecular-weight heparin (reviparin)

BACKGROUND: Low-molecular-weight heparin (LMWH) has been shown to prolong survival of rat cardiac allografts independently from immunosuppressive treatment. Furthermore, long-term treatment reduces the development of chronic graft vascular disease after experimental heart transplantation. The aim of the present study was to determine whether treatment with the LMWH reviparin has a beneficial effect on chronic rejection in a rat renal allograft model. METHODS: Kidneys of Fisher (F344) rats were transplanted into unilaterally nephrectomized Lewis (LEW) recipients. LEW-->LEW isografts served as controls. Animals were treated with cyclosporine (5 mg/kg/d) for the first 10 days. Nephrectomy of the remaining kidney was performed after 10 days. Allografted animals were treated either with reviparin (2 mg/kg/d subcutaneously) for 24 weeks (Allo-24), from week 12 to 24 (Allo-12), or with vehicle for 24 weeks. Proteinuria was determined at regular intervals. Kidneys were harvested after 24 weeks for histomorphological and immunohistochemical evaluation. RESULTS: No major bleeding complications were observed in reviparin-treated animals. Proteinuria was significantly reduced in allografted animals both by early as well as by late-onset treatment with reviparin. Transplant glomerulopathy was diminished in Allo-24 and in Allo-12 groups compared to vehicle-treated animals, whereas tubulointerstitial inflammation was influenced only in animals immediately treated with reviparin. Immunohistochemical studies demonstrated a marked reduction of renal monocyte and T-cell infiltration as well as expression of MHC II by treatment with reviparin. CONCLUSIONS: Treatment with the LMWH reviparin significantly improved chronic renal allograft rejection in the F344-to-LEW rat model, both after early and late start of therapy. Although the exact mechanisms of this beneficial effect remain unclear, our data offer a potential new therapeutical approach for prevention of chronic allograft nephropathy.     

Induction of chronic renal allograft injury by injection of a monoclonal antibody against a donor MHC Ib molecule in a nude rat model

BACKGROUND: Chronic allograft injury induced by immunological as well as non-immunological mechanisms is still a major cause of long-term graft loss after renal transplantation. Major histocompatibility complex (MHC) incompatibilities as well as donor-specific alloantibodies are known risk factors, but the interaction of cellular and humoral mechanisms leading to allograft damage remains to be defined. The aim of this study was to analyze the impact of donor-specific post-transplant antibodies against a non-classical MHC Ib antigen apart from T-cell-dependent immune response. Therefore, we utilized a transplant rat model injecting a moAb directed against a donor MHC Ib molecule into athymic nude recipients lacking an immunocompetent T-cell system. METHODS: F344 kidneys were transplanted into LEW.RNU rats. Donor and recipient differ in the RT1.C locus (MHC Ib) but are phenotypically identical for the RT1.A (MHC I) and RT1.B/D (MHC II) loci. A moAb directed against the donors RT1.C(lv1) was injected into recipients with stable graft function. A control group remained untreated after transplantation. The rats were monitored for renal function and grafts were analyzed for morphological changes, infiltrating cells and C4d deposition. RESULTS: Antibody-infused rats developed renal impairment with massive urine albumin excretion. Histological changes consistent with antibody-mediated injury were interstitial fibrosis, tubular atrophy and severe glomerulopathy accompanied by an infiltrate of numerous macrophages. At time of death, grafts were negative for C4d at the peritubular capillaries and arterial endothelium. CONCLUSION: Antibodies directed against a MHC Ib antigen are able to induce allograft injury in T-cell-deficient rats. This model underlines the role of non-classical MHC disparities for long-term allograft survival and demonstrates the long-term results of antibody-induced allograft damage.     

Chronic renal allograft nephropathy

Chronic rejection/chronic allograft nephropathy is the most prevalent cause of renal graft loss after the first year post-transplant. Chronic rejection/chronic allograft nephropathy is characterized by a slow progressive deterioration of graft function, often in combination with proteinuria and hypertension. Both immunologic and non-immunologic factors play key roles in the pathogenesis of chronic allograft nephropathy. Acute rejection episodes are the most prevalent risk factor for chronic rejection. Many risk factors for chronic allograft nephropathy have been identified, such as delayed graft function, nephron-dosing mismatch, repeated acute rejection episodes, and pathologically severe rejection. However, the precise pathogenesis of chronic allograft nephropathy remains elusive. The differential diagnosis of immunologically mediated chronic rejection and chronic rejection caused by non-immunologic factors is usually not possible using clinical parameters. The histopathologic findings of chronic allograft nephropathy are progressive interstitial fibrosis and remodelling of the vascular wall, and these findings are nonspecific. However, typical chronic transplant glomerulopathy, which affects glomerular tufts, as well as the multilayering of the peritubular capillary basement membrane, are characteristic of immunologic chronic rejection. Furthermore, in long-surviving patient with an allograft treated with a potent immunosuppressive agent, a calcineurin inhibitor, two or more concomitant independent lesions often develop. Therefore, the term "chronic allograft nephropathy" may be clinically preferable to "chronic rejection" to describe the gradual decline in graft function months or years after transplantation, in the absence of a well defined mechanism of graft dysfunction. The most effective way to prevent chronic allograft nephropathy is to avoid any kind of graft damage via either immunologic or non-immunologic mechanisms. Received: April 1, 2000 / Accepted: May 2, 2000     

Chronic renal allograft rejection. Selective involvement of the glomerular endothelium in humoral immune reactivity and intravascular coagulation

To study immune reactive and thrombotic mechanisms involved in chronic renal allograft rejection, Lewis rat kidneys were transplanted into bilaterally nephrectomized Brown Norway recipients tolerant of LEW erythrocyte antigens. Such BN rats fail to produce anti class I MHC alloantibodies after insertion of a LEW kidney. The LEW renal allografts experience a transient rejection episode without proteinuria followed by the development of chronic rejection, clinically characterized by glomerular proteinuria in the presence of stable renal function. Immunohistological studies of such chronically rejected LEW renal allografts showed the occurrence of glomerular and interstitial infiltration of predominantly monocytes and T cells. CD4-positive T cells dominated over CD8-positive T cells in the chronically rejected LEW renal grafts. IgG deposition was found deposited throughout the renal vasculature--this in contrast to IgM, which was observed only in the glomerular vasculature. Glomerular antibodies were not directed to endothelial class II MHC antigens, and showed only weak complement fixation as demonstrated by C3 staining. Selective glomerular IgM deposition was associated with vascular (platelet-containing) thrombi, and focal and segmental fibrinoid necrosis. In contrast, acutely rejected LEW renal grafts in unmodified BN recipients showed IgM deposition as well as thrombus formation throughout the entire renal vasculature. The results demonstrate that the antibody response to endothelial--and, in particular, glomerular endothelial non-MHC antigens--may bring about chronic vascular renal allograft rejection. How the formation of glomerular thrombotic lesions may be assisted by endothelial reactivity to cytokines from local immune reactive cells is discussed.     

Early acute rejection does not affect chronic allograft nephropathy and death censored graft failure

BACKGROUND: Even with the development of modern immunosuppression, an acute rejection episode is a major complication after renal transplantation. Acute rejection episodes have been used as clinical indicators for chronic allograft nephropathy and graft loss. We investigated the timing and frequency of acute rejection episodes in relation to long-term graft survival and chronic allograft nephropathy. METHODS: The Long Term Efficacy and Safety Surveillance study of transplant patients receiving cyclosporin (Neoral) included 1706 adult renal transplants (1995 to 2003) with a functioning graft for at least 1 year. The impact on death-censored long-term graft survival was evaluated for acute rejection episodes (single or multiple) within 3 months, at 3 to 6 months, at 6 to 12 months, or at over 1 year posttransplant. A stepwise binary logistic regression was employed to identify independent risk factors for the time to occurrence of an acute rejection episode. RESULTS: An acute rejection episode occurring within 3 months posttransplantation had no effect on either death-censored long-term graft failure (P=.2157) or chronic allograft nephropathy (P=.9331). However, an acute rejection episode occurring at 1 year or later posttransplantation was significantly associated with death censored long-term graft failure (P <.0001) and chronic allograft nephropathy (P <.0001). The numbers of HLA-DR mismatches and younger recipient ages were independent risk factors for early acute rejection. CONCLUSION: Among patients whose graft survives at least 12 months, an early acute rejection episode within 3 months posttransplant was not associated with either death-censored long-term graft survival or chronic allograft nephropathy among adults treated with cyclosporin. However, an acute rejection episode occurring at 1 year or later posttransplantation showed a positive association with death-censored long-term graft survival or chronic allograft nephropathy. Lower numbers of HLA-DR mismatches sum to reduce the occurrence of acute rejection and the hospitalization time.     

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.     

The relative roles of MHC and non-MHC antigens in bone marrow transplantation in rats. Graft acceptance and antigenic expression on donor red blood cells

In order to investigate the influence of MHC and non-MHC genes in bone marrow transplantation, various combinations of congenic and inbred strains of rats were used as donors and recipients. A standard regimen of busulfan and cyclophosphamide treatment was used to condition the recipients. The resultant survival patterns of the animals indicated that: (1) a difference across the entire RT1 (MHC) complex is sufficient for the induction of fatal graft-versus-host disease (GVHD) in 100% of the engrafted animals; and (2) the blood group antigens RT2 and RT3, which are controlled by non-MHC genes, do not cause bone marrow graft rejection or GVHD. There were sequential changes of expression in surface alloantigens on the red cells in different donor-recipient combinations without other hematologic changes in the busulfan-cyclophosphamide conditioned bone marrow chimeras.     

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.     

Chronic allograft nephropathy

Chronic allograft nephropathy (CAN) is the leading cause of renal allograft loss in paediatric renal transplant recipients. CAN is the result of immunological and nonimmunological injury, including acute rejection episodes, hypoperfusion, ischaemia reperfusion, calcineurin toxicity, infection and recurrent disease. The development of CAN is often insidious and may be preceded by subclinical rejection in a well-functioning allograft. Classification of CAN is histological using the Banff classification of renal allograft pathology with classic findings of interstitial fibrosis, tubular atrophy, glomerulosclerosis, fibrointimal hyperplasia and arteriolar hyalinosis. Although improvement in immunosuppression has led to greater 1-year graft survival rates, chronic graft loss remains relatively unchanged and opportunistic infectious complications remain a problem. Protocol biopsy monitoring is not current practice in paediatric transplantation for CAN monitoring but may have a place if new treatment options become available. Newer immunosuppression regimens, closer monitoring of the renal allograft and management of subclinical rejection may lead to reduced immune injury leading to CAN in the paediatric population but must be weighed against the risk of increased immunosuppression and calcineurin inhibitor nephrotoxicity.     

Effects of everolimus on cellular and humoral immune processes leading to chronic allograft nephropathy in a rat model with sensitized recipients

BACKGROUND: Chronic allograft nephropathy (CAN) remains the most common cause of late graft loss especially in sensitized patients. The aim of this study is to evaluate the therapeutic effect of everolimus on cellular and humoral mechanisms of chronic allograft damage in a rat model with sensitized recipients. METHODS: F344 kidneys were transplanted to LEW.RNU rats. The athymic recipients were reconstituted with 3.5 x 10(7) or 5 x 10(7) presensitized CD4+T-lymphocytes. In the treatment group, everolimus was introduced five weeks posttransplantation. Rats were monitored for peripheral blood lymphocytes, renal function, histological changes in the graft, and the development of donor-specific alloantibodies. RESULTS: Rats developed cell dose-dependent renal failure. Increased urinary albumin excretion and glomerulopathy were frequently accompanied by the development of donor-specific major histocompatibility complex (MHC) alloantibodies. In the everolimus group, five of six animals survived for 20 weeks with stable serum creatinine and displayed neither acute cellular rejection nor CAN. Prolonged survival was accompanied with significantly reduced tubulointerstitial cell infiltrate in the graft. Increased urinary albumin excretion was present in all, acute tubular necrosis in five of six, and glomerular sclerosis in two grafts. MHC alloantibodies were found in four of six animals. CONCLUSION: The used rat model offers the opportunity to study the influence of everolimus on the interaction of humoral and cellular mechanisms involved in chronic renal damage. Everolimus leads to a prolongation of allograft survival, reduced cell infiltrate in the graft, and prevents tubular atrophy and interstitial fibrosis. The development of alloantibodies and albuminuria was not prevented. These data suggest that although cellular rejection is clearly suppressed, humoral mechanisms of CAN cannot be completely controlled by everolimus treatment in the sensitized rat model.     

Chronic rejection in renal transplantation

Chronic rejection in renal transplantation is an alloantigen-dependent immune process ultimately leading to graft failure. We reviewed the literature on the basis of the case history of a patient who lost her renal allograft apparently from chronic interstitial rejection. Chronic rejection presents clinically as chronic transplant dysfunction starting at various intervals after transplantation. The histopathologic features consist of chronic allograft nephropathy with or without transplant vasculopathy or glomerulopathy. Chronic rejection should be differentiated from chronic toxicity of calcineurin inhibitors, de novo or recurrent glomerulonephritis, polyoma (BK) virus nephropathy, transplant renal artery stenosis, and nephrosclerosis. Young recipient age, black race, presensitization, histoincompatibility, and acute, especially vascular, and late acute rejection episodes are dominant risk factors, compatible with immunologic mechanisms. Cellular and humoral responses resulting from indirect recognition of alloantigens with subsequent fibrotic sequelae play a central role in the pathogenesis. Circulating donor-specific antibodies and staining for C4d can detect humoral chronic rejection. The prognosis depends on alloreactivity and the presence of progression factors such as old donor age, renal dysfunction, proteinuria, hyperlipidemia, and smoking. A multifactorial approach directed to the risk and progression factors is needed to prevent premature graft loss from chronic rejection.     

Partial tolerance in rat renal allograft recipients following multiple blood transfusions and concomitant cyclosporine

Multiple prior administrations of donor-strain blood while under limited cyclosporine cover, consistently induce extensive rat renal allograft survival and transplantation tolerance. Yet it was hypothesized that some chronic rejection mechanisms were nevertheless operative since consistent but nonprogressive minor renal dysfunction was observed long-term. A histopathologic study on these putative tolerant rats was undertaken to test this hypothesis. Twenty long-term LEW recipients of BN renal allografts receiving the blood-CsA regimen were examined histopathologically at day 100 post-transplant. Sixteen control LEW recipients receiving only a BN renal allograft were studied acutely at day 7 posttransplant. The control recipients demonstrated a range of lesions consistent with previous studies on acute renal allograft rejection in the rat. However, tolerant recipients demonstrated mild-to-moderate lesions consistent with chronic mechanisms of rejection including the following: moderate focal interstitial mononuclear inflammatory cellular infiltration, with periglomerular and perivascular accumulation; occasional arteriolar luminal obliteration and glomerular atrophy; focal areas of moderate interstitial fibrosis; mild interstitial hemorrhage; mild-to-moderate tubular atrophy; and focal tubular necrosis. Previously our laboratory has documented that tissue-specific renal basement membrane antigens may be responsible for inciting this pattern of focal chronic interstitial inflammation. However, from the present histopathologic studies, it would appear likely that chronic rejection mechanisms in these recipients, which were defined as tolerant by immunologic criteria, involve both tissue-specific and MHC determinants. Therefore, induction of transplantation tolerance in these indefinite survivors is partial or incomplete.     

Chronic rejection and late renal allograft dysfunction

Renal transplantation is currently standard therapy for end-stage kidney disease for children. Despite the considerable improvement in short-term results, the expected allograft half-life has remained the same. This is due to chronic rejection/late graft dysfunction which has proved resistant to therapeutic attempts. During the last few years the multifactorial pathogenesis of chronic renal allograft rejection has been clarified to some extent. Early injury by immunological and non-immunological mechanisms is followed by vascular remodelling due to repetitive cycles of cytokine release, upregulation of growth factors, and vascular smooth muscle cell proliferation. This leads to typical concentric arteriolosclerosis and ischemia. Secondary kidney-specific mechanisms are initiated by the reduction in functioning renal mass and lead to gradual progression of chronic rejection. There is no single optimal therapy. Several attempts to influence the pathophysiological cascade have been promising. Attention should be focused on minimizing early immunological/non-immunological injury in order to attenuate future progression of chronic rejection. A significant prolongation of allograft half-life may be achieved during the next decade with the introduction of new therapeutic agents and comprehensive approach to treatment. This would be especially beneficial for pediatric recipients, reducing the need for retransplantation in adulthood.     

Alloantigen-induced, T-cell-dependent production of nitric oxide by macrophages infiltrating skin allografts in mice

The immunological rejection reaction occurring after organ or tissue transplantation is characterized by a strong infiltration of the graft by T cells and macrophages. Since the rejection reaction is highly specific, we tested the role of T cells in the activation of macrophages and in the induction of nitric oxide (NO) production during graft rejection. The rejection of both MHC and non-MHC antigen-disparate skin allografts was associated with a significantly increased production of NO in the graft. The kinetics of NO production after transplantation correlated with the rejection reaction and with the fate of the allograft. A significant reduction in NO production was found in immunologically hyporeactive mice treated with cyclosporine, and no specific production of NO was found in tolerated skin allografts from neonatally tolerant mice. The production of NO was completely suppressed in graft explants from mice with depleted CD4(+) cells, but remained at a normal level in skin allografts from mice treated with anti-CD8 monoclonal antibody. The treatment of recipients of fully allogeneic skin grafts with 2-amino-5,6-dihydro-6-methyl-4H-1,3-thiazine (AMT), a specific inhibitor of the inducible NO synthase, resulted in a significant prolongation of graft survival. The results thus show CD4(+) T-cell-dependent, alloantigen-induced production of NO by graft-infiltrating macrophages and the role of NO in the rejection reaction. We suggest that this pathway may represent one of the local effector mechanisms of graft rejection.     

Cardiac transplantation in the rat. I. The effect of histocompatibility differences on graft arteriosclerosis

The development of arteriosclerosis is the most serious and common complication in long-term survivors of cardiac transplantation. We have used a variety of inbred rat strains with selected histocompatibility differences to examine the influence of prolonged, mild rejection reactions on the development of pathological changes in long-term cardiac allografts. Heterotopic cardiac allografts were exchanged between rat strains that differed for MHC class I (RT1.A and/or RT1.E) antigens or groups of minor, non-MHC antigens in MHC-compatible congenic combinations. Our results demonstrate that in strain combinations in which the allograft reaction is mild and prolonged, the donor hearts exhibit pathological changes that include a diffuse, interstitial myocardial fibrosis, perivascular fibrosis, and intimal proliferation in arteries of the graft myocardium. The lesions were less prominent in animals with more active rejection and infrequent in strains that differ for class I histocompatibility antigens or syngeneic controls. These results suggest that the comparable pathological changes seen in long-term human cardiac survivors may reflect low-level, persistent allograft reactions rather than factors associated with graft anoxia or effects of immunotherapy to prevent graft rejection.     

MHC matching and mechanisms of alloactivation in corneal transplantation.

BACKGROUND: In human corneal transplantation the value of matching, particularly for MHC class II, is unclear and controversial. The contribution of the direct pathway to T cell activation is also uncertain. We have determined the relative contribution of class I, II and non-MHC antigens to graft rejection and of the direct and indirect pathways to T cell activation in a rat model mimicking human incompatibilities. METHODS: DA (RT1a) strain recipients received fully mismatched PVG (RT1c) strain grafts or grafts from one of three recombinant strains bearing DA MHC genes on a PVG background. Graft survival was assessed and the specificity of T cells generated in the draining lymph nodes was determined in mixed lymphocyte (MLR) proliferation assays. To assess the contribution of the direct pathway, fully mismatched graft were performed and allospecific proliferation was measured after depletion of recipient APC from the MLR reaction. RESULTS: There was no significant difference in survival of grafts between the four grades of mismatch, which ranged from a full mismatch to non-MHC mismatches alone (median survival 12.5, 11, 13 and 12.5 days respectively). In conformity with clinical results, strong secondary responses were generated against targets matched for MHC with the recipient. Depletion of recipient APC from a fully allogeneic secondary MLR did not fully abrogate donor-specific proliferation. CONCLUSIONS: Class II matching is of no benefit in this model. Strong indirect responses to non-MHC mismatches are sufficient to induce the rapid rejection, but the small numbers of class II+ cells in the donor appear sufficient to generate a direct response.