Influence of aging on rolipram-sensitive phosphodiesterase activity and [3H]rolipram binding in the rat brain

Cytolytic T cells were generated in vitro by culturing purified Balb/c CD4+ T cells with irradiated C57Bl/6 (B6) splenocytes plus anti-IL-4 mAb. Matched, noncytotoxic T cells were similarly generated by culturing purified Balb/c CD4+ T cells with irradiated B6 splenocytes plus recombinant murine IL-4. The latter T cells displayed to cytolytic activity, even in lectin-mediated lysis assays, but produced characteristic cytokines upon contact with specific alloantigens. Transfusion of cytolytic T cell populations into Balb/c SCID mice bearing B6 cardiac allografts resulted in acute allograft rejection within 5 to 10 days. Transfusion of noncytolytic T cell populations into Balb/c SCID mice bearing B6 cardiac allografts also resulted in acute allograft rejection within 7 to 10 days. Limiting dilution analysis (LDA) of infiltrating cells recovered from rejected allografts after collagenase digestion demonstrated that the CD4+ T cells retained their cytolytic or noncytolytic functional phenotypes in vivo throughout the rejection process. These data demonstrate that isolated CD4+ T cell populations can promote rapid acute cardiac allograft rejection, and that cytolytic activity is not necessary for this acute rejection response.     

Rejection of cardiac allografts by T cells expressing a restricted repertoire of T-cell receptor V beta genes

We have recently shown that T cells infiltrating cardiac allografts early in graft rejection use a limited T-cell receptor (TCR) V beta repertoire. In this study we tested whether this limited repertoire of V beta genes is important for graft rejection. A cell line, AL2-L3, was established from LEW lymphocytes infiltrating ACI heart allografts 2 days after transplantation. This cell line is composed of CD4+ T cells that primarily recognize the class II RTI.B major histocompatibility complex (MHC) molecule expressed by the donor graft. This cell line precipitated acute rejection of donor hearts with a median survival time (MST) of 10.5 days following adoptive transfer to sublethally irradiated LEW recipients. This rate of graft rejection was significantly (P < 0.0007) accelerated when compared with a MST of 60 days for allografts in irradiated control recipients. The AL2-L3-mediated acceleration of graft rejection was donor specific as WF third-party heart allografts were rejected with a delayed tempo (MST = 28.5 days). The V beta repertoire of this cell line was primarily restricted to the expression of V beta 4, 15 and 19 genes. The nucleotide sequence analysis of the beta-chain cDNAs from this cell line demonstrated that the restricted use of the V gene repertoire was not shared with the N, D and J regions. A wide variety of CDR3 loops and J beta genes were used in association with selected V beta genes. These data provide evidence for the role a restricted repertoire of V beta genes plays in cardiac allograft rejection in this model. The restricted usage of the V beta repertoire in an early T-cell response to allografts may provide the opportunity to therapeutically disrupt the rejection reaction by targeting selected T-cell populations for elimination at the time of organ transplantation.     

On histocompatibility barriers, Th1 to Th2 immune deviation, and the nature of the allograft responses

In the present study, we have sought to determine the basis for the frequent failure of Th1 to Th2 immune deviation to blunt the severity of allograft rejection, as such immune deviation has proven highly effective in the treatment of several T cell-dependent autoimmune states. Our study demonstrates that treating islet allograft recipient mice with anti-IL-12 mAb is highly effective in producing Th1 to Th2 immune deviation in several model systems (i.e., fully MHC, partially MHC, or multiple minor Ag barriers). Nevertheless, anti-IL-12 failed to prolong the engraftment of fully MHC-mismatched islet allografts. However, anti-IL-12-treated recipients carrying MHC-matched but multiple minor Ag-mismatched allografts experienced prolonged engraftment; allograft tolerance was frequently achieved in the DBA/2J (H-2d) to BALB/c (H-2d) strain combination. In another model, in which the host response was dominated by CD4+ T cells responding to donor allopeptides presented upon host APCs in the context of self MHC class II molecules, anti-IL-12 treatment proved to be extremely potent. Thus, Th1 to Th2 immune deviation produces prolonged engraftment as compared with recipients of MHC-mismatched allografts when rejection is dependent upon indirectly presented allogeneic peptides and a reduced mass of responding alloreactive T cells.     

Immunolocalization of acidic fibroblast growth factor and receptors in the tubulointerstitial compartment of chronically rejected human renal allografts

Tubular damage and loss associated with interstitial inflammation and fibrosis may be the most important determinants in chronic renal allograft rejection. To elucidate potential pathophysiologic mechanisms associated with tubulointerstitial lesions, we examined the expression of a fibrogenic cytokine, acidic fibroblast growth factor (FGF-1) and its high-affinity receptors, in both relevant renal transplant controls (n=5) and tissue from patients (n=19) who underwent nephrectomy after graft loss, secondary to chronic rejection. In situ hybridization and immunohistochemical analyses demonstrated minimal expression of FGF-1 mRNA and protein in the tubulointerstitial compartment of the normal human kidney. In contrast, tubulointerstitial lesions in kidney allografts experiencing chronic rejection demonstrated the exaggerated appearance of both FGF-1 protein and mRNA in resident inflammatory and tubular epithelial cells. Patterns of staining were consistent throughout tubular compartments and did not appear to be localized to any particular region. The tubulointerstitium in kidneys with findings of chronic rejection also exhibited increased immunodetection of proliferating cell nuclear antigen in the tubular epithelium, inflammatory cell infiltrate, and neovascular structures. The enhanced appearance of FGF-1 and readily detectable fibroblast growth factor receptors suggests that this polypeptide mitogen may serve as an important mediator of growth and repair responses, associated with development of angiogenesis and tubulointerstitial lesions during chronic rejection of human renal allografts.     

Clinicopathologic features of retinoblastoma after primary chemoreduction

BACKGROUND: Cytotoxic T cells can induce target cell lysis and apoptosis by different pathways. The interactions of CD95 antigen (Fas) with its ligand (CD95L) and of tumor necrosis factor (TNF)-alpha with its receptor (TNF-R1) lead to apoptotic cell death. Recently, conflicting studies have been published concerning the expression and the role of CD95L in allograft rejection and tolerance. METHODS: In this study, the intragraft expression of CD95/CD95L and TNF-alpha and the frequency and distribution of apoptotic cells were compared in a model of heterotopic cardiac allograft in the rat in which recipients were either not treated (acute rejection) or pretreated with donor-specific blood transfusion (tolerant). RESULTS: In the acutely rejected allografts, a peak in the expression of CD95L and TNF-alpha and in the number of apoptotic cells was observed during the first week after transplantation; apoptotic cells were confined to graft-infiltrating cells. In the tolerated allografts, however, levels of graft-infiltrating cell apoptosis and CD95L and TNF-alpha expression during the same period of time were dramatically lower. The expression of Fas was constitutive and was not modulated during acute rejection or tolerance. CONCLUSION: This down-regulation of CD95L and TNF-alpha in allografts rendered tolerant by donor-specific transfusion suggests a role for apoptosis-inducing pathways in acute allograft rejection.     

Patterns of allosensitization in allograft recipients: long-term cardiac allograft acceptance is associated with active alloantibody production in conjunction with active inhibition of alloreactive delayed-type hypersensitivity

BACKGROUND: The immunologic characteristics of experimental allograft acceptance remain ill-defined. This study evaluates humoral and cell-mediated immunity in transiently immunosuppressed mice that have accepted cardiac allografts. METHODS: DBA/2-->C57BL/6 heterotopic cardiac allograft recipients were immunosuppressed with either GK1.5 monoclonal antibody or gallium nitrate and monitored for donor-reactive delayed-type hypersensitivity (DTH) assessed by ear challenge and for alloantibody production detected by flow cytometry. RESULTS: Cardiac allograft function continued for >90 days in approximately 50% of GK1.5-treated and 97% of gallium nitrate-treated transplant recipients. All nonsuppressed recipients lost graft function within 7 to 10 days. Among mice that accepted allografts, donor-reactive IgG was produced by about 50% of GK1.5 monoclonal antibody-treated mice and 80% of gallium nitrate-treated mice. None of the these mice exhibited donor-reactive DTH responses, and all could down-regulate third-party DTH responses in a donor alloantigen-dependent manner. This down-regulation is not found in nonsuppressed allograft recipients or in naive mice. Importantly, transfer into SCID mice of splenocytes from mice that accepted allografts, but not naive splenocytes, provided them with a similar ability to accept cardiac allografts, even if the grafts co-expressed third-party alloantigens. CONCLUSIONS: IgG alloantibody production by murine cardiac allograft recipients is not a precise indicator of allosensitization leading to either cardiac allograft rejection or acceptance. However, expression of alloreactive DTH is a reliable indicator of allosensitization leading to acute rejection, and the absence of DTH in association with active DTH down-regulatory mechanisms is a reliable indicator of allograft acceptance in this experimental model. Thus, DTH analysis may hold more promise than alloantibody detection for clinical assessment of posttransplant immune status.     

Importance of T cells to accelerated rejection and acceptance of renal allografts in sensitized rat recipients

BACKGROUND: Sensitized recipients often experience fulminant allograft loss by yet ill-defined cellular and/or humoral immune mechanisms. In this study, we analyzed the contribution of cellular elements, in particular T cells, to the accelerated rejection of renal allografts in sensitized rats. METHODS AND RESULTS: LEW rats sensitized with BN skin grafts died of uremia in 3.3+/-0.9 days after transplantation of a BN kidney, similarly to bilaterally nephrectomized animals. Adoptive transfer of 10(6) graft-infiltrating mononuclear cells as well as their CD25+ subset into otherwise normal LEW recipients accelerated rejection of BN test cardiac allografts (5.4+/-0.5 days to 6.6+/-0.4 days vs. 7.8+/-0.8 days in controls, P<0.0007), while the CD25- population was ineffective (8.0+/-0.6 days, NS). Furthermore, alpha/beta-T-cell receptor (TCR)-targeted therapy with R73 monoclonal antibody abrogated accelerated rejection, and produced long-term survival in sensitized animals treated before kidney engraftment (day -7 to day -1). Long-term survival was associated with an up-regulation of intragraft interleukin-4 and interleukin-10 expression in conjunction with depressed Th-1-type cytokines. In addition, alpha/beta-TCR-targeted therapy even in low subtherapeutic dose decreased IgM alloantibody levels, and prevented the switch from IgM to IgG alloantibody response. CONCLUSIONS: This is the first report that documents the striking efficacy of alpha/beta-TCR-targeted therapy in sensitized rat renal transplant recipients. The results provide evidence for a critical role of T cells for both accelerated rejection and long-term graft survival. Up-regulation of Th2-type cytokine profile may, at least in part, contribute to the acquisition of immune unresponsiveness after alpha/beta-TCR-targeted therapy in this well-defined rat renal transplant model.     

Tolerance induction ameliorates allograft vasculopathy in rat aortic transplants. Influence of Fas-mediated apoptosis

Based on successful induction of donor-specific unresponsiveness by alloantigenic stimulation in several animal models of acute rejection, we hypothesized that similar immune manipulations would also inhibit the evolution of chronic rejection and transplant vasculopathy. To induce immune tolerance, DA rats received a PVG heart allograft and were immunosuppressed with cyclosporine for 30 d. At day 100 the animals were challenged with a PVG aortic allograft after either 1 or 18 h of cold ischemia. 8 wk after the aortic transplantation, the grafts were investigated for morphological changes, infiltrating cells, apoptosis, and Fas-Fas ligand expression. Control allografts showed advanced transplant arteriosclerosis, whereas tolerance-induced aortic allografts displayed reduced neointimal formation, less medial atrophy, fewer apoptotic cells, and fewer Fas- and FasL-expressing cells. Prolonged ischemic storage time did not profoundly alter the morphological changes of the allografts. Fas expression was found in T cells, macrophages, vascular smooth muscle cells, and endothelial cells, whereas FasL was expressed mainly by T cells and macrophages. FasL mRNA expression was evident throughout the entire allograft wall. In conclusion, induction of allospecific tolerance can effectively prevent transplant arteriosclerosis. Cold ischemia damage does not abrogate the beneficial effect of tolerance, but creates a separate identity of mainly endothelial lesions. Furthermore, Fas-mediated apoptosis appears to be involved in the pathological lesions seen in chronic rejection.     

Transplantation immunology: is the manipulation of the cytokine network therapeutically justified?

Classical allograft rejection is a cellular-mediated immune response in which the activation of the CD4+ T helper (Th) cell plays a crucial role. After activation the Th cell produces a variety of cytokines which are essential for initiating allograft rejection. Th cells can be distinguished by their cytokine profile. Th 1 cells produce IL-2 and IFN gamma, which are associated with rejection. Th2 cells are characterized by the production of IL-4 and IL-10, cytokines which are found in models when tolerance is induced. These findings are called the "Th1/Th2 paradigm" and lead to the following hypothesis: Th1 cells are responsible for allograft rejection and manipulation of the cytokine network towards a Th2 type cytokine pattern results in tolerance or delayed rejection. This study attempts to answer the question whether the Th1/Th2 paradigm is a pure association or corresponds to a mechanism which might be used therapeutically. Allograft rejection in the absence of the proinflammatory cytokines IL-2 and IFN gamma occurs almost unaltered. Moreover, supplying the anti-inflammatory cytokines IL-4 and IL-10 did not result in delayed rejection. Therefore, therapeutic manipulation of the very complex cytokine network will most likely fail. Blocking cytokine-independent T cell activation might be a better concept for induction of allograft tolerance.     

Ionic mechanisms mediating the differential effects of methohexital and thiopental on action potential duration in guinea pig and rabbit isolated ventricular myocytes

BACKGROUND: The stress response to injury concept has been proposed as a mechanism of chronic rejection. This hypothesis has been tested with a rat cardiac allograft model in recipients pretreated with donor bone marrow (BM) cells. Chronic rejection is manifested in this BM group by obliterative arteriopathy and the epicardium and endocardium contains lymphocytic infiltrates resembling Quilty lesions. Pretreatment with a liver allograft (the orthotopic liver transplant [OLTx] group) is associated with an absence of chronic rejection in the transplanted heart. METHODS AND RESULTS:. Stress responses in the allograft were assessed by determining heat shock protein (hsp) expression by immunohistology of graft tissues and immunoblot analysis of stromal tissue lysates with monoclonal antibodies (mAb) to mammalian hsp60, the inducible hsp72, the constitutively expressed hsc73, and the grp78 C-terminal sequence KSEKDEL (grp78seq). Immunostaining showed clusters of grp78seq-positive cells in the inflammatory infiltrates of obliterated blood vessels and Quilty lesions in the BM group of cardiac allografts. Such grp78seq-positive cells were not seen in the OLTx group of heart allografts nor in syngrafts. Neither group showed significantly different graft myocyte staining of grp78 or hsp72, whereas hsp60 and hsc73 showed higher expression in the BM group and, to a lesser extent, the OLTx group. The increased expression of hsc73 was seen especially in the obliterated arteries and in myocytes nearby cellular infiltrates. Immunoblot analysis of graft stromal tissue lysates showed additional bands with mAb to hsp60 and hsc73 for the OLTx and especially the BM group. No significant bands were seen for hsp72 and grp78. Lymphocytes isolated from chronically rejecting allografts reacted with irradiated autologous spleen cells in the presence of mycobacterial hsp65 and interleukin-2. Culturing of graft-infiltrating cells with mycobacterial hsp71 and interleukin-2 yielded lymphocyte clones without alloreactivity, but with strong proliferative responsiveness to self-antigen-presenting cells and, only in the presence of mycobacterial hsp71 or murine grp78. This T-cell reactivity seemed to require intact hsp molecules because treatment of hsp71 with proteolytic enzymes, polymyxin, or ATP abrogated this induction of the stimulatory effect of self-antigen-presenting cells. These T cells are similar to the hsp-dependent, autoreactive lymphocytes cloned from acutely rejecting rat allografts. CONCLUSIONS: These findings support the concept that the pathogenesis of chronic rejection involves a stress response and the participation of graft-infiltrating autoreactive T cells that operate under hsp-dependent mechanisms.     

The influence of concordant xenografts on the humoral and cell-mediated immune responses to subsequent allografts in primates

The humoral and cell-mediated immune responses to subsequent allografts were determined in primate recipients after concordant xenotransplantation as a bridge to allotransplantation. Heterotopic heart transplants (n = 4) were performed from cynomolgus monkeys into ABH type-matched olive baboons followed 2 weeks later by allotransplantation from ABH type-matched baboon donors. Allografts were explanted at 8 weeks. All recipients underwent splenectomy at the time of xenotransplantation and received immunosuppression with cyclosporine, azathioprine, and methylprednisolone. Concordant xenotransplantation in these primates did not induce humoral or cell-mediated immune responses that jeopardized subsequent allografts. The degree of xenospecific immune reactivity, as determined by specific cytotoxicity of recipient T-cell lines derived from the xenograft and extent of histologic xenograft rejection, did not predict the severity of subsequent allograft rejection. In two of the four recipients, xenotransplantation induced an alloreactive humoral response against antigens expressed by the B cells of more than 50% of members from a panel of 12 unrelated baboons. In all recipients, priming with xenogeneic splenocytes in vitro induced an accelerated proliferative T-cell response to allogeneic lymphocytes from 16% of this panel. This study affirms the role of concordant xenografts as appropriate biologic bridges to human allotransplantation. However, our results suggest that xenoreactive baboon memory CD4 T cells may recognize major histocompatibility complex class II--like structures shared between the xenogeneic and allogeneic targets. The potential allorecognition induced by a xenograft may affect the process of subsequent allograft donor selection.