Involvement of the Fas (CD95) system in peripheral cell death and lymphoid organ development

Fas-mediated apoptosis is a form of cell death that operates through a Fas-Fas ligand (FasL) interaction. In this study we investigated the role of the Fas system during development of normal and Fas-mutated lymphocytes. Irradiated RAG2-/-recipients were reconstituted with bone marrow cells from B6 and lpr mice (Fas defective) or from B6 and gld mice (FasL defective), and analyzed for long-term development. The results showed a primary role of the Fas system in peripheral cell death and thymic colonization. In the periphery, the interaction in vivo between Fas+ and Fas-T cell populations indicated that cellular homeostasis was defective. Indeed, we observed a FasL-mediated cytotoxic effect on normal-derived T cells, explaining the dominance of lpr T cells in the mixed chimeras. The Fas mutation affected neither cell activation nor cell proliferation, as the effector (Fas-) and target (Fas+) cells behaved similarly with regard to activation marker expression and cell cycle status. However, Fas-T cells failed to seed the periphery and the thymus in the long term. We suggest that this could be due to the fact that FasL is involved in the structural organization of the lymphoid compartment.     

Contribution of Fas ligand to cardiac allograft rejection

Effector mechanisms for allograft injury remain unclear. In the present study, we verified the contribution of Fas and Fas ligand (FasL) to cardiac allograft rejection by utilizing the Fas-deficient lpr or FasL-deficient gld mice as the donor or recipient. Cardiac myocytes prepared from normal mice, but not those from lpr mice, constitutively expressed Fas and were susceptible to FasL-mediated lysis. Survival of cardiac allografts was substantially prolonged when gld or lpr mice were used as the recipient. In contrast, cardiac allografts from lpr mice were normally rejected without a delay. Histological examination of the grafts in the gld or lpr recipients demonstrated a lesser cellular infiltration and much milder myocyte damage. Proliferative response and cytotoxic T lymphocyte induction against the donor-type alloantigens were not impaired in the gld or lpr recipients. These results indicate a substantial contribution of FasL to cardiac allograft rejection, independent of Fas in the grafts. This ralses a possibility that FasL may be more generally involved in tissue damage associated with various diseases than expected from the expression of Fas in the target organs.     

Fas- and FasL-deficient mice are resistant to induction of autoimmune encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is an organ-specific autoimmune disease inducible in susceptible animals by myelin Ag-specific CD4+ Th1 cells. The mechanisms by which these cells induce inflammation and demyelination in the central nervous system (CNS) are incompletely understood. To determine the roles of Fas and FasL in the involvement of CNS autoimmune injury, we determined susceptibility to EAE of Fas-or FasL-deficient mice. Compared with wild-type mice, mice expressing lpr (Fas) and gld (FasL) mutations were relatively resistant to the development of clinical EAE, and this correlated with fewer inflammatory infiltrates and cells undergoing apoptosis in the CNS of the mutant mice. The gld and lpr mice, however, developed significant T cell responses with production of Th1 cytokines in response to the encephalitogenic myelin peptide. These results suggest that the Fas/FasL pathway plays a critical role in the development of EAE probably by mediating apoptosis within the target tissue.     

Up-regulation by ammonium trichloro(dioxoethylene-0,0') tellurate (AS101) of Fas/Apo-1 expression on B16 melanoma cells: implications for the antitumor effects of AS101

It was recently reported that human and mouse melanoma cells express Fas ligand (FasL) but almost no Fas, which may contribute to their immune privilege. AS101 (ammonium trichloro(dioxoethylene-0,0')tellurate), a synthetic immunomodulator with minimal toxicity, was found to have antitumor effects in various tumor models. Our present study shows that AS101 has direct and indirect effects on tumor cells; AS101 inhibits the clonogenicity of B16 melanoma cells in vitro. Moreover, wild-type P53 expression, which is required for induction of Apo-1 expression, increased significantly in AS101-treated cells. We therefore investigated Fas expression in AS101-treated B16 cells and found that Fas, but not FasL, expression was significantly increased; moreover, Fas receptors were functional. Longer incubation with AS101 resulted in spontaneous apoptosis triggered by the Fas-FasL system. To explore the relationship of these results to the antitumor effects of AS101, we injected B16-F10 mouse melanoma cells into syngeneic C57BL/6 mice carrying the lpr mutation in the Fas gene and to gld mutant mice that lack functional FasL. Tumor development in control groups was lowest in the lpr mice, while no difference was observed between gld and wild-type mice. Among the AS101-treated groups, the most pronounced effect appeared in the lpr mice, while the lowest was seen in the gld mutant mice. Our study suggests that AS101 may render melanoma tumor cells more sensitive to Fas/FasL-induced apoptosis and may therefore have clinical potential.     

Prevention of islet allograft rejection with engineered myoblasts expressing FasL in mice

Allogeneic transplantation of islets of Langerhans was facilitated by the cotransplantation of syngeneic myoblasts genetically engineered to express the Fas ligand (FasL). Composite grafting of allogeneic islets with syngeneic myoblasts expressing FasL protected the islet graft from immune rejection and maintained normoglycemia for more than 80 days in mice with streptozotocin-induced diabetes. Graft survival was not prolonged with composite grafts of unmodified myoblasts or Fas-expressing myoblasts. Islet allografts transplanted separately from FasL-expressing myoblasts into the contralateral kidney were rejected, as were similarly transplanted third-party thyroid allografts. Thus, the FasL signal provided site- and immune-specific protection of islet allografts.     

Fas ligand-mediated bystander lysis of syngeneic cells in response to an allogeneic stimulus

Using a mouse allospecific lymph node (LN) CTL (H-2b) response to transplanted cells (H-2k), effector cells were shown to lyse C3H/HeJ or L929-Fas (H-2k) target cells in either a perforin-dependent or a Fas ligand (FasL)-dependent manner. C3H/HeJ.lpr targets or L929 targets lacking Fas were not sensitive to these effectors generated in perforin-deficient (Po) mice. By contrast, C3H/HeJ.lpr target cells and L929 were as responsive as C3H/HeJ and L929-Fas targets to the effectors generated in perforin wild-type (P+/+) mice. To measure potential bystander lysis in allogeneic responses, these same effector LN from either C57BL/6 P+/+ or P(o) mice were examined for lysis of C3H/HeJ (or C3H/HeJ.lpr) or L929-Fas (or L929) cocultured with 51Cr-labeled C57BL/6 (H-2b) target cells. Bystander lysis of C57BL/6 targets was observed only in those allogeneic responses where FasL was the defined mechanism of lysis. By contrast, perforin-mediated lysis was restricted by allo-recognition. Syngeneic (H-2b) targets that were not sensitive to Fas-mediated lysis were not lysed in a bystander fashion. Depletion of subsets of LN Po effectors (b anti-k) demonstrated that CD4+ T cells were primarily responsible for FasL-mediated direct and bystander lysis. FasL-mediated bystander lysis was also observed in H-2k anti-b reactions, except when the effectors were FasL mutant (gld). These data suggest that CTL responses to foreign Ag may evoke a certain amount of collateral damage to local host Fas-sensitive cells.     

Myelin oligodendrocyte glycoprotein-induced autoimmune encephalomyelitis is chronic/relapsing in perforin knockout mice, but monophasic in Fas- and Fas ligand-deficient lpr and gld mice

The expression and action of Fas/Fas ligand (FasL) in multiple sclerosis has been postulated as a major pathway leading to inflammatory demyelination. To formally test this hypothesis, C57BL/6-lpr and -gld mice, which due to gene mutation express Fas and FasL in an inactive form, were immunized with myelin oligodendrocyte glycoprotein peptide(35-55). Whereas in wild-type C57BL/6 mice, experimental autoimmune encephalomyelitis (EAE), was chronic/relapsing, EAE in lpr and gld mice was characterized by a lower incidence of disease and a monophasic course. This contrasts with C57BL/6 perforin knockout mice, which showed the most severe form of EAE of all mouse strains tested, the course being chronic relapsing. The difference noted cannot be attributed to an involvement of FasL in oligodendrocyte damage since oligodendrocytes are insensitive to FasL-mediated cytotoxicity in vitro, and since in the acute phase of EAE gld mice also show CD4+ T cell infiltrates with associated demyelination in brain and spinal cord. Unlike oligodendrocytes, astrocytes were killed by FasL in vitro. It remains to be established whether this latter finding explains the different disease course of lpr and gld mice compared to wild-type and perforin knockout mice.     

Genomic amplification of a decoy receptor for Fas ligand in lung and colon cancer

Fas ligand (FasL) is produced by activated T cells and natural killer cells and it induces apoptosis (programmed cell death) in target cells through the death receptor Fas/Apol/CD95. One important role of FasL and Fas is to mediate immune-cytotoxic killing of cells that are potentially harmful to the organism, such as virus-infected or tumour cells. Here we report the discovery of a soluble decoy receptor, termed decoy receptor 3 (DcR3), that binds to FasL and inhibits FasL-induced apoptosis. The DcR3 gene was amplified in about half of 35 primary lung and colon tumours studied, and DcR3 messenger RNA was expressed in malignant tissue. Thus, certain tumours may escape FasL-dependent immune-cytotoxic attack by expressing a decoy receptor that blocks FasL.     

Anterior chamber inoculation of splenocytes without Fas/Fas-ligand interaction primes for a delayed-type hypersensitivity response rather than inducing anterior chamber-associated immune deviation

The inoculation of antigens into the anterior chamber (AC) of the eye induces an antigen-specific immune response that inhibits delayed-type hypersensitivity (DTH). This regulatory response is known as anterior chamber-associated immune deviation (ACAID). The ACAID response appears to be complex, as it can be elicited by a wide variety of soluble and cell-associated antigens, including foreign, self, tumor, and alloantigens. To evaluate the contribution of Fas/Fas ligand (FasL) interaction to the induction of ACAID to alloantigens, gld and lpr mutant mice were used in conjunction with normal C3H, MRL, and BALB/c mice. ACAID was induced by inoculation of non-irradiated splenocytes from donor mice into the AC of various recipients. After 1 week, recipients were primed intradermally with donor splenocytes. One week later DTH was measured by ear swelling. C3Hgld mutants lacking functional FasL did not develop ACAID after the AC inoculation of BALB/c splenocytes. Conversely, the AC inoculation sensitized these mutants. MRL/pr mutants, which lack Fas, developed ACAID following inoculation of BALB/c cells. AC inoculation of lpr splenocytes did not induce ACAID, but sensitized C3H recipients. Treatment of the AC inoculum with an anti-Fas antibody blocked ACAID induction in a transient manner, as the recipients developed ACAID later. These results show that interaction of the Fas and FasL is required to induce ACAID to allogeneic cells. In the absence of Fas expression on donor splenocytes, or FasL expression by the recipient, AC inoculation primes for a DTH response rather than inducing ACAID.     

Polymorphism of murine Fas ligand that affects the biological activity

Fas ligand (FasL) is a member of the tumor necrosis factor family and induces apoptosis in Fas (CD95)-bearing target cells. In this study, we generated several mAbs that react with mouse FasL (mFasL) and characterized their functional properties. One of these mAbs, K10, specifically reacted with mFasL derived from C57BL/6 (B6) mice, but not that from BALB/c mice as estimated by surface staining and blocking of cytotoxic activities of mFasL transfectants, suggesting a polymorphism of mFasL. Sequence analysis of mFasL cDNA from several strains revealed that BALB/c and DBA/2 mice have three nucleotide differences from the known B6 and C3H sequences, which result in two amino acid substitutions (Thr-184 --> Ala-184 and Glu-218 --> Gly-218) in the extracellular region. Analysis of the K10 reactivity and genotyping by PCR-restriction fragment length polymorphism revealed that inbred mice segregate into the following two allotypes: mFasL.1 (B6, C3H, MRL, SJL, NOD, NZB, NZW) and mFasL.2 (BALB/c, DBA/1, DBA/2). Interestingly, COS7 cells expressing BALB/c FasL lysed Fas-bearing target cells more efficiently than those expressing B6 FasL. Furthermore, BALB/c-derived CD8-FasL fusion protein, which is composed of the extracellular domains of human CD8alpha and mFasL, exhibited 9-fold higher specific activity than did B6-derived CD8-FasL. These results suggest that in mFasL.2 mice the Fas/FasL system works more effectively than in mFasL.1 mice.     

Fas and Fas ligand interaction is necessary for human osteoblast apoptosis

We investigated the cellular and humoral interactions between peripheral blood mononuclear cells (PBMCs) and human osteoblasts, leading to apoptosis of osteoblasts. Human osteoblastic cell line MG63 and human primary osteoblast-like cells obtained from biopsy specimens were used in this study. PBMCs were isolated from healthy donors and cultured with or without stimulation by recombinant interleukin-2 followed by 12-o-tetradecanoylphorbol 13-acetate with ionomycin. Fas was functionally expressed on MG63 and primary osteoblast-like cells. Activated PBMCs expressed Fas ligand (FasL) strongly on their surface and killed MG63 and primary osteoblast-like cells. Cultured supernatants of activated PBMCs also induced apoptotic cell death of MG63 and primary osteoblast-like cells. In contrast, both unstimulated PBMCs and cultured supernatants of unstimulated PBMCs did not induce apoptosis of these cells. Furthermore, the cytotoxic effect and induction of apoptosis against MG63 and primary osteoblast-like cells by activated PBMCs and cultured supernatants were inhibited significantly by human Fas chimeric protein. Our data showed that human osteoblasts expressed Fas fuctionally and both membrane-type and soluble form FasL from activated PBMCs induced apoptosis of these cells, providing the one possible mechanism of bone loss in inflammatory diseases such as rheumatoid arthritis.     

Fas-mediated cytotoxicity is not required for rejection of murine nonvascularized heterotopic cardiac allografts

BACKGROUND: Using mice with loss-of-function mutations in the Fas and Fas ligand (FasL) genes (lpr and gld, respectively) in transplantation experiments has resulted in contradictory findings concerning the role of Fas/FasL-mediated cytotoxicity in allograft rejection. The observation that these mutant mice develop an abnormal lymphocyte phenotype with increasing age that is hyporesponsive in vitro led us to examine the possibility that this characteristic might explain seemingly discordant observations in the literature. Therefore, to distinguish between the effects of Fas/FasL pathway disruption and the effects of immune senescence on in vivo cytotoxicity and allograft rejection, we evaluated the survival of cardiac allografts in gld, lpr, and wild-type mice of varying ages. METHODS: Six- to 21-week-old C3H, C3H/HeJ-Fasl(gld), C57B1/6, and B6.MRL-Fas(lpr) recipients were transplanted with heterotopic, nonvascularized cardiac allografts from neonatal Balb/c, C3H, C57Bl/6, and B6.MRL-Fas(lpr) donors. Mixed lymphocyte reactions were performed in naive gld, lpr, and wild-type animals, 6 and 12 weeks of age. Rejected allografts in gld, lpr, and wild-type recipients and functioning syngeneic transplants were evaluated for intragraft apoptosis by a DNA fragmentation detection assay. RESULTS: Graft survival was not significantly different between 6-week-old gld and lpr recipients and their respective wild-type controls. However, allograft rejection was delayed significantly in older (13-week) gld mice compared with age-matched wild-type mice (P=0.02) or young (6-week) gld animals (P=0.04). Similarly, 21-week-old lpr mice exhibited prolonged graft survival compared with 6-week-old lpr animals (P=0.01). Reduced alloreactive proliferative responses in 12-week-old gld and lpr mice were observed when compared with age-matched wild-type strains. Rejecting allografts displayed a similar level of intragraft apoptotic cells regardless of mutant or wild-type phenotype or age of recipient. CONCLUSIONS: The findings of this study confirm that Fas/FasL-mediated cytotoxicity is not required for murine cardiac allograft rejection. Our findings also demonstrate that the observed delayed graft rejection in lpr and gld mice is a consequence of an age-related alteration of the immune system, specific to gld and lpr mice and associated with an in vivo and in vitro hyporeactivity to alloantigens.     

Administration of IL-12 induces a CD3+ CD4- CD8- B220+ lymphoid population capable of eliciting cytolysis against Fas-positive tumor cells

The present study investigates the effect of IL-12 administration on the generation of lymphoid cells that exhibit cytotoxicity against tumor cells expressing Fas Ag. Systemic injection of rIL-12 into BALB/c or (B6C3)F1 mice bearing syngeneic CSA1M or OV-HM tumor induced complete tumor regression. CSA1M tumor cells expressed Fas Ag, and exposure of these cells to IFN-gamma enhanced Fas expression. In contrast, Fas Ag was hardly detected on OV-HM cells even after IFN-gamma exposure. Only CSA1M cells were lysed by anti-Fas mAb or cells expressing Fas ligand (FasL), indicating that Fas on CSA1M cells is functional in mediating cell death. An increase in the frequency of lymphoid cells characterized as CD3+ CD4- CD8- B220+ was observed in spleens from both CSA1M and OV-HM tumor-bearing mice after IL-12 treatment. A splenic population enriched in cells with these unique phenotypes exhibited considerable degrees of cytotoxicity against Fas+ CSA1M, but not against Fas- OV-HM tumor cells. The lysis of CSA1M cells was almost completely blocked by addition of Fas-Fc, a fusion protein between the extracellular domain of mouse Fas and the Cgamma1 domain of human Ig. Regressing CSA1M and OV-HM tumor masses after IL-12 treatment exhibited a massive lymphoid cell infiltration and expressed significant levels of FasL mRNA, suggesting the infiltration of FasL-expressing cells to tumor sites. These results indicate that IL-12 induces the expansion of lymphoid cells that exhibit FasL-mediated cytolytic activity and accumulate into regressing tumor masses.     

Fas-Fas ligand-based interactions between tumor cells and tumor-specific cytotoxic T lymphocytes: a lethal two-way street

In the current study, we investigated the repercussions of the interaction between tumor cells (LSA) and the tumor-specific cytotoxic T lymphocyte (CTL) (PE-9) when both expressed Fas and Fas ligand (FasL). The CTL clone, PE-9, expressed high levels of Fas and FasL upon activation through the T-cell receptor (TCR). Furthermore, the activated PE-9 cells used both perforin- and FasL-based pathways to kill Fas-positive (Fas+) LSA tumor cells. Interestingly, LSA tumor cells also constitutively expressed FasL but not perforin, and killed Fas+ PE-9 CTLs and Fas+ but not Fas-negative (Fas-) activated T cells and thymocytes, as detected using the JAM test. PE-9 CTLs, cultured for 24 hours in the presence of cell lysates of FasL-bearing LSA cells but not FasL-deficient P815 cells, exhibited significant apoptosis as detected using the TUNEL method. Moreover, another FasL+ T-cell lymphoma line, EL-4, induced apoptosis in Fas+ but not in Fas- T cells in a similar fashion. The current study demonstrates for the first time that not only can the tumor-specific CTL mediate Fas-based killing of tumor cells, but FasL+ tumor cells can kill the Fas+ tumor-specific CTL. Thus, the survival of the tumor or the host may depend on which cell can accomplish this task more efficiently. The current study also suggests that FasL-based killing of CTLs by specific tumor cells may constitute a major limiting factor in successful immunotherapy.     

Microglia are more susceptible than macrophages to apoptosis in the central nervous system in experimental autoimmune encephalomyelitis through a mechanism not involving Fas (CD95)

Morphological studies have shown that macrophages and microglia undergo apoptosis in the central nervous system (CNS) in acute experimental autoimmune encephalomyelitis (EAE) in the Lewis rat. To assess the relative levels of macrophage and microglial apoptosis, and the molecular mechanisms involved in this process, we used three-colour flow cytometry to identify CD45lowCD11b/c+ microglial cells and CD45highCD11b/c+ macrophages in the inflammatory cells isolated from the spinal cords of Lewis rats 13 days after immunization with myelin basic protein (MBP) and complete Freund's adjuvant. Simultaneously, we analyzed the DNA content of these cell populations to assess the proportions of cells undergoing apoptosis and in different stages of the cell cycle or examined their expression of three apoptosis-regulating proteins, i.e. Fas (CD95), Fas ligand (FasL) and Bcl-2. Microglia were highly vulnerable to apoptosis and were over-represented in the apoptotic population. Macrophages were less susceptible to apoptosis than microglia and underwent mitosis more frequently than microglia. The different susceptibilities of microglia and macrophages to apoptosis did not appear to be due to variations in Fas, FasL or Bcl-2 expression, as the proportions of microglia and macrophages expressing these proteins were similar, and were relatively high. Furthermore, in contrast to T cell apoptosis, apoptosis of microglia/macrophages did not occur more frequently in cells expressing Fas or FasL, or less frequently in cells expressing Bcl-2. These results indicate that the apoptosis of microglia and CNS macrophages in EAE is not mediated through the Fas pathway, and that Bcl-2 expression does not protect them from apoptosis. Expression of FasL by macrophages and microglia may contribute to the pathogenesis and immunoregulation of EAE through interactions with Fas+ oligodendrocytes and Fas+ T cells. The high level of microglial apoptosis in EAE indicates that microglial apoptosis may be an important homeostatic mechanism for controlling the number of microglia in the CNS following microglial activation and proliferation.     

Oxidized LDL activates fas-mediated endothelial cell apoptosis

Oxidized low density lipoproteins (OxLDL) promote chronic inflammatory responses in the vasculature that give rise to atherosclerotic plaques. Fas ligand (FasL) is naturally expressed on the vascular endothelium where it can induce apoptosis in Fas-expressing immune cells as they enter the vessel wall. Although vascular endothelial cells are normally resistant to Fas-mediated cell death, OxLDL were shown to induce apoptosis in cultured endothelial cells and endothelium of arterial explants by a process that could be inhibited with Fas L neutralizing antibodies. OxLDL-induced cell death was also reduced in the aortic endothelium cultured from gld (FasL-/-) and lpr (Fas-/-) mice as compared with wild-type mice. OxLDL acted by sensitizing endothelial cells to death signals from the Fas receptor. Thus, the ability of OxLDL to promote Fas-mediated endothelial cell suicide may be a feature that contributes to their atherogenicity.     

Sensitization of human bladder cancer cells to Fas-mediated cytotoxicity by cis-diamminedichloroplatinum (II)

PURPOSE: The resistance of bladder cancer to anticancer chemotherapeutic drugs is a major problem. Several immunotherapeutic approaches have been developed to treat drug-resistant tumor cells. The Fas antigen (Fas)-Fas ligand pathway is involved in cytotoxic T lymphocyte and natural killer cell-mediated cytotoxicity. Like the Fas ligand, anti-Fas monoclonal antibody (mAb) induces apoptosis in tumor cells expressing Fas. Several anticancer drugs also mediate apoptosis and may share with Fas common intracellular pathways leading to cell killing. We reasoned that treatment of drug-resistant cancer cells with a combination of anti-Fas mAb and drugs might overcome their resistance. This study has investigated whether anticancer drugs synergize with anti-Fas mAb in cytotoxicity against bladder cancer cells. MATERIALS AND METHODS: Cytotoxicity was determined by a 1-day microculture tetrazolium dye assay. Synergy was assessed by isobolographic analysis. RESULTS: Treatment of the T24 human bladder cancer cell line with anti-Fas mAb in combination with 5-fluorouracil, mitomycin C or methotrexate did not overcome resistance to these agents. However, treatment of T24 tumor cells with a combination of anti-Fas mAb and cisdiamminedichloroplatinum (II) (CDDP) resulted in a synergistic cytotoxic effect. In addition, the CDDP-resistant T24 line (T24/CDDP) was sensitive to treatment with a combination of anti-Fas mAb and CDDP. Synergy by combination of anti-Fas mAb and CDDP was also achieved in three other bladder cancer lines and four freshly derived human bladder cancer cells. The combination of anti-Fas mAb and carboplatin also resulted in a synergistic cytotoxic effect on T24 cells; however, the combination of anti-Fas mAb and trans-diamminedichloroplatinum (II) resulted in an additive cytotoxic effect. Treatment with CDDP enhanced the expression of Fas on T24 cells. The synergy achieved in cytotoxicity with anti-Fas mAb and CDDP was also achieved in apoptosis. Incubation of T24 cells with anti-Fas mAb increased the intracellular accumulation of CDDP. Treatment of freshly isolated bladder cancer cells with CDDP enhanced their susceptibility to lysis by autologous lymphocytes. CONCLUSIONS: This study demonstrates that combination treatment of bladder cancer cells with anti-Fas mAb and CDDP overcomes their resistance. Synergy was achieved with established CDDP-resistant bladder cancer cells and freshly isolated bladder cancer cells. In addition, the sensitization required low concentrations of CDDP, thus supporting the potential in vivo application of combination of CDDP and immunotherapy in the treatment of CDDP- and/or immunotherapy-resistant bladder cancer.