Membrane-bound and soluble Fas ligands have opposite functions in photoreceptor cell death following separation from the retinal pigment epithelium.

Fas ligand (FasL) triggers apoptosis of Fas-positive cells, and previous reports described FasL-induced cell death of Fas-positive photoreceptors following a retinal detachment. However, as FasL exists in membrane-bound (mFasL) and soluble (sFasL) forms, and is expressed on resident microglia and infiltrating monocyte/macrophages, the current study examined the relative contribution of mFasL and sFasL to photoreceptor cell death after induction of experimental retinal detachment in wild-type, knockout (FasL-/-), and mFasL-only knock-in (ΔCS) mice. Retinal detachment in FasL-/- mice resulted in a significant reduction of photoreceptor cell death. In contrast, ΔCS mice displayed significantly more apoptotic photoreceptor cell death. Photoreceptor loss in ΔCS mice was inhibited by a subretinal injection of recombinant sFasL. Thus, Fas/FasL-triggered cell death accounts for a significant amount of photoreceptor cell loss following the retinal detachment. The function of FasL was dependent upon the form of FasL expressed: mFasL triggered photoreceptor cell death, whereas sFasL protected the retina, indicating that enzyme-mediated cleavage of FasL determines, in part, the extent of vision loss following the retinal detachment. Moreover, it also indicates that treatment with sFasL could significantly reduce photoreceptor cell loss in patients with retinal detachment.

Thymic stromal lymphopoietin (TSLP)-mediated dermal inflammation aggravates experimental asthma.

Individuals with one atopic disease are far more likely to develop a second. Approximately half of all atopic dermatitis (AD) patients subsequently develop asthma, particularly those with severe AD. This association, suggesting a role for AD as an entry point for subsequent allergic disease, is a phenomenon known as the "atopic march." Although the underlying cause of the atopic march remains unknown, recent evidence suggests a role for the cytokine thymic stromal lymphopoietin (TSLP). We have established a mouse model to determine whether TSLP plays a role in this phenomenon, and in this study show that mice exposed to the antigen ovalbumin (OVA) in the skin in the presence of TSLP develop severe airway inflammation when later challenged with the same antigen in the lung. Interestingly, neither TSLP production in the lung nor circulating TSLP is required to aggravate the asthma that was induced upon subsequent antigen challenge. However, CD4 T cells are required in the challenge phase of the response, as was challenge with the sensitizing antigen, demonstrating that the response was antigen specific. This study, which provides a clean mouse model to study human atopic march, indicates that skin-derived TSLP may represent an important factor that triggers progression from AD to asthma.

Sp1 is the major fasl gene activator in abnormal CD4(-)CD8(-)B220(+) T cells of lpr and gld mice.

The abnormal CD4(-)CD8(-)TCRalpha beta(+)B220(+) double-negative (DN) T cells that accumulate in lpr and gld mice are refractory to TCR cross-linking and IL-2 stimulation, yet they have an activated phenotype and express a high level of fasl mRNA. Specific binding sites for Sp1, NFAT, Egr, and NF-kappaB have been identified in the promoter region of the fasl gene. To determine the critical factor for fasl gene activation, fasl promoter reporter and mutant constructs were transiently transfected into the abnormal DN T cells. The data demonstrate that the Sp1 binding site is the major response element that regulates fasl promoter activity. Moreover, the abnormal DN T cells contain in their nuclei a high level of Sp1, a low level of NFAT and NF-kappaB, and a very low level of Egr. Ectopic expression of Egr-3 but not Sp1 protein in the abnormal DN T cells enhanced fasl promoter activity, suggesting that the Egr but not Sp1 was limiting for fasl gene activation. Comparison between the abnormal DN T cells and the Sertoli TM4 cells showed a strong correlation between Sp1 expression and fasl mRNA level and FasL function. Our study has identified Sp1 as the major transcription factor responsible for fasl gene activation in the abnormal DN T cells that are defective in signal transduction through TCR and IL-2R, thereby, implicating a novel regulatory pathway for fasl gene activation during the physiological development and elimination of the abnormal DN T cells.

Fas ligand engagement of resident peritoneal macrophages in vivo induces apoptosis and the production of neutrophil chemotactic factors.

Fas ligand (FasL) is a potent proapoptotic type-II transmembrane protein that can cause cell death in Fas+ target populations. Despite the presumed "silent" nature of apoptotic cell death, forced expression of FasL can induce a dramatic inflammatory response. To elucidate the in vivo mechanism(s) linking FasL and inflammation, we used a membrane-bound cell-free form of FasL (mFasL-vesicle preparation (VP)). We found that i.p. injection of FasL-microvesicles led to the rapid activation and subsequent demise of Mac1(high) resident peritoneal macrophages. Apoptosis of Mac1(high) peritoneal macrophages was observed within 0.5 h of mFasL-VP injection and correlated with the detection of increased macrophage inflammatory protein (MIP)-2 levels in peritoneal lavage fluid as well as induced RNA expression of IL-1beta, MIP-2, MIP-1alpha, and MIP-1beta. In vitro culture of purified peritoneal populations identified Mac1(high) cells as the major cytokine/chemokine producers in response to mFasL-VP. Purified Mac1(high) cells exposed to FasL could restore the ability of Fas-deficient mice to mount an inflammatory response. Our data demonstrate that the FasL-mediated inflammatory response starts with the production of proinflammatory mediators by preapoptotic resident tissue macrophages and suggest a general mechanism responsible for neutrophil inflammation seen in cases of FasL-expressing allografts.

Apoptosis-inducing membrane vesicles. A novel agent with unique properties.

The CD95 ligand (FasL) transmembrane protein is found on activated T cells and cells outside the immune system. A well-known turnover process of membrane FasL is mediated by matrix metalloproteinase, which generates soluble FasL (sFasL). Here, we demonstrate that membrane FasL turnover occurs effectively through the release of membrane vesicles. Quantitative analysis indicates that this process is as effective as sFasL release for FasL-3T3 cells but somewhat less effective for FasL-expressing T cells. The apoptosis-inducing membrane vesicles display unique properties not found in FasL-expressing cells and sFasL. Unlike sFasL, vesicle-associated FasL remained bioactive, killing the same panel of targets that are susceptible to FasL-expressing cells. In contrast to FasL-expressing T cells, FasL-mediated killing by vesicles do not involve LFA-1/ICAM interaction and do not depend on de novo protein synthesis. These observations indicate that the release of FasL-bearing vesicles contributes to the turnover of cell-associated FasL, but the impact of the bioactive FasL-expressing vesicles on the function of cell-associated FasL is different from that of sFasL.

CD95 (Fas) ligand-expressing vesicles display antibody-mediated, FcR-dependent enhancement of cytotoxicity.

Bioactive Fas ligand (FasL)-expressing vesicles were generated (vesicle preparation, VP) from two cell lines overexpressing FasL. The effect of NOK-1 anti-FasL mAb (mouse IgG1) on the cytotoxicity of FasL VP against various targets was determined. At high concentrations (1-10 microg/ml), NOK-1 inhibited the cytotoxicity. By contrast, NOK-1 in the dose range of 1-100 ng/ml significantly enhanced cytotoxicity against the FcR(+) LB27.4, M59, and LF(+) targets, but not the FcR(-) Jurkat and K31H28 hybridoma T cell targets. The ability to enhance FasL VP-mediated cytotoxicity could be blocked by the FcR-specific mAb 2.4G2. Enhancement was also observed with FcR(+) A20 B lymphoma but not with the FcR(-) A20 variant. Enhancement of FasL VP cytotoxicity was observed with five IgG anti-FasL mAbs, but not with an IgM anti-FasL mAb. Inhibition was observed with high doses of all mAb except the IgG anti-FasL mAb G247-4, which is specific to a segment outside the FasL binding site. Interestingly, under identical conditions but in the presence of 2.4G2, G247-4 inhibited the cytotoxicity of FasL VP. In addition, G247-4 inhibited the FasL VP-mediated killing of FcR(-) Jurkat. The data demonstrate that FasL-expressing bioactive vesicles display a property heretofore unknown in bioactive agents that express FasL-mediated cytotoxicity. The mechanism of the Ab-mediated, FcR-dependent enhancement of cytotoxicity of bioactive vesicles and its physiological significance are discussed.

Immune complexes present in the sera of autoimmune mice activate rheumatoid factor B cells.

The fate of an autoreactive B cell is determined in part by the nature of the interaction of the B cell receptor with its autoantigen. In the lpr model of systemic autoimmunity, as well as in certain human diseases, autoreactive B cells expressing rheumatoid factor (RF) binding activity are prominent. A murine B cell transgenic model in which the B cell receptor is a RF that recognizes IgG2a of the j allotype (IgG2aj), but not the b allotype, was used in this study to investigate how the form of the autoantigen influences its ability to activate B cells. We found that sera from autoimmune mice, but not from nonautoimmune mice, were able to induce the proliferation of these RF+ B cells but did not stimulate B cells from RF- littermate controls. The stimulatory factor in serum was found to be IgG2aj, but the IgG2aj was stimulatory only when in the form of immune complexes. Monomeric IgG2aj failed to stimulate. Immune complexes containing lupus-associated nuclear and cytoplasmic autoantigens were particularly potent B cell activators in this system. Appropriate manipulation of such autoantibody/autoantigen complexes may eventually provide a means for therapeutic intervention in patients with certain systemic autoimmune disorders.

Double mutant MRL-lpr/lpr-gld/gld cells fail to trigger lpr-graft-versus-host disease in syngeneic wild-type recipient mice, but can induce wild-type B cells to make autoantibody.

Lethally irradiated mice reconstituted with histocompatible stem cells from Fas-deficient MRL/lpr mice develop a wasting syndrome reminiscent of chronic graft-versus-host disease. However, reconstitution with double Fas-/Fas ligand (FasL)-deficient stem cells does not result in wasting disease, demonstrating that FasL expression is an important component of the effector mechanisms leading to this syndrome. In the absence of wasting disease double-deficient T cells can induce wild-type B cells to make autoantibodies. These data indicate that autoantibody production is regulated by FasL-expressing T cells, and that Fas-sufficient wild-type B cells differ from Fas-deficient Ipr cells only with regard to their sensitivity to FasL.

TRAIL expression in vascular smooth muscle.

TRAIL is a cell-associated tumor necrosis factor-related apoptosis-inducing ligand originally identified in immune cells. The ligand has the capacity to induce apoptosis after binding to cell surface receptors. To examine TRAIL expression in murine vascular tissue, we employed in situ hybridization and immunohistochemistry. In these studies, we found that TRAIL mRNA and protein were specifically localized throughout the medial smooth muscle cell layer of the pulmonary artery. Notably, a similar pattern of expression was observed in the mouse aorta. Consistent with these findings, we found that cultures of primary human aorta and pulmonary artery smooth muscle cells express abundant TRAIL mRNA and protein. We also found that these cells and endothelial cells undergo cell lysis in response to exogenous addition of TRAIL. Last, we confirmed that TRAIL specifically activated a death program by confirming poly(ADP ribose) polymerase cleavage. Overall, we believe that these findings are relevant to understanding the factors that regulate cell turnover in the vessel wall.

Opposing effects of transmembrane and soluble Fas ligand expression on inflammation and tumor cell survival.

Fas ligand (FasL) has been shown to mediate both apoptotic and inflammatory reactions. To rigorously assess the physiological role of different forms of the FasL molecule with regard to these two distinct processes, we isolated stably transfected lymphoma cell lines that expressed either murine wild-type FasL, membrane-only FasL, or functionally distinct forms of soluble FasL. First, the ability of these lines to induce an inflammatory response was assessed in vivo by injecting the transfectants intraperitoneally and measuring subsequent neutrophil extravasation into the peritoneal cavity. Second, lines were assessed by injecting the transfectants subcutaneously and monitoring their growth as solid tumors. Our study clearly demonstrated that the extent of inflammation induced by the transfectants directly correlated with their relative cytotoxic activities. A neutrophil response could only be elicited in mice with intact Fas death domains although Fas expression by the neutrophils was not essential. Lymphoma cells expressing the soluble FasL form corresponding to the natural cleavage product could not trigger apoptosis and did not induce a neutrophil response. In contrast to the other FasL transfectants, these cells survived as tumor transplants. However, expression of soluble FasL was not benign, but actually suppressed the inflammatory response and protected other transfectants from the effector mechanisms elicted by membrane-bound FasL.

Protection of T cells from activation-induced cell death by Fas+ B cells.

Naive CD4+ T cells proliferate strongly in response to stimulation by superantigens such as staphylococcal enterotoxin B (SEB). However, when these same cells revert to a resting phenotype and are subjected to restimulation with either SEB or anti-CD3, the majority of these SEB-responsive cells undergo Fas ligand (FasL)-mediated activation-induced cell death (AICD). We investigated the impact of Fas expression on T cell AICD by utilizing B cell stimulators that lacked functional FasL and either expressed or did not express the Fas receptor. Our results indicate that B cells play an important role in modulating the level of T cell AICD via the Fas/FasL pathway. Activated B cells expressing high levels of Fas receptor can redirect the FasL expressed by T cells primed to undergo AICD away from the T cells and prevent the induction of AICD in these cells. Furthermore, B cells stimulated through both the CD40 receptor and membrane IgM appear to mediate a stronger protective effect on T cells by virtue of their resistance to FasL-mediated cytolysis. These observations suggest a mechanism by which normal B cell and T cell responses to foreign antigen are maintained, while responses to self antigen are not.

Accelerated development of IgG autoantibodies and autoimmune disease in the absence of secreted IgM.

Individuals with systemic lupus erythematosus and rheumatoid arthritis are characterized by the presence of high levels of circulating IgM and IgG autoantibodies. Although IgG autoantibodies often are pathogenic, the role of IgM autoantibodies in autoimmune disease is not clear. Using mice that are unable to secrete IgM but are able to express surface IgM and IgD and to secrete other classes of immunoglobulins, we examined the effect of the absence of secreted IgM in the development of IgG autoantibodies and autoimmune disease in lupus-prone lymphoproliferative (lpr) mice. Compared with regular lpr mice, lpr mice that lack secreted IgM developed elevated levels of IgG autoantibodies to double-stranded DNA and histones and had more abundant deposits of immune complexes in the glomeruli; they also suffered more severe glomerulonephritis and succumbed to the disease at an earlier age. Similarly, the absence of secreted IgM also resulted in an accelerated development of IgG autoantibodies in normal mice. These findings suggest that secreted IgM, including IgM autoantibodies produced naturally or as part of an autoimmune response, may lessen the severity of autoimmune pathology associated with IgG autoantibodies.

FasL promoter activation by IL-2 through SP1 and NFAT but not Egr-2 and Egr-3.

Recently activated peripheral T cells treated with IL-2 for 4 days expressed Fas ligand (FasL)-mediated cytotoxicity. These IL-2-treated T cells had high nuclear expression of SP1 and NFAT, but lacked the Egr-2 and Egr-3 that could be induced by anti-CD3 stimulation and had been implicated in FasL gene activation. A minimal promoter region that responded to IL-2 was identified by transient transfection assays using deletion mutants. The data suggests that the GGGCGGAAA site present in the 5' end of the minimal FasL promoter is critical to IL-2-induced FasL gene activation. The GGGCGGAAA sequence contains an overlapping site used by two transcription factor families, one (GGGCGG) for the SP1 family and the other (GGAAA) for the NFAT family. FasL promoter activity was partially but statistically significantly reduced with constructs mutated at either site. More activity was lost with a construct mutated at both sites. In contrast, mutation at the Egr site had no effect on IL-2-induced FasL promoter activity. Our study identified a new FasL promoter site responding to IL-2-induced SP1 and NFAT factors. Furthermore, the nuclei of IL-2-treated cells express SP1 and NFAT, but not Egr-2 and Egr-3, for FasL gene activation.

Characterization of a novel cis-element that regulates Fas ligand expression in corneal endothelial cells.

Constitutively expressed Fas ligand in the cornea, Sertoli cell of the testes, Paneth cell of the intestines, and Clara cell of the airway protect surrounding parenchymal tissue by inducing apoptosis of Fas(+) immune cells during inflammatory reactions. Indeed, the action of corneal Fas ligand has been suggested to facilitate successful allogeneic cornea transplantation. To study the transcriptional regulation of Fas ligand in the eye, we employed an immortalized mouse corneal endothelial cell line (C3H3) that constitutively expresses Fas ligand. By deletion analysis of the mouse Fas ligand promoter, gel mobility shift assays, and site-directed mutagenesis, we found that a TCCT motif located -299 base pairs upstream from the transcriptional start site served as a major positive regulatory cis-element in C3H3 cells. In contrast, this element was not required for Fas ligand transcriptional activity in Sertoli cells and airway epithelial cells. By UV cross-linking analysis, we found that an approximately 30-kDa corneal nuclear protein binds to the Fas ligand promoter TCCT box and, thus, likely plays an important role in Fas ligand expression in corneal endothelial cells.

Characterization of a mutant T-cell hybridoma line with defects in the TCR-mediated apoptotic pathway.

A mutant T-cell hybridoma line named mutant 51 was developed that, unlike the parental line, did not die after T-cell receptor (TCR) engagement and demonstrated reduced death in response to dexamethasone. Intracellular calcium measurements showed that available calcium stores were markedly reduced in the mutant cell line. Unlike control cells, secretion of IL-2 from mutant cells was also greatly reduced, although addition of exogenous IL-2 did not facilitate increased apoptosis. Although levels of the cell death gene product Nur77 were equivalent, additional studies showed that mutant cells expressed Nur77 predominantly in the cytoplasm following TCR engagement, while parental cells displayed a nuclear translocalization of Nur77. In addition, Fas levels and Fas ligand dependant killing were both markedly reduced in the mutant clone. From these data we hypothesize a role for available calcium stores and Nur77 nuclear localization in TCR-mediated apoptosis in T-cell hybridomas.

Acceleration of lpr lymphoproliferative and autoimmune disease by transgenic protein kinase CK2 alpha.

MRL-lpr/lpr mice have a Fas receptor mutation that leads to abnormalities of apoptosis, lymphoproliferation, and a lupus-like autoimmune disease associated with the production of autoantibodies. Other than Fas pathway defects, little is known about molecular abnormalities that predispose to autoimmunity. Protein kinase CK2 (also termed casein kinase II), a serine-threonine protein kinase whose targets include many critical regulators of cellular growth, is highly expressed in a lymphoproliferative disease of cattle and in many human cancers. Overexpression of the CK2alpha catalytic subunit in lymphocytes of transgenic mice leads to T cell lymphoma. We hypothesized that CK2 dysregulation and Fas mutation might cooperatively augment lymphocyte proliferation and transformation. We find that in MRL-lpr/lpr mice bearing the CK2alpha transgene, the lymphoproliferative process is dramatically exacerbated, as these mice develop massive splenomegaly and lymphadenopathy by 12 wk of age in association with increased autoantibody production and accelerated renal disease. The lymphoid organs are filled with the unusual B220+CD4-CD8- T cells typically seen in MRL-lpr/lpr mice, not the B220-CD4+CD8+ or B220-CD4-CD8+ T cells typically seen in CK2a transgenic lymphomas. The T cells do not fulfill the criteria for transformation, as they are polyclonal and not transplantable or immortal in cell culture. Thus, although the lpr lymphoproliferative and autoimmune syndrome is potentiated by the presence of the CK2a transgene, this combination of apoptotic and proliferative abnormalities appears to be insufficient to transform lymphoid cells.

Targeted disruption of the catalytic subunit of the DNA-PK gene in mice confers severe combined immunodeficiency and radiosensitivity.

The DNA-dependent protein kinase is a mammalian protein complex composed of Ku70, Ku80, and DNA-PKcs subunits that has been implicated in DNA double-strand break repair and V(D)J recombination. Here, by gene targeting, we have constructed a mouse with a disruption in the kinase domain of DNA-PKcs, generating an animal model completely devoid of DNA-PK activity. Our results demonstrate that DNA-PK activity is required for coding but not for signal join formation in mice. Although our DNA-PKcs defective mice closely resemble Scid mice, they differ by having elevated numbers of CD4+CD8+ thymocytes. This suggests that the Scid mice may not represent a null phenotype and may retain some residual DNA-PKcs function.

Identification of two NF-kappa B sites in mouse CD95 ligand (Fas ligand) promoter: functional analysis in T cell hybridoma.

Fas ligand (FasL) gene expression is critically involved in peripheral T cell tolerance and lymphocyte homeostasis. Previous studies have suggested that nuclear translocation of NF-kappaB during T cell activation is a critical event for FasL gene activation. In the present study we have identified two NF-kappaB sites (designated FasL-kappaB1 and FasL-kappaB2) on the promoter (approximately 700 bp) of FasL. The NF-kappaB sites were identified by electrophoretic mobility shift assay. Transient transfection reporter analyses showed that the FasL promoter activity was comparable between a construct that contains both sites and a shorter construct (433 bp) that contains only the FasL-kappaB1 site. Furthermore, elimination of FasL-kappaB1 by site-directed mutagenesis significantly inhibited FasL promoter activity. These observations provide strong evidence that NF-kappaB directly binds to the FasL-kappaB1 site and up-regulates FasL gene expression.