CD95 ligand-expressing tumors are rejected in anti-tumor TCR transgenic perforin knockout mice.

CD95 (APO-/Fas) ligand (CD95L) is a member of the TNF family predominantly expressed by activated T and NK cells but also by tumors of diverse cellular origin. CD95L trimerizes surface CD95 expressed by target cells that subsequently undergo apoptosis. The role of the CD95/CD95L system in the down-regulation of an immune response (activation-induced cell death) is established. However, it is so far unclear why tumors express CD95L. To investigate whether tumors use the CD95L to down-regulate an anti-tumor immune response, we established a transgenic (tg) mouse model consisting of 1) apoptosis-resistant tumor cells, designated LKC-CD95L, which express functional CD95L and the model tumor Ag K(b); and 2) perforin knockout (PKO) anti-K(b) TCR tg mice. L1210-Fas antisense expressing K(b), crmA, and CD95L (LKC-CD95L) killed CD95(+) unrelated tumor targets and Con A-activated splenocytes from anti-K(b) TCR tg PKO mice by a CD95L-dependent mechanism in vitro. However, we could not detect any cytotoxic activity against anti-tumor (anti-K(b)) T cells in vivo. We also observed reduced growth of LKC-CD95L in nude mice and rapid rejection in anti-K(b) TCR tg PKO mice. Because the tumor cells are resistant to CD95L-, TNF-alpha-, and TNF-related apoptosis-inducing ligand-induced apoptosis and the mice used are perforin-deficient, the involvement of these four cytotoxicity mechanisms in tumor rejection can be excluded. The histological examination of tumors grown in nude mice showed infiltration of LKC-CD95L tumors by neutrophils, whereas L1210-Fas antisense expressing K(b) and crmA (LKC) tumor tissue was neutrophil-free. Chemotaxis experiments revealed that CD95L has no direct neutrophil-attractive activity. Therefore, we conclude that LKC-CD95L cells used an indirect mechanism to attract neutrophils that may cause tumor rejection.

Herpes simplex virus type 1 infection of activated cytotoxic T cells: Induction of fratricide as a mechanism of viral immune evasion.

Herpes simplex virus type 1 (HSV1), a large DNA-containing virus, is endemic in all human populations investigated. After infection of mucocutaneous surfaces, HSV1 establishes a latent infection in nerve cells. Recently, it was demonstrated that HSV1 can also infect activated T lymphocytes. However, the consequences of T cell infection for viral pathogenesis and immunity are unknown. We have observed that in contrast to the situation in human fibroblasts, in human T cell lines antigen presentation by major histocompatibility complex class I molecules is not blocked after HSV1 infection. Moreover, HSV1 infection of T cells results in rapid elimination of antiviral T cells by fratricide. To dissect the underlying molecular events, we used a transgenic mouse model of HSV1 infection to demonstrate that CD95 (Apo-1, Fas)-triggered apoptosis is essential for HSV1-induced fratricide, whereas tumor necrosis factor (TNF) also contributes to this phenomenon but to a lesser extent. By contrast, neither TRAIL (TNF-related apoptosis-inducing ligand) nor perforin were involved. Finally, we defined two mechanisms associated with HSV1-associated fratricide of antiviral T cells: (a) T cell receptor-mediated upregulation of CD95 ligand and (b) a viral "competence-to-die" signal that renders activated T lymphocytes susceptible to CD95 signaling. We propose that induction of fratricide is an important immune evasion mechanism of HSV1, helping the virus to persist in the host organism throughout its lifetime.

The regulation of CD95 ligand expression and function in CTL.

Previous studies with CTL lines and CTL hybridomas have suggested that functional CD95 (APO-1/Fas)-ligand (CD95L) expression on effector CTLs is a consequence of specific CTL-target recognition and TCR triggering of newly transcribed CD95L. Such a control on the expression of CD95L could provide a double safeguard for killing only cognate target cells. Here the regulation of CD95L expression and function was tested in in vivo primed, alloreactive peritoneal exudate CTL (PEL) from perforin-deficient (P0) mice. CD95L-based, PEL-mediated cytotoxicity was blocked by brefeldin A, an inhibitor of intracellular protein transport, but not by the protein synthesis inhibitor emetine, the immunosuppressive drug cyclosporin A, or the DNA transcription inhibitor actinomycin D. CD95L mRNA transcripts in freshly isolated PEL were shown by RT-PCR; CD95L surface expression was evident by staining with Fas-Fc as well as CD95L Abs. Undiminished CD95L expression and cytocidal activity were found in PEL incubated for 48 h in culture, without adding Ag, mitogen, or cytokines. PEL expressed functional CD95L, yet exhibited target cell-specific killing, except when encountering high CD95-expressing cells. The results indicate that PEL use CD95L probably expressed in the Golgi and/or on the cell surface and do not require newly transcribed CD95L upon target cell conjugation. Hence the TCR-triggered recruitment of preformed CD95L, rather than its biosynthesis, controls CD95L-based specific lysis induced by CTL.