Jennifer Q. Russell

Cellular FLIP (Long Form) Regulates CD8+ T Cell Activation through Caspase-8-Dependent NF-κB Activation

Cellular FLIP long form (c-FLIPL) was originally identified as an inhibitor of Fas (CD95/Apo-1). Subsequently, additional functions of c-FLIPL were identified through its association with receptor-interacting protein (RIP)1 and TNFR-associated factor 2 to activate NF-κB, as well as by its association with and activation of caspase-8. T cells from c-FLIPL-transgenic (Tg) mice manifest hyperproliferation upon activation, although it was not clear which of the various functions of c-FLIPL was involved. We have further explored the effect of c-FLIPL on CD8+ effector T cell function and its mechanism of action. c-FLIPL-Tg CD8+ T cells have increased proliferation and IL-2 responsiveness to cognate Ags as well as to low-affinity Ag variants, due to increased CD25 expression. They also have a T cytotoxic 2 cytokine phenotype. c-FLIPL-Tg CD8+ T cells manifest greater caspase activity and NF-κB activity upon activation. Both augmented proliferation and CD25 expression are blocked by caspase inhibition. c-FLIPL itself is a substrate of the caspase activity in effector T cells, being cleaved to a p43FLIP form. p43FLIP more efficiently recruits RIP1 than full-length c-FLIPL to activate NF-κB. c-FLIPL and RIP1 also coimmunoprecipitate with active caspase-8 in effector CD8+ T cells. Thus, one mechanism by which c-FLIPL influences effector T cell function is through its activation of caspase-8, which in turn cleaves c-FLIPL to allow RIP1 recruitment and NF-κB activation. This provides a partial explanation of why caspase activity is required to initiate proliferation of resting T cells.

Caspase-8 and c-FLIPL Associate in Lipid Rafts with NF-κB Adaptors during T Cell Activation

Humans and mice lacking functional caspase-8 in T cells manifest a profound immunodeficiency syndrome due to defective T cell antigen receptor (TCR)-induced NF-κB signaling and proliferation. It is unknown how caspase-8 is activated following T cell stimulation, and what is the caspase-8 substrate(s) that is necessary to initiate T cell cycling. We observe that following TCR ligation, a small portion of total cellular caspase-8 and c-FLIPL rapidly migrate to lipid rafts where they associate in an active caspase complex. Activation of caspase-8 in lipid rafts is followed by rapid cleavage of c-FLIPL at a known caspase-8 cleavage site. The active caspase·c-FLIP complex forms in the absence of Fas (CD95/APO1) and associates with the NF-κB signaling molecules RIP1, TRAF2, and TRAF6, as well as upstream NF-κB regulators PKCθ, CARMA1, Bcl-10, and MALT1, which connect to the TCR. The lack of caspase-8 results in the absence of MALT1 and Bcl-10 in the active caspase complex. Consistent with this observation, inhibition of caspase activity attenuates NF-κB activation. The current findings define a link among TCR, caspases, and the NF-κB pathway that occurs in a sequestered lipid raft environment in T cells.

Cellular FLIP long form augments caspase activity and death of T cells through heterodimerization with and activation of caspase-8

Caspase activity is required not only for the death of T cells, but also for their activation. A delicate balance of caspase activity is thus required during T cell activation at a level that will not drive cell death. How caspase activity is initiated and regulated during T cell activation is not known. One logical candidate for this process is cellular FLIP long form (c-FLIPL), because it can block caspase-8 recruitment after Fas (CD95) ligation as well as directly heterodimerize with and activate caspase-8. The current findings demonstrate that after T cell activation, caspase-8 and c-FLIPL associate in a complex enriched for active caspases. This occurs coincidently with the cleavage of two known caspase-8 substrates, c-FLIPL and receptor interacting protein 1. Caspase activity is higher in wild-type CD8+ than CD4+ effector T cells. Increased expression of c-FLIPL results in augmented caspase activity in resting and effector T cells to levels that provoke cell death, especially of the CD8 subset. c-FLIPL is thus not only an inhibitor of cell death by Fas, it can also act as a principal activator of caspases independently of Fas.

Spatial differences in active caspase-8 defines its role in T-cell activation versus cell death.

Caspase-8, a cysteine-protease, initiates apoptosis when activated by death receptors. Caspase-8 is also essential for initiating T lymphocyte proliferation following T-cell antigen receptor (TCR) signaling. Given these disparate functions of caspase-8, we sought to determine whether this represented only a difference in the magnitude of caspase-8 activation, or different intracellular locations of active caspase-8. We demonstrate by high-resolution multicolor confocal laser scanning microscopy an aggregation of active caspase-8 within membrane lipid rafts in T cells stimulated with anti-CD3. This suggests that following TCR stimulation active caspase-8 physically interacts with lipid raft proteins, possibly to form a signaling platform. In contrast, Fas stimulation of T cells resulted in a much more profound activation of caspase-8 that was exclusively cytosolic. These confocal microscopic findings were confirmed using discontinuous sucrose gradient ultracentrifugation to isolate lipid raft versus cytosolic components. This sequestration model of caspase-8 activation was further supported by the observation that a classic caspase-8 substrate, BID, was not cleaved in CD3-stimulated T cells, but was cleaved after Fas engagement. Our data support a model that the location of active caspase-8 may profoundly influence its functional capacity as a regulator of either cell cycling or cell death.

Effector CD4+ T Cells Generate Intermediate Caspase Activity and Cleavage of Caspase-8 Substrates

Caspase-8 activation promotes cell apoptosis but is also essential for T cell activation. The extent of caspase activation and substrate cleavage in these divergent processes remains unclear. We show that murine effector CD4+ T cells generated levels of caspase activity intermediate between unstimulated T cells and apoptotic populations. Both caspase-8 and caspase-3 were partially activated in effector T cells, which was reflected in cleavage of the caspase-8 substrates, c-FLIPL, receptor interacting protein 1, and to a lesser extent Bid, but not the caspase-3 substrate inhibitor of caspase-activated DNase. Th2 effector CD4+ T cells manifested more caspase activity than did Th1 effectors, and caspase blockade greatly decreased initiation of cell cycling. The current findings define the level of caspase activity and substrates during initiation of T cell cycling.

Cellular FLIP Long Form-Transgenic Mice Manifest a Th2 Cytokine Bias and Enhanced Allergic Airway Inflammation

Cellular FLIP long form (c-FLIPL) is a caspase-defective homologue of caspase-8 that blocks apoptosis by death receptors. The expression of c-FLIPL in T cells can also augment extracellular signal-regulated kinase phosphorylation after TCR ligation via the association of c-FLIPL with Raf-1. This contributes to the hyperproliferative capacity of T cells from c-FLIPL-transgenic mice. In this study we show that activated CD4+ T cells from c-FLIPL-transgenic mice produce increased amounts of Th2 cytokines and decreased amounts of Th1 cytokines. This correlates with increased serum concentrations of the Th2-dependent IgG1 and IgE. The Th2 bias of c-FLIPL-transgenic CD4+ T cells parallels impaired NF-κB activity and increased levels of GATA-3, which contribute, respectively, to decreased IFN-γ and increased Th2 cytokines. The Th2 bias of c-FLIPL-transgenic mice extends to an enhanced sensitivity to OVA-induced asthma. Taken together, these results show that c-FLIPL can influence cytokine gene expression to promote Th2-driven allergic reaction, in addition to its traditional role of blocking caspase activation induced by death receptors.

Liver Damage by Infiltrating CD8+ T Cells Is Fas Dependent

Ag stimulation of CD8+ lymphocytes in vivo results in their migration to various tissues as well as the activation of a cytolytic program involving perforin, TNF-α, and Fas ligand. The liver is one of the main sites for infiltration by activated CD8+ T cells, and this is followed by the death of hepatocytes. The contribution of the various cytolytic components to this process is unclear. Hepatocyte damage by CD8+ T cells was studied using the MHC class I-restricted OVA-specific TCR transgenic mouse (OT-1) to examine the contribution of Fas to hepatocyte death. Activated CD8+ T cells from both OT-1 and Fas-deficient OT-1lpr mice migrated to the liver in similar numbers after OVA administration, but only in OT-1 mice was there evidence of significant hepatocyte damage histologically and by elevation of serum aspartate transaminase. These differences were not the result of inefficient induction of cytolytic activity in OT-1lpr liver T cells, since they were as cytolytic in vitro as OT-1 liver T cells. This was supported by findings of similar high levels of message for perforin, TNF-α, and Fas ligand in liver lymphocytes from both mice. These findings demonstrate that following Ag activation, infiltrating liver CD8+ T lymphocytes induce hepatocyte damage in a Fas-dependent manner.

Activation of γδ T Cells by Borrelia burgdorferi Is Indirect via a TLR- and Caspase-Dependent Pathway

Activation of the innate immune system typically precedes engagement of adaptive immunity. Cells at the interface between these two arms of the immune response are thus critical to provide full engagement of host defense. Among the innate T cells at this interface are γδ T cells. γδ T cells contribute to the defense from a variety of infectious organisms, yet little is understood regarding how they are activated. We have previously observed that human γδ T cells of the Vδ1 subset accumulate in inflamed joints in Lyme arthritis and proliferate in response to stimulation with the causative spirochete, Borrelia burgdorferi. We now observe that murine γδ T cells are also activated by B. burgdorferi and that in both cases the activation is indirect via TLR stimulation on dendritic cells or monocytes. Furthermore, B. burgdorferi stimulation of monocytes via TLR, and secondary activation of γδ T cells, are both caspase-dependent.

Proteolytic Regulation of Nuclear Factor of Activated T (NFAT) c2 Cells and NFAT Activity by Caspase-3

The nuclear factor of activated T (NFAT) cell family of transcription factors is important in regulating the expression of a broad array of genes, including cytokines, T cell surface receptors, and other transcription factors. NFATc1 and NFATc2 are two principal NFAT members that are expressed in peripheral T cells. Levels of NFAT expression in T cells are partly transcriptionally regulated, but less is understood regarding their post-transcriptional control. We show here that NFATc1 and NFATc2 are rapidly degraded in apoptotic T cells. NFATc2 is highly sensitive to cleavage by caspase-3, whereas NFATc1 is only weakly sensitive to caspase-3 or caspase-8. Two potential caspase-3 cleavage sites were identified in the N-terminal transactivation domain. These sites were confirmed by in vitro caspase cleavage assays. Abolition of NFATc2 cleavage by mutation of these two cleavage sites resulted in augmented NFAT transcriptional activity. Furthermore, NFAT activity could be augmented in wild-type effector T cells by inhibition of caspase activity. Of particular interest was that non-apoptotic T cells from cellular FLIP long transgenic (c-FLIPL-Tg) mice that manifest elevated caspase activity have greatly reduced levels of NFATc2 protein and NFAT transcriptional activity. Our findings reveal a new post-transcriptional regulation of NFATc2 that operates, not only during apoptosis, but also in non-apoptotic effector T cells.

The c-FLIPL cleavage product p43FLIP promotes activation of extracellular signal-regulated kinase (ERK), nuclear factor κB (NF-κB), and caspase-8 and T cell survival.

Background: c-FLIPL is a regulator of caspase-8 activity in T lymphocytes. Results: Caspase-8 activity is lost upon deletion of c-FLIPL. p43FLIP rescues caspase-8 activity through Raf1, TRAF2, and RIPK1 association, augmenting ERK and NF-κB pathways. Conclusion: The FLIPL cleavage product p43FLIP promotes activation of pathways involved with T cell growth. Significance: This study provides new insight into the regulation of caspase-8 activity by c-FLIP. Caspase-8 is now appreciated to govern both apoptosis following death receptor ligation and cell survival and growth via inhibition of the Ripoptosome. Cells must therefore carefully regulate the high level of caspase-8 activity during apoptosis versus the modest levels observed during cell growth. The caspase-8 paralogue c-FLIP is a good candidate for a molecular rheostat of caspase-8 activity. c-FLIP can inhibit death receptor-mediated apoptosis by competing with caspase-8 for recruitment to FADD. However, full-length c-FLIPL can also heterodimerize with caspase-8 independent of death receptor ligation and activate caspase-8 via an activation loop in the C terminus of c-FLIPL. This triggers cleavage of c-FLIPL at Asp-376 by caspase-8 to produce p43FLIP. The continued function of p43FLIP has, however, not been determined. We demonstrate that acute deletion of endogenous c-FLIP in murine effector T cells results in loss of caspase-8 activity and cell death. The lethality and caspase-8 activity can both be rescued by the transgenic expression of p43FLIP. Furthermore, p43FLIP associates with Raf1, TRAF2, and RIPK1, which augments ERK and NF-κB activation, IL-2 production, and T cell proliferation. Thus, not only is c-FLIP the initiator of caspase-8 activity during T cell activation, it is also an initial caspase-8 substrate, with cleaved p43FLIP serving to both stabilize caspase-8 activity and promote activation of pathways involved with T cell growth.