Delineation of the cell-extrinsic apoptosis pathway in the zebrafish.

The mammalian extrinsic apoptosis pathway is triggered by Fas ligand (FasL) and Apo2 ligand/tumor necrosis factor (TNF)-related apoptosis-inducing ligand (Apo2L/TRAIL). Ligand binding to cognate receptors activates initiator caspases directly in a death-inducing signaling complex. In Drosophila, TNF ligand binding activates initiator caspases indirectly, through JNK. We characterized the extrinsic pathway in zebrafish to determine how it operates in a nonmammalian vertebrate. We identified homologs of FasL and Apo2L/TRAIL, their receptors, and other components of the cell death machinery. Studies with three Apo2L/TRAIL homologs demonstrated that they bind the receptors zHDR (previously linked to hematopoiesis) and ovarian TNFR (zOTR). Ectopic expression of these ligands during embryogenesis induced apoptosis in erythroblasts and notochord cells. Inhibition of zHDR, zOTR, the adaptor zFADD, or caspase-8-like proteases blocked ligand-induced apoptosis, as did antiapoptotic Bcl-2 family members. Thus, the extrinsic apoptosis pathway in zebrafish closely resembles its mammalian counterpart and cooperates with the intrinsic pathway to trigger tissue-specific apoptosis during embryogenesis in response to ectopic Apo2L/TRAIL expression.

Tumor necrosis factor receptor and Fas signaling mechanisms.

Four members of the tumor necrosis factor (TNF) ligand family, TNF-alpha, LT-alpha, LT-beta, and LIGHT, interact with four receptors of the TNF/nerve growth factor family, the p55 TNF receptor (CD120a), the p75 TNF receptor (CD120b), the lymphotoxin beta receptor (LT beta R), and herpes virus entry mediator (HVEM) to control a wide range of innate and adaptive immune response functions. Of these, the most thoroughly studied are cell death induction and regulation of the inflammatory process. Fas/Apo1 (CD95), a receptor of the TNF receptor family activated by a distinct ligand, induces death in cells through mechanisms shared with CD120a. The last four years have seen a proliferation in knowledge of the proteins participating in the signaling by the TNF system and CD95. The downstream signaling molecules identified so far--caspases, phospholipases, the three known mitogen activated protein (MAP) kinase pathways, and the NF-kappa B activation cascade--mediate the effects of other inducers as well. However, the molecules that initiate these signaling events, including the death domain- and TNF receptor associated factor (TRAF) domain-containing adapter proteins and the signaling enzymes associated with them, are largely unique to the TNF/nerve growth factor receptor family.

Targeted disruption of the mouse Caspase 8 gene ablates cell death induction by the TNF receptors, Fas/Apo1, and DR3 and is lethal prenatally.

Homozygous targeted disruption of the mouse Caspase 8 (Casp8) gene was found to be lethal in utero. The Caspase 8 null embryos exhibited impaired heart muscle development and congested accumulation of erythrocytes. Recovery of hematopoietic colony-forming cells from the embryos was very low. In fibroblast strains derived from these embryos, the TNF receptors, Fas/Apo1, and DR3 were able to activate the Jun N-terminal kinase and to trigger IkappaB alpha phosphorylation and degradation. They failed, however, to induce cell death, while doing so effectively in wild-type fibroblasts. These findings indicate that Caspase 8 plays a necessary and nonredundant role in death induction by several receptors of the TNF/NGF family and serves a vital role in embryonal development.

Death-inducing functions of ligands of the tumor necrosis factor family: a Sanhedrin verdict.

Members of the tumor necrosis factor ligand family can kill cells in a rather straightforward manner. They induce their receptors to recruit and activate caspases, enzymes that are critically involved in the death process, and this activation is further amplified by intracellular mitochondria-associated mechanisms. The potentially hazardous expression of the ligands occurs widely in the body; it is antigen-restricted only in the lymphocytes. Yet, in addition to control modes affecting ligand expression, there are numerous inhibitory mechanisms that act within target cells, to make doubly sure of avoiding an undue 'death verdict', while allowing the cells to exhibit other, noncytocidal effects of the ligands.

CASH, a novel caspase homologue with death effector domains.

CASP-8 and CASP-10, members of a cysteine protease family that participates in apoptosis, interact with MORT1/FADD, an adapter protein in the CD120a (p55 tumor necrosis factor receptor), and CD95 (Fas/Apo-1) death-inducing signaling pathways, through a shared N-terminal sequence motif, the death effector domain. We report cloning of two splice variants of a novel protein, CASH, that contain two N-terminal death effector domains and can bind through them to each other, to MORT1/FADD, to CASP-8, and to CASP-10. The unique C-terminal part of the longer variant shows marked sequence homology to the caspase protease region yet lacks several of the conserved caspase active site residues, suggesting that it is devoid of cysteine protease activity. Overexpression of the short CASH splice variant strongly inhibited cytotoxicity induction by CD120a and CD95. Expression of the longer variant, while inhibiting cytotoxicity in HeLa cells, had a marked cytocidal effect in 293 cells that could be shown to involve its protease homology region. The findings suggest that CASH acts as an attenuator and/or initiator in CD95 and CD120a signaling for cell death.

Exploring cell death mechanisms by analyzing signaling cascades of the TNF/NGF receptor family.

The ability of ligands of the tumor necrosis factor (TNF) family to induce death of cells independently of new protein synthesis provides a unique approach to molecular analysis of programmed cell death mechanisms. Sequential analysis of the protein-protein interactions by which these receptors signal, allows identification of specific molecules that participate in the cell death process and unequivocal definition of cause-effect relationships between them. Several receptors of this family, with structurally unrelated intracellular domains, have the ability to trigger cell death. some intracellular proteins that bind to the receptors and participate in the induction of their effects have been identified. Association of the Fas/APO1-interacting protein MORT1/FADD with the p55 TNF receptor-interacting protein TRADD, and the association of both MORT1/FADD and TRADD with a third protein, RIP, provide potential cross-talk mechanisms between Fas/APO1 and the p55 TNF receptor. TRAF2, a cytoplasmic protein that binds to the p75 TNF receptor, as well as to several other receptors of the TNF/NGF family, also binds to TRADD, thus further extending the range of receptors of this family that can share common signaling mechanisms. The N-terminal part of MORT1/FADD binds to a protease of the CED3/ICE family, MACH alpha. Activation of MACH alpha by the TNF/NGF receptors appears to be the most upstream enzymatic activity in the cascade of signaling for cell death.

A potential mechanism of "cross-talk" between the p55 tumor necrosis factor receptor and Fas/APO1: proteins binding to the death domains of the two receptors also bind to each other.

The p55 tumor necrosis factor (TNF) receptor and Fas/APO1 induce cell death via distinct regions in their intracellular domains. Three cytoplasmic proteins that bind to these receptor regions have been identified recently. One, MORT1 (also called FADD), binds to Fas/APO1 but not to p55-R; another, TRADD, binds to the p55 TNF receptor but not to Fas/APO1; and the third, RIP, binds weakly to both receptors. The regions within these proteins that are involved in binding to the receptors and the receptor regions to which they bind share a common sequence motif, that of the "death domain." This study shows that the death domain motifs in MORT1, TRADD, and RIP bind effectively to each other, a mode of binding that may allow "cross-talk" between the functional expression of the p55 TNF receptor and Fas/APO1.

A novel protein that interacts with the death domain of Fas/APO1 contains a sequence motif related to the death domain.

Signaling for cell death by Fas/APO1 occurs via a distinct region in its intracellular domain. This region contains a conserved sequence motif, the death domain motif, that is also found in the intracellular domains of the p55 tumor necrosis factor receptor and the low affinity nerve growth factor receptor, as well as in the regulatory domain of the ankyrins. A novel protein that specifically binds to the death domain of Fas/APO1 but not to Fas/APO1 molecules with a loss of function point mutation occurring in lprcg mice was cloned by a two-hybrid screen of a HeLa cells' cDNA library. The cloned protein itself contains a death domain motif, and this region binds to the death domain of Fas/APO1, while the region upstream to the death domain prompts self-association of the protein. Induced expression of the protein results in ligand-independent triggering of cytotoxicity, suggesting that it is involved in cell death induction by Fas/APO1.

Self-association of the "death domains" of the p55 tumor necrosis factor (TNF) receptor and Fas/APO1 prompts signaling for TNF and Fas/APO1 effects.

Signaling by the p55 tumor necrosis factor (TNF) receptor and by the structurally related receptor Fas/APO1 is initiated by receptor clustering. Data presented here and in other recent studies (Wallach, D., Boldin, M., Varfolomeev, E. E., Bigda, Y., Camonis, H.J. and Mett, I. (1994) Cytokine 6, 556; Song, H.Y., Dunbar, J.D., and Bonner, D.B. (1994) J. Biol. Chem. 269, 22492-22495) indicate that part of that region within the intracellular domains of the two receptors that is involved in signaling for cell death, as well as for some other effects (the "death domain", specifically self-associates. We demonstrate also the expected functional consequence of this association; a mere increase in p55 TNF receptor expression, or the expression just of its intracellular domain, is shown to trigger signaling for cytotoxicity as well as for interleukin 8 gene induction, while expression of the intracellular domain of Fas/APO1 potentiates the cytotoxicity of co-expressed p55 TNF receptor. These findings indicate that the p55 TNF and Fas/APO1 receptors play active roles in their own clustering and suggest the existence of cellular mechanisms that restrict the self-association of these receptors, thus preventing constitutive signaling.

Structural requirements for inducible shedding of the p55 tumor necrosis factor receptor.

Induced shedding of the p55 tumor necrosis factor receptor (p55-R) was previously shown to be independent of the amino acid sequence properties of the intracellular domain of this receptor. We now find it also independent of the sequence properties of the transmembrane domain and of the cysteine-rich region that constitutes most of the extracellular domain of the receptor. The shedding is shown to depend solely on the sequence properties of a small region within the spacer that links the cysteine-rich region in the extracellular domain to the transmembrane domain. Detailed tests of effects of mutations in the spacer on the shedding indicate that the process is independent of the amino acid side-chain identity in this region except for a limited dependence on the identity of 1 residue (Val-173), located downstream to the putative major cleavage site of the receptor. It is strongly affected, however, by some mutations that seem to change the conformation of the spacer region. These findings suggest that a short amino acid sequence in the p55-R is essential and sufficient for its shedding and that the shedding is mediated either by a protease with limited sequence specificity or by several different proteases that recognize different amino acid sequences, yet it strictly depends on some conformational features of the cleavage region in the receptor.