Charles M. Zacharchuk

Lack of a role for Jun kinase and AP-1 in Fas-induced apoptosis.

Cross-linking of Fas (CD95) induces apoptosis, a response that has been reported to depend upon the Ras activation pathway. Since many examples of apoptosis have been reported to involve AP-1 and/or the AP-1-activation pathway. Since many examples of apoptosis have been reported to involve AP-1 and/or the AP-1-activating enzyme Jun kinase (JNK), downstream effectors of Ras or Ras-like small GTP-binding proteins, we evaluated the role of these molecules in Fas-mediated apoptosis. Although cross-linking of Fas on Jurkat T cells did result in JNK activation, increased activity was observed relatively late, being detectable only after 60 min of stimulation. Expression of a dominant negative form of SEK1 that blocked Fas-mediated induction of JNK activity had no effect on Fas-mediated apoptosis. Furthermore, maximally effective concentrations of anti-Fas did not cause JNK activation if apoptosis was blocked by a cysteine protease inhibitor, suggesting that under these conditions, activation of JNK may be secondary to the stress of apoptosis rather than a direct result of Fas engagement. Despite the activation of JNK, there was no induction of AP-1 activity as determined by gel shift assay or induction of an AP-1-responsive reporter. The lack of a requirement for AP-1 induction in Fas-mediated death was further substantiated with Jurkat cells that were stably transfected with a dominant negative cJun, TAM-67. While TAM-67 effectively prevented AP-1-dependent transcription of both the interleukin-2 and cJun genes, it had no effect on Fas-induced cell death, even at limiting levels of Fas signaling. Thus, induction of JNK activity in Jurkat cells by ligation of Fas at levels sufficient to cause cell death is likely a result, rather than a cause, of the apoptotic response, and AP-1 function is not required for Fas-induced apoptosis.

Target Cell Lysis by CTL Granule Exocytosis Is Independent of ICE/Ced-3 Family Proteases

Activation of ICE/Ced-3 family proteases (caspases) has been proposed to mediate both the granule exocytosis and Fas-Fas ligand pathways of rapid target cell death by cytotoxic T lymphocytes. In agreement with this model, two peptide fluoromethyl ketone caspase inhibitors and baculovirus p35 blocked apoptotic nuclear damage and target cell lysis by the CTL-mediated Fas-Fas ligand pathway. The peptide caspase inhibitors also blocked drug-induced apoptotic cell death in tumor cells. In contrast, the caspase inhibitors blocked CTL granule exocytosis-induced target apoptotic nuclear damage, but did not inhibit target lysis. These results are consistent with recent demonstrations that granzyme B can activate caspases leading to apoptotic nuclear damage, but show that target cell lysis by CTL granule exocytosis occurs by a caspase-independent pathway.

A simple assay for examining the effect of transiently expressed genes on programmed cell death

Programmed cell death (PCD) has been observed in a wide variety of cell types in response to physiologic signals or types of stress. How these stimuli trigger PCD, and whether there is a common PCD signal transduction pathway, is not clear. As more genes are described that may participate in or regulate PCD, an assay system in which gene products can easily be introduced and/or modulated would be of great value. To avoid the generation and screening of multiple individual stable cell transfectants, a simple transient transfection death assay has been developed. 2B4.11, a murine T cell hybridoma, was transfected by electroporation with a constitutively active beta-galactosidase reporter gene and the cells were incubated in culture medium or with a PCD-inducing stimulus. The amount of beta-galactosidase activity remaining in the intact cells at the end of the culture period represented only viable transfected cells. Bcl-2 was chosen to examine whether this system would be useful to study the effect of transiently transfected genes since it blocks PCD in a number of experimental systems. Consistent with data obtained using stable transfectants, transient expression of Bcl-2 in 2B4.11 completely protected cells from glucocorticoid- and cytotoxic agent-induced PCD. This protection from death was confirmed at the individual cell level by the transient co-expression of a class I Ld surface antigen and flow cytometric analysis. Some of the advantages of the transient transfection death assay described here are; (1) the simple and sensitive beta-galactosidase assay, (2) the rapidity of the assay, (3) the ability to perform conventional viability assays to monitor treatment-induced cytotoxicity, (4) multiple gene products can be tested alone, and in combination, (5) antisense or dominant negative approaches can be used, and (6) the adaptability of this assay system to other cell types, transfection techniques, or reporter and expression vectors. The transient transfection death assay should make it easier to identify and order important steps in the PCD signal transduction pathways.

Recombinant Mouse Bcl-2(1-203) TWO DOMAINS CONNECTED BY A LONG PROTEASE-SENSITIVE LINKER

Bcl-2 is a cytoplasmic integral membrane protein with potent anti-apoptotic activity but whose mechanism of action is poorly understood. The purpose of this paper was to obtain large amounts of soluble Bcl-2 protein for structural and functional studies. Mouse Bcl-2(1-203) (missing the COOH-terminal hydrophobic tail) was produced in bacterial inclusion bodies, solubilized in guanidine, and refolded by dialysis. The resulting protein was monomeric in nondenaturing solution and was active in protecting mouse T hybridoma cells from glucocorticoid-induced apoptosis. Refolded Bcl-2(1-203) showed no tendency to homodimerize by gel filtration or analytical ultracentrifugation. Limited proteolysis experiments identified a region between the BH3 and BH4 homology domains of Bcl-2(1-203) which was extremely susceptible to digestion by several common proteases, but not by a cell extract known to contain CPP-32-like (interleukin-1β-converting enzyme family) protease activity. The protease-sensitive sites were located within a 50-residue stretch that contained most of the nonconserved and proline residues of Bcl-2(1-203). Trypsin-cleaved Bcl-2(1-203) eluted in the same position as the undigested protein on gel filtration in nondenaturing solution, indicating that the two portions of the molecule connected by the protease-sensitive region associate stably and noncovalently. The solution properties of Bcl-2(1-203) suggest that it consists of two noncovalently associated domains connected by a long protease-sensitive linker and that its structure is similar to that of Bcl-xL, which has been determined by x-ray and NMR analysis.

Bispecific antibodies retarget murine T cell cytotoxicity against syngeneic breast cancer in vitro and in vivo

Bispecific antibodies with specificity for CD3 and a tumor antigen can redirect cytolytic T cells to kill tumor targets, regardless of their natural specificity. To assess the clinical potential of bispecific antibodies for treatment of human cancers we have, in the present study, adapted a totally syngeneic mouse model to the targeting of mouse T cells against mouse tumors in immunocompetent mice. We show that gp52 of the mouse mammary tumor virus (MTV) can serve as a tumor-specific antigen for redirected cellular cytotoxicity. Chemically crosslinked and genetically engineered bispecific antibodies with specificities for gp52 and murine CD3 ε-chain induced activated mouse T cells to specifically lyse mouse mammary tumor cells from cultured lines and primary tumors from C3H-MTV+ mice. Retargeted T cells also blocked the growth of mammary tumors in vitro as well as their growth in syngeneic mice. These findings identify murine MTV-induced mammary adenocarcinomas as a solid-tumor, animal model for retargetin T cells with bispecific antibodies against syngeneic breast cancer.

Caspase Inhibitors as Molecular Probes of Cell Death

Recognition of the importance of programmed cell death in basic biological processes as well as its relevance to clinical problems has led to a surge of research interest in this area in recent years. The appealing idea behind much of this research is that an endogenous death pathway is present in most cells which can be triggered to kill cells by physiological signals or when they encounter some types of stressful conditions. In spite of the rapid progress made in some respects, fundamental issues in this field remain unresolved, and the major challenge is still to molecularly characterize this death pathway and understand the controls which lead to its activation. Recent research in a number of laboratories has identified a family of enzymes which at very least now provides a testable candidate for a central player in such physiological death pathways. Specific inhibitors of these enzymes are newly available tools which can be used to test for their participation in particular physiological and experimental cell death systems (Henkart, 1996). In this paper we will present examples illustrating their use from our own studies on lymphoid cells. For reasons which will become clear, we believe that a functional death criterion based on inhibiting enzyme function provides a more significant characterization of cell death than the commonly used apoptotic death phenotypes.