Loss of drug-induced activation of the CD95 apoptotic pathway in a cisplatin-resistant testicular germ cell tumor cell line.

Testicular germ cell tumors (TGCTs) are unusually sensitive to cisplatin. In the present study the role of the CD95 death pathway in cisplatin sensitivity of TGCT cells was studied in Tera and its in vitro acquired cisplatin-resistant subclone Tera-CP. Cisplatin induced an increase in CD95 membrane expression, which preceded the onset of apoptosis. Cisplatin-induced apoptosis was efficiently blocked by caspase-8 inhibitor zIETD-fmk in Tera cells, but only partially in Tera-CP cells. In addition, cisplatin induced FADD and caspase-8 recruitment to the CD95 receptor in Tera cells, which was not noticed in Tera-CP cells. Moreover, overexpression of vFLIP reduced apoptosis induction by cisplatin in Tera cells. CD95L-blocking experiments revealed the involvement of CD95/CD95L interactions in cisplatin-induced apoptosis of Tera cells as well as cisplatin-sensitive 833KE TGCT cells. Tera and 833KE cells, treated with low doses of cisplatin, were sensitive for an apoptosis-inducing anti-CD95 antibody. In contrast, CD95L blocking had no effect on cisplatin-induced apoptosis in Tera-CP or Scha, an intrinsic resistant TGCT cell line, nor did anti-CD95 antibody induce additional apoptosis in cisplatin-treated Tera-CP or Scha cells. Taken together, these results show that (1) cisplatin sensitivity of TGCT cells is dependent on the activation of the CD95 death pathway and (2) loss of cisplatin-induced activation of this CD95 signaling pathway may result in resistance to cisplatin.

Indomethacin-induced activation of the death receptor-mediated apoptosis pathway circumvents acquired doxorubicin resistance in SCLC cells.

Small-cell lung cancers (SCLCs) initially respond to chemotherapy but are often resistant at recurrence. A potentially new method to overcome resistance is to combine classical chemotherapeutic drugs with apoptosis induction via tumour necrosis factor (TNF) death receptor family members such as Fas. The doxorubicin-resistant human SCLC cell line GLC4-Adr and its parental doxorubicin-sensitive line GLC4 were used to analyse the potential of the Fas-mediated apoptotic pathway and the mitochondrial apoptotic pathway to modulate doxorubicin resistance in SCLC. Western blotting showed that all proteins necessary for death-inducing signalling complex formation and several inhibitors of apoptosis were expressed in both lines. The proapototic proteins Bid and caspase-8, however, were higher expressed in GLC4-Adr. In addition, GLC4-Adr expressed more Fas (3.1x) at the cell membrane. Both lines were resistant to anti-Fas antibody, but plus the protein synthesis inhibitor cycloheximide anti-Fas antibody induced 40% apoptosis in GLC4-Adr. Indomethacin, which targets the mitochondrial apoptotic pathway, induced apoptosis in GLC4-Adr but not in GLC4 cells. Surprisingly, in GLC4-Adr indomethacin induced caspase-8 and caspase-9 activation as well as Bid cleavage, while both caspase-8 and caspase-9 specific inhibitors blocked indomethacin-induced apoptosis. In GLC4-Adr, doxorubicin plus indomethacin resulted in elevated caspase activity and a 2.7-fold enhanced sensitivity to doxorubicin. In contrast, no effect of indomethacin on doxorubicin sensitivity was observed in GLC4. Our findings show that indomethacin increases the cytotoxic activity of doxorubicin in a doxorubicin-resistant SCLC cell line partly via the death receptor apoptosis pathway, independent of Fas.

Modulation of death receptor pathways in oncology.

Chemotherapeutic efficacy is hampered by occurrence of drug resistance. Several mechanisms cause this phenomenon. A final common factor is the reduced capacity of resistant cells to go into apoptosis following treatment with DNA-damaging agents. It is therefore interesting to search for ways to facilitate this apoptotic process following use of chemotherapeutic drugs. The death receptor ligands tumor necrosis factor (TNF), FasL and TNF-related apoptosis-inducing ligand (TRAIL) might be interesting candidates as they are able to induce apoptosis by binding to their cell membrane receptors. Recombinant forms of these ligands potentiate chemotherapeutic drug effects in preclinical models. For the clinical application of TNF, FasL and TRAIL, it is of primary importance that their safety be guaranteed. RhTNF is the only ligand currently used in humans. However, systemic rhTNF has shown low antitumor activity and higher doses induce severe sepsis-like toxicity. Perfusion setting aimed at limb preservation with rhTNF plus melphalan is currently used in sarcoma patients. A number of options have been tested in the preclinical setting that might allow circumvention of TNF toxicity in the clinic. Systemic rhFasL administration in humans is not yet feasible because of observed severe liver toxicity in mice due to Fas-mediated apoptosis of hepatocytes. Measures to circumvent liver toxicity have not yet been exploited. Another option for using FasL in the clinic may be to identify an alternative route of administration. In the animal model, FasL appeared to be less toxic for the liver compared with anti-Fas antibodies when administered intraperitoneally. There are relatively nontoxic modulators of the Fas death pathway, such as interferon and nonsteroidal antiinflammatory drugs (NSAIDs), which might prove interesting in combination with chemotherapy. Finally, it may be possible to produce a modified FasL with a reduced toxicity profile. TRAIL, produced as soluble, zinc-stabilized rhTRAIL seems to be without preclinical toxicity. Agonistic DR4 and DR5 antibodies against their TRAIL death receptor are being studied as another potential clinical option to induce apoptosis. Due to the synergistic effect observed in the preclinical setting between death receptor ligands and other modulators of the death receptor pathways and chemotherapy, it may well be that this approach is especially of value in the clinic when combined with chemotherapy. Ideally, choices for specific (modified) death receptor ligands for the treatment of patients can be rationally made based on tumor characteristics.