We have used the proteasome inhibitor bortezomib to sensitize human tumor cell lines to apoptosis mediated by death ligands, in particular the protein TRAIL. Also we have performed studies with antibodies that act as agonists to the TRAIL death receptors. The agonist antibodies may offer specific advantages for cancer therapy. There are 4 well-defined TRAIL receptors in humans, yet only 2 of them death receptor 4 (DR4) and death receptor 5 (DR5) send the apoptotic death signal. Therefore specific agonist antibodies to these receptors may be more selective than the TRAIL protein itself that can bind to all of the receptors. In addition antibodies tend to have a much longer half-life that the TRAIL protein in vivo, so their effects may be more potent and longer lasting. Bortezomib, a novel anticancer agent that inhibits the proteasome complex of enzymes recently was approved by the FDA for the therapy of multiple myeloma as a single agent. We have shown that in a panel of 50 human tumor cell lines, bortezomib sensitized about 45% of these cells to the apoptotic effects of TRAIL, about 25% to the apoptotic effects of Fas Ligand and less than 7 % to apoptosis by TNF. Since this proteasome inhibitor was very efficient in sensitizing tumor cells to TRAIL we studied this sensitization in more detail. In mouse models of renal cancer and breast cancer we showed that agonist antibodies to the mouse TRAIL death receptor DR5 had significantly enhanced pro-apoptotic activity in vitro in the presence of the proteasome inhibitor bortezomib. More importantly, this combination of agents had an improved therapeutic effect over either agent alone in experimental lung metastases models of both the renal and breast carcinomas in vivo. In addition the therapeutic combination did not cause any obvious toxicity in the mice on examination of a large number of organs. This was the first demonstration, to our knowledge, that this combination could have therapeutic anticancer efficacy in vivo in the absence of significant toxicity. There are currently clinical trails in progress using bortezomib and agonist antibodies to the TRAIL death receptor 4 in patients with multiple myeloma. We investigated the molecular basis of this sensitization in more detail. Cell death by apoptosis in response to the death ligands can proceed by 2 pathways. These are the extrinsic pathway, where the signaling from the death ligand death receptors is strong and directly signals cell death by setting off a cascade of enzymes. Alternatively for the intrinsic pathway, signaling from the death receptors is weaker and subsequent damage to the mitochondria of the cell is necessary for the cell death to occur. Using human renal carcinoma cells that are either sensitized or resistant to the effects of bortezomib on TRAIL-driven apoptosis, we concluded that the major effects of bortzomib were on amplifying the extrinsic apoptotic pathway. However exactly how a proteasome inhibitor amplifies this signaling at the molecular level is unclear and is under further investigation. In collaboration with the Molecular Targeting Development Program (MTDP) of the NCI we have also established a high-throughput screen to identify novel agents that can sensitize human cancer cells to TRAIL-mediated apoptosis. Over 18,000 pure synthetic compounds or natural products were screened and 18 compounds were identified for further study, 14 pure products and 4 synthetic compounds. Six of the compounds have been studied in more detail. None are proteasome inhibitors, but most may be DNA-damaging agents. Studies on these compounds, and the high-throughput testing of purified compounds from a wide variety of various extracts that the MTDP possesses are currently underway.We have used the proteasome inhibitor bortezomib to sensitize human tumor cell lines to apoptosis mediated by death ligands, in particular the protein TRAIL. Also we have performed studies with antibodies that act as agonists to the TRAIL death receptors. The agonist antibodies may offer specific advantages for cancer therapy. There are 4 well-defined TRAIL receptors in humans, yet only 2 of them death receptor 4 (DR4) and death receptor 5 (DR5) send the apoptotic death signal. Therefore specific agonist antibodies to these receptors may be more selective than the TRAIL protein itself that can bind to all of the receptors. In addition antibodies tend to have a much longer half-life that the TRAIL protein in vivo, so their effects may be more potent and longer lasting. Bortezomib, a novel anticancer agent that inhibits the proteasome complex of enzymes recently was approved by the FDA for the therapy of multiple myeloma as a single agent. We have shown that in a panel of 50 human tumor cell lines, bortezomib sensitized about 45% of these cells to the apoptotic effects of TRAIL, about 25% to the apoptotic effects of Fas Ligand and less than 7 % to apoptosis by TNF. Since this proteasome inhibitor was very efficient in sensitizing tumor cells to TRAIL we studied this sensitization in more detail. In mouse models of renal cancer and breast cancer we showed that agonist antibodies to the mouse TRAIL death receptor DR5 had significantly enhanced pro-apoptotic activity in vitro in the presence of the proteasome inhibitor bortezomib. More importantly, this combination of agents had an improved therapeutic effect over either agent alone in experimental lung metastases models of both the renal and breast carcinomas in vivo. In addition the therapeutic combination did not cause any obvious toxicity in the mice on examination of a large number of organs. This was the first demonstration, to our knowledge, that this combination could have therapeutic anticancer efficacy in vivo in the absence of significant toxicity. There are currently clinical trails in progress using bortezomib and agonist antibodies to the TRAIL death receptor 4 in patients with multiple myeloma. We investigated the molecular basis of this sensitization in more detail. Cell death by apoptosis in response to the death ligands can proceed by 2 pathways. These are the extrinsic pathway, where the signaling from the death ligand death receptors is strong and directly signals cell death by setting off a cascade of enzymes. Alternatively for the intrinsic pathway, signaling from the death receptors is weaker and subsequent damage to the mitochondria of the cell is necessary for the cell death to occur. Using human renal carcinoma cells that are either sensitized or resistant to the effects of bortezomib on TRAIL-driven apoptosis, we concluded that the major effects of bortzomib were on amplifying the extrinsic apoptotic pathway. However exactly how a proteasome inhibitor amplifies this signaling at the molecular level is unclear and is under further investigation. In collaboration with the Molecular Targeting Development Program (MTDP) of the NCI we have also established a high-throughput screen to identify novel agents that can sensitize human cancer cells to TRAIL-mediated apoptosis. Over 18,000 pure synthetic compounds or natural products were screened and 18 compounds were identified for further study, 14 pure products and 4 synthetic compounds. Six of the compounds have been studied in more detail. None are proteasome inhibitors, but most may be DNA- [summary truncated at 7800 characters]
Sun, Kai; Li, Minghui; Sayers, Thomas J et al. (2008) Differential effects of donor T-cell cytokines on outcome with continuous bortezomib administration after allogeneic bone marrow transplantation. Blood 112:1522-9 |