Antiproliferative and proapoptotic activities of pyranoxanthenones, pyranothioxanthenones and their pyrazole-fused derivatives in HL-60 cells.

BACKGROUND: Synthetic pyranoxanthenones, pyranothioxanthenones and their pyrazole-fused derivatives, which bind to DNA, block the G2 + M-phases of the cell cycle and inhibit the proliferation of ascitic and solid tumor cell lines in vitro, were tested for their ability to induce apoptosis in the HL-60 cell system. MATERIALS AND METHODS: Various markers of tumor cell metabolism, apoptosis induction and mitochondrial permeability transition (MPT) were assayed in vitro to evaluate drug cytotoxicity. RESULTS: All these compounds, and especially the pyrazole-fused pyranoxanthenones 7, 8 and 10, which were effective in the 3-5 microM range and were more potent than the pyranoxanthenones, reduced the proliferation of HL-60 cells at 2 and 4 days. These antitumor drugs inhibited DNA synthesis at 2 h in relation to their ability to block the cellular uptake of purine and pyrimidine nucleosides within 15 min. Internmucleosomal DNA fragmentation, a late marker of apoptosis, was induced in a concentration-dependent manner by 7 and 10 at 24 h. Poly(ADP-ribose) polymerase-1 (PARP-1) cleavage, an early event required for cells committed to apoptosis, was detected within 12 h in HL-60 cells treated with 7 and 10. In accord with the fact that the caspase cascade is responsible for PARP-1 cleavage, 7 and 10 induced the activities of initiator caspases-2 and -9 and effector caspase-3 within 9 h in HL-60 cells. The release of mitochondrial cytochrome c (Cyt c) was also detected within 9 h in HL-60 cells treated with 7 and 10, consistent with the fact that Cyt c is the apoptotic trigger that activates caspase-9. However, 7 and 10 neither caused the rapid collapse of mitochondrial transmembrane potential, nor the mitochondrial swelling linked to MPT. CONCLUSION: Pyrazole-fused pyranoxanthenones are DNA-interacting antiproliferative drugs that do not directly target mitochondria in cell and cell-free systems to induce the intrinsic pathway of apoptosis.

Antitumor triptycene analogs induce a rapid collapse of mitochondrial transmembrane potential in HL-60 cells and isolated mitochondria.

Since synthetic analogs of triptycene (TT code number), such as bisquinones TT2 and TT13, can trigger cytochrome c release without caspase activation and retain their ability to induce apoptosis in multidrug-resistant (MDR) tumor cells, fluorescent probes of transmembrane potential have been used to determine whether these antitumor compounds might directly target mitochondria in cell and cell-free systems to cause the collapse of mitochondrial membrane potential ( downward arrow Deltapsim) that is linked to permeability transition pore (PTP) opening. Using JC-1 dye, the abilities of various TT analogs to induce the downward arrow Deltapsim in wild-type and MDR HL-60 cells are rapid (within 5-20 min), irreversible after drug removal, concentration dependent in the 0.64-25 microM range, and generally related to their antitumor activities in vitro. The downward arrow Deltapsim caused by TT2 and TT13, which are more potent than mitoxantrone, staurosporine and the reference depolarizing agent, carbonyl cyanide m-chlorophenylhydrazone (CCCP), in HL-60 cells, are not prevented by caspase-2 or -8 inhibitors, suggesting that activation of these apical caspases upstream of mitochondria is not involved in this process. Antitumor TT analogs (0.64-25 microM) also mimic the abilities of the known depolarizing agents, CCCP, alamethicin, gramicidin A and 100 microM CaCl(2), to directly induce within 20 min the downward arrow Deltapsim in isolated mitochondria prepared from mouse liver and loaded with rhodamine 123 dye. The fact that 20 microM Ca(2+), which is insufficient to trigger depolarization on its own, is required to reveal the depolarizing effect of TT2 in isolated mitochondria suggests that antitumor TT analogs might interact with the PTP to alter its conformation and increase its Ca(2+) sensitivity. Indeed, such Ca(2+)-dependent downward arrowDeltapsim of isolated mitochondria treated with 25 microM TT2 or 100 microM Ca(2+) are blocked by ruthenium red. Daunorubicin (DAU) is unable to mimic the rapid downward arrowDeltapsim caused by antitumor TT bisquinones within 5-40 min of treatment in HL-60 cells or isolated mitochondria. Moreover, the downward arrowDeltapsim caused by 25 microM TT2 or 100 microM Ca(2+) in isolated mitochondria are similarly blocked by cyclosporin A (CsA), bongkrekic acid and decylubiquinone, which prevent PTP opening, suggesting that, in contrast to DAU, antitumor TT analogs that directly target mitochondria to trigger the Ca(2+)-dependent and CsA-sensitive downward arrowDeltapsim, might induce PTP opening and the mitochondrial pathway of apoptosis even in the absence of nuclear signals.

Rapid collapse of mitochondrial transmembrane potential in HL-60 cells and isolated mitochondria treated with anti-tumor 1,4-anthracenediones.

Since synthetic analogs of 1,4-anthraquinone (AQ code number), such as AQ8, AQ9 and AQ10, can trigger cytochrome c release without caspase activation and retain their ability to induce apoptosis in multidrug-resistant (MDR) tumor cells, fluorescent probes of transmembrane potential have been used to determine whether these anti-tumor compounds might directly target mitochondria in cell and cell-free systems to cause the collapse of mitochondrial membrane potential (/Deltapsim) that is linked to permeability transition pore (PTP) opening. Using JC-1 dye, the abilities of various AQ analogs to induce the /Deltapsim in wild-type and MDR HL-60 cells are rapid (within 2.5-10 min), irreversible after drug removal, concentration dependent in the 0.256-10 micromol/l range and generally related to their anti-tumor activities in vitro. The /Deltapsim caused by AQ9 and AQ10, which are more potent than mitoxantrone, staurosporine and the reference depolarizing agent carbonyl cyanide m-chlorophenylhydrazone (CCCP) in HL-60 cells, are not prevented by caspase-2 or -8 inhibitors, suggesting that activations of these apical caspases upstream of mitochondria are not involved in this process. Antitumor AQ analogs (0.256-10 micromol/l) also mimic the abilities of the known depolarizing agents CCCP, alamethicin, gramicidin A and 100 micromol/l CaCl2 to directly induce within 15 min the /Deltapsim in isolated mitochondria prepared from mouse liver and loaded with rhodamine 123 dye. The fact that 20 micromol/l Ca2+, which is insufficient to trigger depolarization on its own, is required to reveal the depolarizing effect of AQ9 in isolated mitochondria suggests that anti-tumor AQ analogs might interact with the PTP to alter its conformation and increase its Ca2+ sensitivity. Indeed, such Ca2+-dependent /Deltapsim of isolated mitochondria treated with 1.6 micromol/l AQ9 or 100 micromol/l Ca2+ are blocked by ruthenium red. Daunorubicin (DAU) is unable to mimic the rapid /Deltapsim caused by anti-tumor AQ analogs within 2.5-40 min of treatment in HL-60 cells or isolated mitochondria. Moreover, the /Deltapsim caused by 1.6 micromol/l AQ9 or 100 micromol/l Ca2+ in isolated mitochondria are similarly blocked by cyclosporin A (CsA), bongkrekic acid and decylubiquinone, which prevent PTP opening, suggesting that, in contrast to DAU, anti-tumor AQ analogs that directly target mitochondria to trigger the Ca2+-dependent and CsA-sensitive /Deltapsim, might induce PTP opening and the mitochondrial pathway of apoptosis even in the absence of nuclear signals.