Quercetin-3-O-(2”-galloyl)-α-l-rhamnopyranoside prevents TRAIL-induced apoptosis in human keratinocytes by suppressing the caspase-8- and Bid-pathways and the mitochondrial pathway

ABSTRACT Apoptosis was induced rapidly in HeLa cells after exposure to bacterial Shiga toxin (Stx1 and Stx2; 10 ng/ml). Approximately 60% of HeLa cells became apoptotic within 4 h as detected by DNA fragmentation, terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling (TUNEL) assay, and electron microscopy. Stx1-induced apoptosis required enzymatic activity of the Stx1A subunit, and apoptosis was not induced by the Stx2B subunit alone or by the anti-globotriaosylceramide antibody. This activity was also inhibited by brefeldin A, indicating the need for toxin processing through the Golgi apparatus. The intracellular pathway leading to apoptosis was further defined. Exposure of HeLa cells to Stx1 activated caspases 3, 6, 8, and 9, as measured both by an enzymatic assay with synthetic substrates and by detection of proteolytically activated forms of these caspases by Western immunoblotting. Preincubation of HeLa cells with substrate inhibitors of caspases 3, 6, and 8 protected the cells against Stx1-dependent apoptosis. These results led to a more detailed examination of the mitochondrial pathway of apoptosis. Apoptosis induced by Stx1 was accompanied by damage to mitochondrial membranes, measured as a reduced mitochondrial membrane potential, and increased release of cytochrome c from mitochondria at 3 to 4 h. Bid, an endogenous protein known to permeabilize mitochondrial membranes, was activated in a Stx1-dependent manner. Caspase-8 is known to activate Bid, and a specific inhibitor of caspase-8 prevented the mitochondrial damage. Although these data suggested that caspase-8-mediated cleavage of Bid with release of cytochrome c from mitochondria and activation of caspase-9 were responsible for the apoptosis, preincubation of HeLa cells with a specific inhibitor of caspase-9 did not protect against apoptosis. These results were explained by the discovery of a simultaneous Stx1-dependent increase in endogenous XIAP, a direct inhibitor of caspase-9. We conclude that the primary pathway of Stx1-induced apoptosis and DNA fragmentation in HeLa cells is unique and includes caspases 8, 6, and 3 but is independent of events in the mitochondrial pathway.

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Differential Regulation and ATP Requirement for Caspase-8 and Caspase-3 Activation during CD95- and Anticancer Drug–induced Apoptosis

Journal of Experimental Medicine ◽

10.1084/jem.188.5.979 ◽

1998 ◽

Vol 188 (5) ◽

pp. 979-984 ◽

Cited By ~ 130

Author(s):

Davide Ferrari ◽

Ania Stepczynska ◽

Marek Los ◽

Sebastian Wesselborg ◽

Klaus Schulze-Osthoff

Keyword(s):

Death Receptor ◽

Mitochondrial Pathway ◽

Atp Depletion ◽

Caspase 8 ◽

Chemotherapeutic Drugs ◽

Caspase Activation ◽

Drug Induced ◽

Regulatory Pathways ◽

Atp Production ◽

Induced Apoptosis

Apoptosis is induced by different stimuli, among them triggering of the death receptor CD95, staurosporine, and chemotherapeutic drugs. In all cases, apoptosis is mediated by caspases, although it is unclear how these diverse apoptotic stimuli cause protease activation. Two regulatory pathways have been recently identified, but it remains unknown whether they are functionally independent or linked to each other. One is mediated by recruitment of the proximal regulator caspase-8 to the death receptor complex. The other pathway is controlled by the release of cytochrome c from mitochondria and the subsequent ATP-dependent activation of the death regulator apoptotic protease-activating factor 1 (Apaf-1). Here, we report that both pathways can be dissected by depletion of intracellular ATP. Prevention of ATP production completely inhibited caspase activation and apoptosis in response to chemotherapeutic drugs and staurosporine. Interestingly, caspase-8, whose function appeared to be restricted to death receptors, was also activated by these drugs under normal conditions, but not after ATP depletion. In contrast, inhibition of ATP production did not affect caspase activation after triggering of CD95. These results suggest that chemotherapeutic drug–induced caspase activation is entirely controlled by a receptor-independent mitochondrial pathway, whereas CD95-induced apoptosis can be regulated by a separate pathway not requiring Apaf-1 function.

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Baicalein attenuates proteasome inhibition-induced apoptosis by suppressing the activation of the mitochondrial pathway and the caspase-8- and Bid-dependent pathways

European Journal of Pharmacology ◽

10.1016/j.ejphar.2014.02.039 ◽

2014 ◽

Vol 730 ◽

pp. 116-124 ◽

Cited By ~ 16

Author(s):

Eun Byul Jung ◽

Chung Soo Lee

Keyword(s):

Proteasome Inhibition ◽

Mitochondrial Pathway ◽

Caspase 8 ◽

Induced Apoptosis

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Triptolide-Induced Apoptosis Is Dependent on Caspase Activation and NFκB Signaling and Mediated by XIAP and Survivin Downregulation through the Mitochondrial Pathway in Leukemic Cells.

Blood ◽

10.1182/blood.v104.11.3394.3394 ◽

2004 ◽

Vol 104 (11) ◽

pp. 3394-3394

Author(s):

Bing Z. Carter ◽

Wendy D. Schober ◽

Teresa McQueen ◽

Randall L. Evans ◽

Michael Andreeff

Keyword(s):

Cell Death ◽

Cell Growth ◽

Chinese Herb ◽

Mitochondrial Pathway ◽

Jurkat Cells ◽

Leukemic Cells ◽

Parp Cleavage ◽

Caspase 8 ◽

Imatinib Resistance ◽

Induced Apoptosis

Abstract Triptolide, an immunosuppressor isolated from the Chinese herb, Tripterygium wilfordii Hook. F, has recently shown anti-tumor activities in a broad range of solid tumors. We examined its effects on leukemic cells and investigated mechanisms of apoptosis. Triptolide, at less than 100 nM, arrested cell growth and potently induced cell death in myeloid and lymphoid leukemic cells tested, including OCI-AML3, U937, Jurkat, KBM5, and K562 cells. In OCI-AML3 cells, triptolide induced caspase 3 activation, PARP cleavage and annexin V positivity with an IC50 of about 30 nM, at 24 hrs, all of which were inhibited by a general caspase inhibitor suggesting caspase dependent cell death. However, Triptolide-induced cell growth arrest was not affected by caspase inhibition. Treatment of OCI-AML3 cells with triptolide decreased XIAP and survivin expression, but did not affect Bcl2 and BclXL levels. Forced overexpression of XIAP attenuated Triptolide-induced cell death. Triptolide induced Bid cleavage, but Jurkat cells deficient in caspase 8 were only slightly less sensitive to triptolide than the wild-type counterpart indicating that Triptolide-induced cell death is caspase 8 independent. Jurkat cells deficient in receptor interacting protein (RIP) and therefore deficient in NFκB activation were resistant to Triptolide demonstrating that NFκB signaling is essential for Triptolide-induced cell death. Triptolide treatment induced cytosolic release of cytochrome C and loss of mitochondrial membrane potential, overexpression of Bcl2 effectively suppressed apoptosis induced by Triptolide, and caspase 9 knockout MEF cells were resistant to Triptolide suggesting criticality of the mitochondrial pathway. The antioxidants GSH (5 mM) and vitamin C (150 μM) did not protect from apoptotic cell death induced by Triptolide. In addition, Triptolide-induced apoptosis of blast crisis CML KBM5 cells was independent of their sensitivity or resistance to Imatinib: Triptolide killed Imatinib resistant KBMSTI cells as effectively as Imatinib sensitive KBM5 cells. Ex vivo studies showed that Triptolide also induced cell death in primary AML blasts. Collectively, our studies demonstrate that Triptolide potently induces caspase-dependent apoptosis and arrests cell growth in leukemic cells. Triptolide-induced cell death is dependent on NFκB signaling, and mediated by downregulation of XIAP and survivin through the mitochondrial pathway. The potent anti-leukemic activity of Triptolide in vitro warrants further investigation of this compound for the treatment of leukemia and other malignancies. This drug may also be potentially useful in overcoming Imatinib resistance in CML and Philadelphia chromosome positive ALL.

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