The novel phloroglucinol PMT7 kills glycolytic cancer cells by blocking autophagy and sensitizing to nutrient stress

The switch from oxidative phosphorylation to glycolytic metabolism results in cells that generate fewer reactive oxygen species (ROS) and are resistant to the intrinsic induction of apoptosis. As a consequence, glycolytic cancer cells are resistant to radiation and chemotherapeutic agents that rely...

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Veröffentlicht in:	Journal of cellular biochemistry 2011-07, Vol.112 (7), p.1869-1879
Hauptverfasser:	Broadley, Kate, Larsen, Lesley, Herst, Patries M., Smith, Robin A.J., Berridge, Michael V., McConnell, Melanie J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Antineoplastic Agents - pharmacology Autophagy Autophagy - drug effects Benzoquinones - chemical synthesis Benzoquinones - pharmacology Cell death Cell Line, Tumor Culture Media, Serum-Free Electron Transport Energetic stress Gene Knockout Techniques Glycolysis Glycolytic metabolism Humans Membrane Potential, Mitochondrial - drug effects Mitochondria - genetics Mitochondrial membrane potential Nutrient stress Oxidation-Reduction RNA Interference Sirtuin 1 - genetics Sirtuin 1 - metabolism Stress, Physiological Superoxides - metabolism Tetrazolium Salts - chemistry Tetrazolium Salts - metabolism Thiazoles - chemistry Thiazoles - metabolism
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container_end_page	1879
container_issue	7
container_start_page	1869
container_title	Journal of cellular biochemistry
container_volume	112
creator	Broadley, Kate Larsen, Lesley Herst, Patries M. Smith, Robin A.J. Berridge, Michael V. McConnell, Melanie J.
description	The switch from oxidative phosphorylation to glycolytic metabolism results in cells that generate fewer reactive oxygen species (ROS) and are resistant to the intrinsic induction of apoptosis. As a consequence, glycolytic cancer cells are resistant to radiation and chemotherapeutic agents that rely on production of ROS or intrinsic apoptosis. Further, the level of glycolysis correlates with tumor invasion, making glycolytic cancer cells an important target for new therapy development. We have synthesized a novel redox‐active quinone phloroglucinol derivative, PMT7. Toxicity of PMT7 was in part due to loss of mitochondrial membrane potential in treated cells with subsequent loss of mitochondrial metabolic activity. Mitochondrial gene knockout ρ0 cells, a model of highly glycolytic cancers, were only half as sensitive as the corresponding wild‐type cells and metabolic pathways downstream of MET were unaffected in ρ0 cells. However, PMT7 toxicity was also due to a block in autophagy. Both wild‐type and ρ0 cells were susceptible to autophagy blockade, and the resistance of ρ0 cells to PMT7 could be overcome by serum deprivation, a situation where autophagy becomes necessary for survival. The stress response class III deacetylase SIRT1 was not significantly involved in PMT7 toxicity, suggesting that unlike other chemotherapeutic drugs, SIRT1‐mediated stress and survival responses were not induced by PMT7. The dependence on autophagy or other scavenging pathways makes glycolytic cancer cells vulnerable. This can be exploited by induction of energetic stress to specifically sensitize glycolytic cells to other stresses such as nutrient deprivation or potentially chemotherapy. J. Cell. Biochem. 112: 1869–1879, 2011. © 2011 Wiley‐Liss, Inc.
doi_str_mv	10.1002/jcb.23107
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Both wild‐type and ρ0 cells were susceptible to autophagy blockade, and the resistance of ρ0 cells to PMT7 could be overcome by serum deprivation, a situation where autophagy becomes necessary for survival. The stress response class III deacetylase SIRT1 was not significantly involved in PMT7 toxicity, suggesting that unlike other chemotherapeutic drugs, SIRT1‐mediated stress and survival responses were not induced by PMT7. The dependence on autophagy or other scavenging pathways makes glycolytic cancer cells vulnerable. This can be exploited by induction of energetic stress to specifically sensitize glycolytic cells to other stresses such as nutrient deprivation or potentially chemotherapy. J. Cell. 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Cell. Biochem</addtitle><description>The switch from oxidative phosphorylation to glycolytic metabolism results in cells that generate fewer reactive oxygen species (ROS) and are resistant to the intrinsic induction of apoptosis. As a consequence, glycolytic cancer cells are resistant to radiation and chemotherapeutic agents that rely on production of ROS or intrinsic apoptosis. Further, the level of glycolysis correlates with tumor invasion, making glycolytic cancer cells an important target for new therapy development. We have synthesized a novel redox‐active quinone phloroglucinol derivative, PMT7. Toxicity of PMT7 was in part due to loss of mitochondrial membrane potential in treated cells with subsequent loss of mitochondrial metabolic activity. Mitochondrial gene knockout ρ0 cells, a model of highly glycolytic cancers, were only half as sensitive as the corresponding wild‐type cells and metabolic pathways downstream of MET were unaffected in ρ0 cells. However, PMT7 toxicity was also due to a block in autophagy. Both wild‐type and ρ0 cells were susceptible to autophagy blockade, and the resistance of ρ0 cells to PMT7 could be overcome by serum deprivation, a situation where autophagy becomes necessary for survival. The stress response class III deacetylase SIRT1 was not significantly involved in PMT7 toxicity, suggesting that unlike other chemotherapeutic drugs, SIRT1‐mediated stress and survival responses were not induced by PMT7. The dependence on autophagy or other scavenging pathways makes glycolytic cancer cells vulnerable. This can be exploited by induction of energetic stress to specifically sensitize glycolytic cells to other stresses such as nutrient deprivation or potentially chemotherapy. J. Cell. 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Mitochondrial gene knockout ρ0 cells, a model of highly glycolytic cancers, were only half as sensitive as the corresponding wild‐type cells and metabolic pathways downstream of MET were unaffected in ρ0 cells. However, PMT7 toxicity was also due to a block in autophagy. Both wild‐type and ρ0 cells were susceptible to autophagy blockade, and the resistance of ρ0 cells to PMT7 could be overcome by serum deprivation, a situation where autophagy becomes necessary for survival. The stress response class III deacetylase SIRT1 was not significantly involved in PMT7 toxicity, suggesting that unlike other chemotherapeutic drugs, SIRT1‐mediated stress and survival responses were not induced by PMT7. The dependence on autophagy or other scavenging pathways makes glycolytic cancer cells vulnerable. This can be exploited by induction of energetic stress to specifically sensitize glycolytic cells to other stresses such as nutrient deprivation or potentially chemotherapy. J. Cell. 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subjects	Antineoplastic Agents - pharmacology Autophagy Autophagy - drug effects Benzoquinones - chemical synthesis Benzoquinones - pharmacology Cell death Cell Line, Tumor Culture Media, Serum-Free Electron Transport Energetic stress Gene Knockout Techniques Glycolysis Glycolytic metabolism Humans Membrane Potential, Mitochondrial - drug effects Mitochondria - genetics Mitochondrial membrane potential Nutrient stress Oxidation-Reduction RNA Interference Sirtuin 1 - genetics Sirtuin 1 - metabolism Stress, Physiological Superoxides - metabolism Tetrazolium Salts - chemistry Tetrazolium Salts - metabolism Thiazoles - chemistry Thiazoles - metabolism
title	The novel phloroglucinol PMT7 kills glycolytic cancer cells by blocking autophagy and sensitizing to nutrient stress
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