Redox Modulation of PTEN Phosphatase Activity by Hydrogen Peroxide and Bisperoxidovanadium Complexes

PTEN is a dual‐specificity protein tyrosine phosphatase. As one of the central tumor suppressors, a thorough regulation of its activity is essential for proper cellular homeostasis. The precise implications of PTEN inhibition by reactive oxygen species (e.g. H2O2) and the subsequent structural conse...

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Veröffentlicht in:	Angewandte Chemie International Edition 2015-11, Vol.54 (46), p.13796-13800
Hauptverfasser:	Lee, Chang-Uk, Hahne, Gernot, Hanske, Jonas, Bange, Tanja, Bier, David, Rademacher, Christoph, Hennig, Sven, Grossmann, Tom N.
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Sprache:	eng
Schlagworte:	Activation bpV-phen Communications Crystallography Disulfides Dose-Response Relationship, Drug Humans Hydrogen Peroxide - chemistry Hydrogen Peroxide - pharmacology Inhibition inhibitors Mass spectrometry Models, Molecular Molecular Structure Organometallic Compounds - chemistry Organometallic Compounds - pharmacology Oxidation-Reduction Peroxides - chemistry Peroxides - pharmacology Phosphatase protein tyrosine phosphatase Proteins PTEN Phosphohydrolase - antagonists & inhibitors PTEN Phosphohydrolase - metabolism Structure-Activity Relationship Suppressors tumor suppressors Tumors Vanadium - chemistry Vanadium - pharmacology
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container_title	Angewandte Chemie International Edition
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creator	Lee, Chang-Uk Hahne, Gernot Hanske, Jonas Bange, Tanja Bier, David Rademacher, Christoph Hennig, Sven Grossmann, Tom N.
description	PTEN is a dual‐specificity protein tyrosine phosphatase. As one of the central tumor suppressors, a thorough regulation of its activity is essential for proper cellular homeostasis. The precise implications of PTEN inhibition by reactive oxygen species (e.g. H2O2) and the subsequent structural consequences remain elusive. To study the effects of PTEN inhibition, bisperoxidovanadium (bpV) complexes serve as important tools with the potential for the treatment of nerve injury or cardiac ischemia. However, their mode of action is unknown, hampering further optimization and preventing therapeutic applications. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, we elucidate the molecular basis of PTEN inhibition by H2O2 and bpV complexes. We show that both molecules inhibit PTEN via oxidative mechanisms resulting in the formation of the same intramolecular disulfide, therefore enabling the reactivation of PTEN under reductive conditions. An important tumor suppressor, the phosphatase PTEN, is crucially involved in regenerative processes. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, the molecular basis of PTEN inhibition by H2O2 and bisperoxidovanadium complexes has been elucidated. Both inhibit PTEN via oxidative mechanisms resulting in the formation of the same intramolecular disulfide, therefore enabling the reactivation of PTEN under reductive conditions.
doi_str_mv	10.1002/anie.201506338
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As one of the central tumor suppressors, a thorough regulation of its activity is essential for proper cellular homeostasis. The precise implications of PTEN inhibition by reactive oxygen species (e.g. H2O2) and the subsequent structural consequences remain elusive. To study the effects of PTEN inhibition, bisperoxidovanadium (bpV) complexes serve as important tools with the potential for the treatment of nerve injury or cardiac ischemia. However, their mode of action is unknown, hampering further optimization and preventing therapeutic applications. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, we elucidate the molecular basis of PTEN inhibition by H2O2 and bpV complexes. We show that both molecules inhibit PTEN via oxidative mechanisms resulting in the formation of the same intramolecular disulfide, therefore enabling the reactivation of PTEN under reductive conditions. An important tumor suppressor, the phosphatase PTEN, is crucially involved in regenerative processes. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, the molecular basis of PTEN inhibition by H2O2 and bisperoxidovanadium complexes has been elucidated. 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Chem. Int. Ed</addtitle><description>PTEN is a dual‐specificity protein tyrosine phosphatase. As one of the central tumor suppressors, a thorough regulation of its activity is essential for proper cellular homeostasis. The precise implications of PTEN inhibition by reactive oxygen species (e.g. H2O2) and the subsequent structural consequences remain elusive. To study the effects of PTEN inhibition, bisperoxidovanadium (bpV) complexes serve as important tools with the potential for the treatment of nerve injury or cardiac ischemia. However, their mode of action is unknown, hampering further optimization and preventing therapeutic applications. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, we elucidate the molecular basis of PTEN inhibition by H2O2 and bpV complexes. We show that both molecules inhibit PTEN via oxidative mechanisms resulting in the formation of the same intramolecular disulfide, therefore enabling the reactivation of PTEN under reductive conditions. An important tumor suppressor, the phosphatase PTEN, is crucially involved in regenerative processes. Based on protein crystallography, mass spectrometry, and NMR spectroscopy, the molecular basis of PTEN inhibition by H2O2 and bisperoxidovanadium complexes has been elucidated. 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Chem. Int. Ed</addtitle><date>2015-11-09</date><risdate>2015</risdate><volume>54</volume><issue>46</issue><spage>13796</spage><epage>13800</epage><pages>13796-13800</pages><issn>1433-7851</issn><issn>1521-3773</issn><eissn>1521-3773</eissn><coden>ACIEAY</coden><abstract>PTEN is a dual‐specificity protein tyrosine phosphatase. As one of the central tumor suppressors, a thorough regulation of its activity is essential for proper cellular homeostasis. The precise implications of PTEN inhibition by reactive oxygen species (e.g. H2O2) and the subsequent structural consequences remain elusive. To study the effects of PTEN inhibition, bisperoxidovanadium (bpV) complexes serve as important tools with the potential for the treatment of nerve injury or cardiac ischemia. However, their mode of action is unknown, hampering further optimization and preventing therapeutic applications. 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Both inhibit PTEN via oxidative mechanisms resulting in the formation of the same intramolecular disulfide, therefore enabling the reactivation of PTEN under reductive conditions.</abstract><cop>Weinheim</cop><pub>WILEY-VCH Verlag</pub><pmid>26418532</pmid><doi>10.1002/anie.201506338</doi><tpages>5</tpages><edition>International ed. in English</edition><oa>free_for_read</oa></addata></record>
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subjects	Activation bpV-phen Communications Crystallography Disulfides Dose-Response Relationship, Drug Humans Hydrogen Peroxide - chemistry Hydrogen Peroxide - pharmacology Inhibition inhibitors Mass spectrometry Models, Molecular Molecular Structure Organometallic Compounds - chemistry Organometallic Compounds - pharmacology Oxidation-Reduction Peroxides - chemistry Peroxides - pharmacology Phosphatase protein tyrosine phosphatase Proteins PTEN Phosphohydrolase - antagonists & inhibitors PTEN Phosphohydrolase - metabolism Structure-Activity Relationship Suppressors tumor suppressors Tumors Vanadium - chemistry Vanadium - pharmacology
title	Redox Modulation of PTEN Phosphatase Activity by Hydrogen Peroxide and Bisperoxidovanadium Complexes
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