Protein Cysteines Map to Functional Networks According to Steady-state Level of Oxidation.

The cysteine (Cys) proteome serves critical roles in protein structure, function and regulation, and includes key targets in oxidative mechanisms of disease. Thioredoxins maintain Cys residues in thiol forms, and previous research shows that the redox potential of thioredoxin in mitochondria and nuclei is more reduced than cytoplasm, suggesting that proteins in these compartments may have different steady-state oxidation. This study measured fractional oxidation of 641 peptidyl Cys residues from 333 proteins in HT29 cells by mass spectrometry. Average oxidation of cytoplasmic, nuclear and mitochondrial proteins was similar (15.8, 15.5, 14%, respectively). Pathway analysis showed that more reduced cytoplasmic Cys were in proteins associated with the cytoskeleton, more reduced nuclear Cys with Ran signaling and RNA post-transcriptional modifcation, and more reduced mitochondrial Cys with energy metabolism, cell growth and cell proliferation. More oxidized cytoplasmic Cys included associations with PI3/Akt, Myc-mediated apoptosis and 14-3-3-mediated signaling. Weaker associations of oxidized nuclear and mitochondrial Cys occurred with granzyme B signaling and intermediary metabolism, respectively. Thus, steady-state peptidyl Cys oxidation is associated with functional pathways rather than simply with organellar distribution. This suggests that oxidative mechanisms of disease could target functional pathways or networks rather than individual proteins or subcellular compartments.

[1]  Dean P. Jones,et al.  Mapping the cysteine proteome: analysis of redox-sensing thiols. , 2011, Current opinion in chemical biology.

[2]  J. Heo Redox control of GTPases: from molecular mechanisms to functional significance in health and disease. , 2011, Antioxidants & redox signaling.

[3]  D. Jones,et al.  Redox sensing: orthogonal control in cell cycle and apoptosis signalling , 2010, Journal of internal medicine.

[4]  R. Ralhan,et al.  Small Interfering RNA Targeting 14-3-3ζ Increases Efficacy of Chemotherapeutic Agents in Head and Neck Cancer Cells , 2010, Molecular Cancer Therapeutics.

[5]  David Baker,et al.  Quantitative reactivity profiling predicts functional cysteines in proteomes , 2010, Nature.

[6]  Roland L Dunbrack,et al.  Structural profiling of endogenous S-nitrosocysteine residues reveals unique features that accommodate diverse mechanisms for protein S-nitrosylation , 2010, Proceedings of the National Academy of Sciences.

[7]  A. Holmgren,et al.  Thioredoxin and thioredoxin reductase: current research with special reference to human disease. , 2010, Biochemical and biophysical research communications.

[8]  T. Hurd,et al.  Cysteine residues exposed on protein surfaces are the dominant intramitochondrial thiol and may protect against oxidative damage , 2010, The FEBS journal.

[9]  H. Forman,et al.  Signaling functions of reactive oxygen species. , 2010, Biochemistry.

[10]  Dean P. Jones,et al.  A key role for mitochondria in endothelial signaling by plasma cysteine/cystine redox potential. , 2010, Free radical biology & medicine.

[11]  Rosa E. Hansen,et al.  An introduction to methods for analyzing thiols and disulfides: Reactions, reagents, and practical considerations. , 2009, Analytical biochemistry.

[12]  Kate S Carroll,et al.  Mining the thiol proteome for sulfenic acid modifications reveals new targets for oxidation in cells. , 2009, ACS chemical biology.

[13]  James R. Roede,et al.  Lipid aldehyde-mediated cross-linking of apolipoprotein B-100 inhibits secretion from HepG2 cells. , 2009, Biochimica et biophysica acta.

[14]  Albert-László Barabási,et al.  Scale-Free Networks: A Decade and Beyond , 2009, Science.

[15]  D. Duong,et al.  Systematical optimization of reverse-phase chromatography for shotgun proteomics. , 2009, Journal of proteome research.

[16]  J. García,et al.  Role of nuclear glutathione as a key regulator of cell proliferation. , 2009, Molecular aspects of medicine.

[17]  Molly M Gallogly,et al.  Molecular mechanisms and clinical implications of reversible protein S-glutathionylation. , 2008, Antioxidants & redox signaling.

[18]  Dean P. Jones Radical-free biology of oxidative stress. , 2008, American journal of physiology. Cell physiology.

[19]  J. Strahler,et al.  Quantifying changes in the thiol redox proteome upon oxidative stress in vivo , 2008, Proceedings of the National Academy of Sciences.

[20]  Dean P. Jones,et al.  Nonequilibrium thermodynamics of thiol/disulfide redox systems: a perspective on redox systems biology. , 2008, Free radical biology & medicine.

[21]  D. Liebler,et al.  Mitochondrial protein targets of thiol-reactive electrophiles. , 2008, Chemical research in toxicology.

[22]  G. Verdine,et al.  The Challenge of Drugging Undruggable Targets in Cancer: Lessons Learned from Targeting BCL-2 Family Members , 2007, Clinical Cancer Research.

[23]  Dean P. Jones,et al.  Reactive aldehyde modification of thioredoxin-1 activates early steps of inflammation and cell adhesion. , 2007, The American journal of pathology.

[24]  Dean P. Jones,et al.  Control of extracellular cysteine/cystine redox state by HT-29 cells is independent of cellular glutathione. , 2007, American journal of physiology. Regulatory, integrative and comparative physiology.

[25]  R. Sitia,et al.  Managing and exploiting stress in the antibody factory , 2007, FEBS letters.

[26]  Dean P. Jones,et al.  Nuclear and Cytoplasmic Peroxiredoxin-1 Differentially Regulate NF-KAPPA B Activities , 2007 .

[27]  Robert W. Li,et al.  Pathway analysis identifies perturbation of genetic networks induced by butyrate in a bovine kidney epithelial cell line , 2007, Functional & Integrative Genomics.

[28]  Dean P. Jones,et al.  Selective oxidative stress in cell nuclei by nuclear-targeted D-amino acid oxidase. , 2007, Antioxidants & redox signaling.

[29]  Catherine E Costello,et al.  Quantification of oxidative posttranslational modifications of cysteine thiols of p21ras associated with redox modulation of activity using isotope-coded affinity tags and mass spectrometry. , 2007, Free radical biology & medicine.

[30]  Steven P Gygi,et al.  Target-decoy search strategy for increased confidence in large-scale protein identifications by mass spectrometry , 2007, Nature Methods.

[31]  Dean P. Jones,et al.  Selective protection of nuclear thioredoxin-1 and glutathione redox systems against oxidation during glucose and glutamine deficiency in human colonic epithelial cells. , 2007, Free radical biology & medicine.

[32]  Dean P. Jones,et al.  Mitochondrial thioredoxin in regulation of oxidant‐induced cell death , 2006, FEBS letters.

[33]  H. Gilbert Molecular and cellular aspects of thiol-disulfide exchange. , 2006, Advances in enzymology and related areas of molecular biology.

[34]  T. Hampton Targeted Cancer Therapies Lagging , 2006 .

[35]  M. Toledano,et al.  The Saccharomyces cerevisiae Proteome of Oxidized Protein Thiols , 2006, Journal of Biological Chemistry.

[36]  Yiling Lu,et al.  Exploiting the PI3K/AKT Pathway for Cancer Drug Discovery , 2005, Nature Reviews Drug Discovery.

[37]  L. Penn,et al.  Cancer therapeutics: targeting the dark side of Myc. , 2005, European journal of cancer.

[38]  John D. Storey,et al.  A network-based analysis of systemic inflammation in humans , 2005, Nature.

[39]  Daniel C Liebler,et al.  Specific Patterns of Electrophile Adduction Trigger Keap1 Ubiquitination and Nrf2 Activation* , 2005, Journal of Biological Chemistry.

[40]  K. Wells,et al.  Global shifts in protein sumoylation in response to electrophile and oxidative stress. , 2004, Chemical research in toxicology.

[41]  Dean P Jones,et al.  Cysteine/cystine couple is a newly recognized node in the circuitry for biologic redox signaling and control , 2004, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[42]  John Nguyen,et al.  Formation of disulfide bond in p53 correlates with inhibition of DNA binding and tetramerization. , 2003, Antioxidants & redox signaling.

[43]  Dean P. Jones,et al.  Redox Potential of Human Thioredoxin 1 and Identification of a Second Dithiol/Disulfide Motif* , 2003, Journal of Biological Chemistry.

[44]  E. Tekle,et al.  Stable and controllable RNA interference: Investigating the physiological function of glutathionylated actin , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[45]  Henry M. Fales,et al.  Reversible Glutathionylation Regulates Actin Polymerization in A431 Cells* , 2001, The Journal of Biological Chemistry.

[46]  Freya Q. Schafer,et al.  Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple. , 2001, Free radical biology & medicine.

[47]  Dean P. Jones,et al.  Glutathione redox potential in response to differentiation and enzyme inducers. , 1999, Free radical biology & medicine.

[48]  S. Gygi,et al.  Quantitative analysis of complex protein mixtures using isotope-coded affinity tags , 1999, Nature Biotechnology.

[49]  Dean P. Jones,et al.  Glutathione measurement in human plasma. Evaluation of sample collection, storage and derivatization conditions for analysis of dansyl derivatives by HPLC. , 1998, Clinica chimica acta; international journal of clinical chemistry.

[50]  K. Mori,et al.  AP-1 transcriptional activity is regulated by a direct association between thioredoxin and Ref-1. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[51]  J. Yates,et al.  An approach to correlate tandem mass spectral data of peptides with amino acid sequences in a protein database , 1994, Journal of the American Society for Mass Spectrometry.

[52]  T. Hirano,et al.  Mitochondrial glutathione depletion in alcoholic liver disease. , 1993, Alcohol.

[53]  T. Curran,et al.  Redox regulation of fos and jun DNA-binding activity in vitro. , 1990, Science.

[54]  S. Orrenius,et al.  Menadione-induced bleb formation in hepatocytes is associated with the oxidation of thiol groups in actin. , 1988, Archives of biochemistry and biophysics.

[55]  D. P. Jones,et al.  Distribution of oxidized and reduced forms of glutathione and cysteine in rat plasma. , 1985, Archives of biochemistry and biophysics.

[56]  D. J. Reed,et al.  Status of the mitochondrial pool of glutathione in the isolated hepatocyte. , 1982, The Journal of biological chemistry.

[57]  K. Summer,et al.  Hydroperoxide-metabolizing systems in rat liver. , 1975, European journal of biochemistry.

[58]  C. Winterbourn,et al.  Redox chemistry of biological thiols , 2010 .

[59]  Dean P. Jones,et al.  Quantification of redox conditions in the nucleus. , 2009, Methods in molecular biology.

[60]  Yu Shyr,et al.  Cytosolic and nuclear protein targets of thiol-reactive electrophiles. , 2006, Chemical research in toxicology.

[61]  Joshua E. Elias,et al.  Evaluation of multidimensional chromatography coupled with tandem mass spectrometry (LC/LC-MS/MS) for large-scale protein analysis: the yeast proteome. , 2003, Journal of proteome research.

[62]  L. Packer,et al.  Redox regulation of NF-kappa B activation. , 1997, Free radical biology & medicine.

[63]  D. P. Jones,et al.  Selective depletion of mitochondrial glutathione concentrations by (R,S)-3-hydroxy-4-pentenoate potentiates oxidative cell death. , 1993, Chemical research in toxicology.

[64]  D. Ziegler Role of reversible oxidation-reduction of enzyme thiols-disulfides in metabolic regulation. , 1985, Annual review of biochemistry.

[65]  J. Sedlák,et al.  Estimation of total, protein-bound, and nonprotein sulfhydryl groups in tissue with Ellman's reagent. , 1968, Analytical biochemistry.