Presentation is loading. Please wait.

Presentation is loading. Please wait.

Measuring the poise of thiol/disulfide redox in vivo Dean P. Jones, Ph.D. Department of Medicine/Division of Pulmonary, Allergy and Critical Care Medicine.

Published byWilla Stephens Modified over 8 years ago

Similar presentations

Presentation on theme: "Measuring the poise of thiol/disulfide redox in vivo Dean P. Jones, Ph.D. Department of Medicine/Division of Pulmonary, Allergy and Critical Care Medicine."— Presentation transcript:

1 Measuring the poise of thiol/disulfide redox in vivo Dean P. Jones, Ph.D. Department of Medicine/Division of Pulmonary, Allergy and Critical Care Medicine Emory University, Atlanta Emory Clinical Biomarkers Laboratory

2 The redox state of GSH/GSSG provides a measure of the balance of prooxidants and antioxidants Jones Meth Enzymol 2002 GSH GSSG Redox states of different couples can be compared by expression as redox potentials E h = E o + * ln [Ox]_ [Red] RT nF Low molecular weight thiols and disulfides are measured by HPLC

3 Reversible oxidation of thiols alters protein structure and function Active site Reduced Trx1Oxidized Trx1 Watson et al. 2003

4 Active site Redox "OFF" switch Dimerization site S-Glutathiylation site, S-Alkylation site S-Nitrosylation site ASK-1 docking regulatory site All cysteines in Trx1 are important in Trx1 function

5 Protein thiol/disulfide redox states are measured by Redox Western blot analysis Trx1-Ox2 Trx1-Ox1 Trx1-Red Trx1-Ox2 Trx1-Ox1 Trx1-Red 0 2 10 30 60 120 Time (min) after H 2 O 2 Nuclei Cytoplasm µM tBH 0 50 200 300 400 Trx1 R Trx1 O Trx2 R Trx2 O Watson, Jones FEBS Lett 2003 Watson et al, JBC 2003 Chen et al FEBS Lett 2006 SDS-PAGE separation by mass following treatment with AMS Native gel separation by charge following treatment with IAA Cytoplasm Mitochondria

6 Quantification of thiol/disulfide redox in biologic systems has provided 3 general conclusions 1. At the cellular level, GSH redox becomes oxidized as cells progress through the life cycle, and cells regulate extracellular thiol/disulfide redox state 2. At the systemic level, plasma GSH redox becomes oxidized with oxidative stress and is oxidized in association with aging and chronic disease 3. In cells and plasma, GSH redox is NOT equilibrated with thioredoxin or Cys/CySS, providing the basis to consider discrete redox circuits for redox signaling and control

7 Redox State (E h, mV) Proliferation Apoptosis Differentiation Redox of GSH/GSSG becomes progressively oxidized in the life cycle of cells -250 -200 -150 -250 -200 -150 Kirlin et al, FRBM 1999; Nkabyo et al, Am J Physiol 2002 1:1 1:10 10:1 100:1 -(SH) 2 :-SS-

8 Extracellular Cys/CySS pool in culture is regulated to a value very similar to that in human plasma Extracellular E h (Cys/CySS) (mV) 0 4812162024 Time (h) -120 -100 -80 -60 -40 -20 +200  M Cysteine +100  M Cystine HT29 cells E h (mV) E h, Cys/CySS Mean=-72.4 StDev=12.8 E h, GSH/GSSG Mean=-130.9 StDev=22.9 Frequency Plasma, 740 subjects Go and Jones, Circulation 2005 Jonas et al, FRBM 2002

9 Interorgan GSH/Cysteine balance Tissues Plasma GSH/GSSG Cys/CySS Major pool Most reduced Major pool Most oxidized -138 mV -220 mV -150mV -80 mV

10 Quantification of thiol/disulfide redox in biologic systems has provided 3 conclusions 1. At the cellular level: Cells regulate extracellular thiol/disulfide redox state. Cellular GSH redox becomes oxidized as cells progress through the life cycle 2. At the systemic level: Plasma GSH redox becomes oxidized with oxidative stress. Plasma redox is oxidized with aging, nutritional deficiency, toxicity and chronic disease 3. Relationship of redox couples: GSH redox is NOT equilibrated with thioredoxin or Cys/CySS. This provides the basis to consider discrete redox circuits for redox signaling and control

11 Many people have redox states more oxidized than young healthy individuals Extracellular E h (Cys/CySS) (mV) 0 4812162024 Time (h) -120 -100 -80 -60 -40 -20 +200  M Cysteine +100  M Cystine HT29 cells E h (mV) E h, Cys/CySS Mean=-72.4 StDev=12.8 E h, GSH/GSSG Mean=-130.9 StDev=22.9 Frequency Plasma, 740 subjects Young healthy in RED Go and Jones, Circulation 2005 Jonas et al, FRBM 2002 Reduced Oxidized Reduced

12 Plasma redox provides a useful measure of oxidative stress in humans GSH & Cys redox oxidized with age GSH redox is oxidized with chemotherapyAntioxidants decrease Cys oxidation with age Cys redox oxidized with smoking Jones, FRBM 2002 Jonas, Am J Clin Nutr 2000 Moriarty, FRBM 2004 Moriarty-Craige, Am J Ophthalmol 2005 536466 Smoking Status CurrentPriorNever E h Cys (mV) - 90 - 80 - 70 - 60 * 536466N = CurrentPriorNever - 90 - 80 - 70 - 60 * -100 -120 -140 7072747678 Age (y) E h GSH (mV) P = 0.002 for effect of time Mean age = 71.7 Mean age = 76.3 -100 -120 -140 7072747678 P = 0.002 for effect of time Mean age = 71.7 Mean age = 76.3 +Vit C, E,  -car Control

13 Plasma redox is oxidized in association with disease and disease risk -110 <60 Controls >60 Controls Type 2 Diabetes ** -135 GSH/GSSG E h (mV) * * GSH/GSSG is oxidized in T2 Diabetes Samiec et al, FRBM 1998 E h GSH/GSSG predicts IMT 0.59 0.61 0.67 0.54 0.58 0.62 0.66 E h GSH/GSSG Carotid IMT (mm) < -130 mV p value 0.009 > -120 mV-120 to -130 mV Ashfaq et al, Am Coll Cardiol 2006

14 Increased Carotid Intima Media Thickness Chemotherapy/BMT Cigarette Smoking Type 2 Diabetes Reversible myocardial perfusion defects Pathophysiologic correlation Low antioxidants, low dietary cysteine Health -80 mV -20 mV (-80 mV) -50 mV (-110 mV) Cys/CySS Redox (GSH/GSSG Redox) (-140 mV) Jones, Antiox Redox Signal, 2006 Lung transplantation Alcohol abuse Aging -62 mV (-122 mV)

15 Quantification of thiol/disulfide redox in biologic systems has provided 3 general conclusions 1. At the cellular level, GSH redox becomes oxidized as cells progress through the life cycle, and cells regulate extracellular thiol/disulfide redox state 2. At the systemic level, plasma GSH redox becomes oxidized with oxidative stress and is oxidized in association with aging and chronic disease 3. In cells and plasma, GSH redox is NOT equilibrated with thioredoxin or Cys/CySS, providing the basis to consider discrete redox circuits for redox signaling and control

16 -250 -200 -150 Redox State (E -300 -250 -200 -150 Redox State (E h, mV) -300 Proliferation Apoptosis Proliferation Differentiation Trx GSH Differentiation Apoptosis Proliferation Differentiation Cys GSH, Trx and Cys redox systems are not in redox equilibrium in cells Jones et al FASEB J 2004

17 H2O2H2O2 Trx -300 -200 -150 -250 Cys/CySS GSH/GSSG (apoptosis) NADPH E h (mV) 4 GR TR1 O2O2 SO O2O2 TO 2 5/GPx GSH/GSSG (differentiation) 6b 1/Prx 6a GSH/GSSG (proliferation) Cellular Extracellular H2O2H2O2 Grx 3 GSH/GSSG, Trx and Cys/CySS provide independent nodes for redox signaling and control Jones et al, FASEB J 2004

18 GSH/GSSG Cys/CySS GSH/GSSG Cys/CySS Trx/TrxSS EGFR  MAPK activation KEAP-1  Nrf-2 translocation to nucleus Trx/TrxSS ASK-1  Apoptosis Nrf-2  DNA binding Protein synthesis Protein S-thiylation Redox-dependent systems are differentially controlled by GSH, Trx1 and Cys redox couples

19 GSH/GSSG Trx(-SH) 2 /SS Cys/CySS Trx1(-SH) 2 /SS Cys/CySS GSH/GSSG Trx2(-SH) 2 /SS GSH/GSSG Plasma/Interstitial Cytoplasmic Nuclear Mitochondrial Endoplasmic Reticulum GSH/GSSG PDI Hansen et al, Annu Rev Pharm Tox, 2006 GSH/GSSG Compartmentation of thiol/disulfide redox state

20 Trx2 is preferentially oxidized by TNF  0 5 10 20 40 1 TNF  (ng/ml) H 2 O 2 (mM) H 2 O 2 (mM) TNF  (ng/ml) 0 5 10 20 40 H2O2 Thioredoxin-1 Thioredoxin-2 TNF  (ng/ml) -300 -280 -260 -240 Redox Potential (Eh) -380 -360 -340 -320 -300 -280 Redox Potential (Eh) J. Hansen

21 Mitochondrial redox circuits NADPH NADH Cyt c O2O2 GR GSH -400 -200 0 +200 +400 +600 Redox Signaling and Control Circuits (low flux) Metabolic Redox Circuits (high flux) EhEh Pyr Mal Succinate MPT TR2 Trx2 O2O2 NADPH GPxPrx3 H2O2H2O2 PrSSG Grx2 Metabolic substrates ASK1 O2-O2- Regulatory Signal MnSOD O2-O2- DP Jones, Chem-Biol Interact 2006 CoQ

22 Summary: Trx2 in Mitochondrial Compartment 1. Mitochondrial Trx2 has a more reduced redox state than cytoplasmic or nuclear Trx1 or cellular GSH 2. Mitochondrial Trx2 is more susceptible to oxidation than the cytoplasmic Trx1 3. Redox western blot analysis of mitochondrial Trx2 provides a useful approach to measure mitochondrial oxidative stress

23 GSH is difficult to measure in nuclei Cotgreave, 2003Bellomo, 1992Voehringer, 1998

24 Translocation of Trx from the cytoplasm to the nucleus Hirota et al, J Biol Chem (1999) 274:27891

25 Time courses of GSH and Trx1 oxidation are similar Trx-1 is somewhat more resistant Trx-1 recovers somewhat more rapidly Trx-Ox2 Trx-Ox1 Trx-Red Trx-Ox2 Trx-Ox1 Trx-Red 0 2 10 30 60 120 Time (min) Nuclei Cytoplasm High levels of oxidants are not selective between GSH and Trx1 Watson, Jones (2003) FEBS Lett 543:144 +1 mM H 2 O 2

26 Physiologic oxidation in response to EGF is specific to cytosolic Trx-1 -285 -275 -265 -255 0102030 Time (min) Nuclear Trx1 Eh (mV) Nuclear Trx1 -285 -275 -265 -255 0102030 Time (min) Cytoplasmic Trx1Eh (mV) Cytosolic Trx1 -285 -275 -265 -255 0102030 Time (min) GSH/GSSG Eh (mV) Cellular GSH P. Halvey et al, Biochem J 2005 -365 -355 -345 -335 0102030 Time (min) Trx2 Eh (mV) Mitochondrial Trx

27 Trx1 and PrSH/PrSSG are more reduced in nuclei Nuclei contain less protein-SH per mg protein than cytoplasm Nuclear Trx1 and PrSH/PrSSG are more resistant to oxidation than cytoplasmic pools

28 Keap-1 Nrf-2 Keap-1 Cytoplasm Nucleus Nrf-2 Maf ARE Nrf-2 Maf ARE Transcription Transcriptional activation by Nrf2

29 0 40 80 120 160 200 EmptyTRX1 +TBHQ 0 50 100 150 ControlBSONAC Nuclear Nrf-2 (% Control) 200 250 300 Keap-1 Nrf-2 Keap-1 Cytoplasm Nucleus Nrf-2 Maf ARE Nrf-2 Maf ARE Transcription ↑ GSH ↓ GSH J. Hansen et al, Tox Sci 2004 GSH controls cytoplasmic activation of Nrf2 translocation to nucleus

30 0 40 80 120 160 200 EmptyTRX1 +TBHQ 0 50 100 150 ControlBSONAC Nuclear Nrf-2 (% Control) 200 250 300 Keap-1 Nrf-2 Keap-1 Cytoplasm Nucleus Nrf-2 Trx1(SH) 2 Trx1(SS) Nrf-2 Maf ARE Nrf-2 Maf ARE Transcription ↑ GSH ↓ GSH 0 50 100 150 200 250 300 Empty Trx-1 C35S Trx-1 NLS-Trx-1 C35S NLS-Trx-1 % Control (Luc/B-gal) J. Hansen et al, Tox Sci 2004 GSH and Trx control different steps in transcriptional activation by Nrf2

31 Cytoplasmic activation of Nrf2 is dependent upon GSH/GSSG Nuclear activity of Nrf2 is dependent upon Trx1

32 Distinct roles for Trx in the cytoplasm and the nucleus IkB p50p65 p50p65 + IkB PO 4 cytosol nucleus p50p65 NF-kB-dependent gene (e.g. TNF) p50p65 Trx-(SH) 2 Ref1 <-- Trx-(SH) 2 Ubiquitination, Degradation endotoxin cytokines oxidants, etc.

33 GSH/GSSG = -220 to -260 Trx1(-SH) 2 /SS = -300 Cys/CySS = -160 Trx1(-SH) 2 /SS = -280 Cys/CySS = -80 GSH/GSSG = -140 Trx2(-SH) 2 /SS = -360 GSH/GSSG = -300 Plasma/Interstitial Cytoplasmic Nuclear Mitochondrial Endoplasmic Reticulum GSH/GSSG = -150 Hansen et al, Annu Rev Pharm Tox, 2006

34 Summary 1.Redox signaling and control involves discrete redox circuitry 2.The mitochondrial compartment is most reduced and most susceptible to oxidation 3.Nuclei are more reduced than cytoplasm and contain special mechanisms to protect against oxidative stress 4.Analytic methods are available to elucidate the redox circuitry and compartmentation of oxidative stress

Download ppt "Measuring the poise of thiol/disulfide redox in vivo Dean P. Jones, Ph.D. Department of Medicine/Division of Pulmonary, Allergy and Critical Care Medicine."

Similar presentations

Physiological roles Influence on many aspects of body function –Direct action –Indirect action Early growth and development Deficiency –Abnormalities Growth.

Physiological roles Influence on many aspects of body function –Direct action –Indirect action Early growth and development Deficiency –Abnormalities Growth.
NF  B 9/2002 SFRBM Education Program Emily Ho 1 NF  B – What is it and What’s the deal with radicals? Emily Ho, Ph.D Linus Pauling Institute Scientist.

NF  B 9/2002 SFRBM Education Program Emily Ho 1 NF  B – What is it and What’s the deal with radicals? Emily Ho, Ph.D Linus Pauling Institute Scientist.
Creatine Kinase Amy Ward. Overview  Metabolism  Creatine Kinase Isoforms  ATP Recycling  Clinical Relevance.

Creatine Kinase Amy Ward. Overview  Metabolism  Creatine Kinase Isoforms  ATP Recycling  Clinical Relevance.
Homework #2 is due 10/17 Bonus #1 is due 10/24 Office hours for this week: W 10-11:30am, 2:30-4:30pm and Th 11am-2pm.

Homework #2 is due 10/17 Bonus #1 is due 10/24 Office hours for this week: W 10-11:30am, 2:30-4:30pm and Th 11am-2pm.
The Effects of Increased Net Reactive Oxygen Species on Mitophagy DONALD TA.

The Effects of Increased Net Reactive Oxygen Species on Mitophagy DONALD TA.
Anahita Fallahi Brian Dixon Tory Hagen, Ph. D. Dept

Anahita Fallahi Brian Dixon Tory Hagen, Ph. D. Dept
DNA Chip Scanning DNA Chips are scanned with a laser to excite the fluorescein dye that is attached to the target cDNA. Only those probe spots where target.

DNA Chip Scanning DNA Chips are scanned with a laser to excite the fluorescein dye that is attached to the target cDNA. Only those probe spots where target.
Larry Marnett Cellular Responses to Aldehydic Products of Lipid Peroxidation.

Larry Marnett Cellular Responses to Aldehydic Products of Lipid Peroxidation.
Petra Bergstrom, Xu Zhang, Aja Harris and Ben Arentson

Petra Bergstrom, Xu Zhang, Aja Harris and Ben Arentson
Oxidative Stress Concepts Donald Becker Redox Biology Center University of Nebraska Graduate Course 2214/938 (KI/UNL) June 14, 2010.

Oxidative Stress Concepts Donald Becker Redox Biology Center University of Nebraska Graduate Course 2214/938 (KI/UNL) June 14, 2010.
Biologically Relevant Thiol Modifications Effects on Protein Function

Biologically Relevant Thiol Modifications Effects on Protein Function
Danish Aging Research Center

Danish Aging Research Center
Redox State Society For Free Radical Biology and MedicineSchafer & Buettner 1 Redox State and Redox Environment Freya Q. Schafer and Garry R. Buettner.

Redox State Society For Free Radical Biology and MedicineSchafer & Buettner 1 Redox State and Redox Environment Freya Q. Schafer and Garry R. Buettner.
HJ Forman: SFRBM 2007 Sunrise Free Radical School Antioxidants Henry Jay Forman, Ph.D. University of California at Merced Sunrise Free Radical School,

HJ Forman: SFRBM 2007 Sunrise Free Radical School Antioxidants Henry Jay Forman, Ph.D. University of California at Merced Sunrise Free Radical School,
Luděk Bláha, PřF MU, RECETOX www.recetox.cz BIOMARKERS AND TOXICITY MECHANISMS 13 – BIOMARKERS Summary and final notes.

Luděk Bláha, PřF MU, RECETOX BIOMARKERS AND TOXICITY MECHANISMS 13 – BIOMARKERS Summary and final notes.
1 Future Areas of Research Intervention Approaches Causes and Mechanisms of Overweight and Obesity Abdominal Fat, Body Weight and Disease Risk Assessment.

1 Future Areas of Research Intervention Approaches Causes and Mechanisms of Overweight and Obesity Abdominal Fat, Body Weight and Disease Risk Assessment.
The Virtual Free Radical School Cell Signaling by Oxidants: Mitogen-Activated Protein Kinases (MAPK) and Activator Protein – 1 (AP-1) Brooke T. Mossman*

The Virtual Free Radical School Cell Signaling by Oxidants: Mitogen-Activated Protein Kinases (MAPK) and Activator Protein – 1 (AP-1) Brooke T. Mossman*
PhGPx, a beginning story

PhGPx, a beginning story
Tumor genetics Minna Thullberg

Tumor genetics Minna Thullberg
Oxidative Stress and Diabetes Jian Li Beijing Institute of Geriatrics Ministry of Health.

Oxidative Stress and Diabetes Jian Li Beijing Institute of Geriatrics Ministry of Health.

Similar presentations

Ads by Google