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Wikipedia

Glutathione

January 30, 2023

Glutathione (GSH, /ˌɡltəˈθn/) is an antioxidant in plants, animals, fungi, and some bacteria and archaea. Glutathione is capable of preventing damage to important cellular components caused by sources such as reactive oxygen species, free radicals, peroxides, lipid peroxides, and heavy metals.[2] It is a tripeptide with a gamma peptide linkage between the carboxyl group of the glutamate side chain and cysteine. The carboxyl group of the cysteine residue is attached by normal peptide linkage to glycine.

Glutathione[1]
Names
Preferred IUPAC name
(2S)-2-Amino-5-({(2R)-1-[(carboxymethyl)amino]-1-oxo-3-sulfanylpropan-2-yl}amino)-5-oxopentanoic acid
Other names
γ-L-Glutamyl-L-cysteinylglycine
(2S)-2-Amino-4-({(1R)-1-[(carboxymethyl)carbamoyl]-2-sulfanylethyl}carbamoyl)butanoic acid
Identifiers
  • 70-18-8 Y
3D model (JSmol)
  • Interactive image
Abbreviations GSH
ChEBI
  • CHEBI:16856 Y
ChEMBL
  • ChEMBL1543 Y
ChemSpider
  • 111188 Y
DrugBank
  • DB00143 Y
ECHA InfoCard 100.000.660
  • 6737
KEGG
  • C00051 Y
MeSH Glutathione
  • 124886
UNII
  • GAN16C9B8O Y
  • DTXSID6023101
  • InChI=1S/C10H17N3O6S/c11-5(10(18)19)1-2-7(14)13-6(4-20)9(17)12-3-8(15)16/h5-6,20H,1-4,11H2,(H,12,17)(H,13,14)(H,15,16)(H,18,19)/t5-,6-/m0/s1 Y
    Key: RWSXRVCMGQZWBV-WDSKDSINSA-N Y
  • C(CC(=O)N[C@@H](CS)C(=O)NCC(=O)O)[C@@H](C(=O)O)N
Properties
C10H17N3O6S
Molar mass 307.32 g·mol−1
Melting point 195 °C (383 °F; 468 K)[1]
Freely soluble[1]
Solubility in methanol, diethyl ether Insoluble[1]
Pharmacology
V03AB32 (WHO)
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

Biosynthesis and occurrence

Glutathione biosynthesis involves two adenosine triphosphate-dependent steps:

While all animal cells are capable of synthesizing glutathione, glutathione synthesis in the liver has been shown to be essential. GCLC knockout mice die within a month of birth due to the absence of hepatic GSH synthesis.[4][5]

The unusual gamma amide linkage in glutathione protects it from hydrolysis by peptidases.[6]

Occurrence

Glutathione is the most abundant thiol in animal cells, ranging from 0.5 to 10 mmol/L. It is present in the cytosol and the organelles.[6]

Human beings synthesize glutathione, but a few eukaryotes do not, including some members of Fabaceae, Entamoeba, and Giardia. The only known archaea that make glutathione are halobacteria. Some bacteria, such as "Cyanobacteria" and Pseudomonadota, can biosynthesize glutathione.[7][8]

Biochemical function

Glutathione exists in reduced (GSH) and oxidized (GSSG) states. The ratio of reduced glutathione to oxidized glutathione within cells is a measure of cellular oxidative stress[9][10] where increased GSSG-to-GSH ratio is indicative of greater oxidative stress. In healthy cells and tissue, more than 90% of the total glutathione pool is in the reduced form (GSH), with the remainder in the disulfide form (GSSG).[11]

In the reduced state, the thiol group of cysteinyl residue is a source of one reducing equivalent. Glutathione disulfide (GSSG) is thereby generated. The oxidized state is converted to the reduced state by NADPH.[12] This conversion is catalyzed by glutathione reductase:

NADPH + GSSG + H2O → 2 GSH + NADP+ + OH

Roles

Antioxidant

GSH protects cells by neutralising (reducing) reactive oxygen species.[13][6] This conversion is illustrated by the reduction of peroxides:

2 GSH + R2O2 → GSSG + 2 ROH  (R = H, alkyl)

and with free radicals:

GSH + R12 GSSG + RH

Regulation

Aside from deactivating radicals and reactive oxidants, glutathione participates in thiol protection and redox regulation of cellular thiol proteins under oxidative stress by protein S-glutathionylation, a redox-regulated post-translational thiol modification. The general reaction involves formation of an unsymmetrical disulfide from the protectable protein (RSH) and GSH:[14]

RSH + GSH + [O] → GSSR + H2O

Glutathione is also employed for the detoxification of methylglyoxal and formaldehyde, toxic metabolites produced under oxidative stress. This detoxification reaction is carried out by the glyoxalase system. Glyoxalase I (EC 4.4.1.5) catalyzes the conversion of methylglyoxal and reduced glutathione to S-D-lactoylglutathione. Glyoxalase II (EC 3.1.2.6) catalyzes the hydrolysis of S-D-lactoylglutathione to glutathione and D-lactic acid.

It maintains exogenous antioxidants such as vitamins C and E in their reduced (active) states.[15][16][17]

Metabolism

Among the many metabolic processes in which it participates, glutathione is required for the biosynthesis of leukotrienes and prostaglandins. It plays a role in the storage of cysteine. Glutathione enhances the function of citrulline as part of the nitric oxide cycle.[18] It is a cofactor and acts on glutathione peroxidase.[19]

Conjugation

Glutathione facilitates metabolism of xenobiotics. Glutathione S-transferase enzymes catalyze its conjugation to lipophilic xenobiotics, facilitating their excretion or further metabolism.[20] The conjugation process is illustrated by the metabolism of N-acetyl-p-benzoquinone imine (NAPQI). NAPQI is a reactive metabolite formed by the action of cytochrome P450 on paracetamol (acetaminophen). Glutathione conjugates to NAPQI, and the resulting ensemble is excreted.

Potential neurotransmitters

Glutathione, along with oxidized glutathione (GSSG) and S-nitrosoglutathione (GSNO), bind to the glutamate recognition site of the NMDA and AMPA receptors (via their γ-glutamyl moieties). GSH and GSSG may be neuromodulators.[21][22][23] At millimolar concentrations, GSH and GSSG may also modulate the redox state of the NMDA receptor complex.[22] Glutathione binds and activates ionotropic receptors, potentially making it a neurotransmitter.[24]

GSH activates the purinergic P2X7 receptor from Müller glia, inducing acute calcium transient signals and GABA release from both retinal neurons and glial cells.[25][26]

In plants

In plants, glutathione is involved in stress management. It is a component of the glutathione-ascorbate cycle, a system that reduces poisonous hydrogen peroxide.[27] It is the precursor of phytochelatins, glutathione oligomers that chelate heavy metals such as cadmium.[28] Glutathione is required for efficient defence against plant pathogens such as Pseudomonas syringae and Phytophthora brassicae.[29] Adenylyl-sulfate reductase, an enzyme of the sulfur assimilation pathway, uses glutathione as an electron donor. Other enzymes using glutathione as a substrate are glutaredoxins. These small oxidoreductases are involved in flower development, salicylic acid, and plant defence signalling.[30]

Bioavailability

Systemic availability of orally consumed glutathione is poor because the tripeptide is the substrate of proteases (peptidases) of the alimentary canal, and due to the absence of a specific carrier of glutathione at the level of cell membrane.[31][32]

Determination of glutathione

Ellman's reagent and monobromobimane

Reduced glutathione may be visualized using Ellman's reagent or bimane derivatives such as monobromobimane. The monobromobimane method is more sensitive. In this procedure, cells are lysed and thiols extracted using a HCl buffer. The thiols are then reduced with dithiothreitol and labelled by monobromobimane. Monobromobimane becomes fluorescent after binding to GSH. The thiols are then separated by HPLC and the fluorescence quantified with a fluorescence detector.

Monochlorobimane

Using monochlorobimane, the quantification is done by confocal laser scanning microscopy after application of the dye to living cells.[33] This quantification process relies on measuring the rates of fluorescence changes and is limited to plant cells.

CMFDA has also been mistakenly used as a glutathione probe. Unlike monochlorobimane, whose fluorescence increases upon reacting with glutathione, the fluorescence increase of CMFDA is due to the hydrolysis of the acetate groups inside cells. Although CMFDA may react with glutathione in cells, the fluorescence increase does not reflect the reaction. Therefore, studies using CMFDA as a glutathione probe should be revisited and reinterpreted.[34][35]

ThiolQuant Green

The major limitation of these bimane-based probes and many other reported probes is that these probes are based on irreversible chemical reactions with glutathione, which renders these probes incapable of monitoring the real-time glutathione dynamics. Recently, the first reversible reaction based fluorescent probe-ThiolQuant Green (TQG)-for glutathione was reported.[36] ThiolQuant Green can not only perform high resolution measurements of glutathione levels in single cells using a confocal microscope, but also be applied in flow cytometry to perform bulk measurements.

RealThiol

The RealThiol (RT) probe is a second-generation reversible reaction-based GSH probe. A few key features of RealThiol:

  • it has a much faster forward and backward reaction kinetics compared to ThiolQuant Green, which enables real-time monitoring of GSH dynamics in live cells;
  • only micromolar to sub-micromolar RealThiol is needed for staining in cell-based experiments, which induces minimal perturbation to GSH level in cells;
  • a high-quantum-yield coumarin fluorophore was implemented so that background noise can be minimized; and
  • the equilibrium constant of the reaction between RealThiol and GSH has been fine-tuned to respond to physiologically relevant concentration of GSH.[37]

RealThiol can be used to perform measurements of glutathione levels in single cells using a high-resolution confocal microscope, as well as be applied in flow cytometry to perform bulk measurements in high throughput manner.

An organelle-targeted RT probe has also been developed. A mitochondria-targeted version, MitoRT, was reported and demonstrated in monitoring the dynamic of mitochondrial glutathione both on confocoal microscope and FACS based analysis.[38]

Protein-based glutathione probes

Another approach, which allows measurement of the glutathione redox potential at a high spatial and temporal resolution in living cells, is based on redox imaging using the redox-sensitive green fluorescent protein (roGFP)[39] or redox-sensitive yellow fluorescent protein (rxYFP).[40] Because of its very low physiological concentration, GSSG is difficult to measure accurately. GSSG concentration ranges from 10 to 50 μM in all solid tissues, and from 2 to 5 μM in blood (13–33 nmol/g Hb). GSH-to-GSSG ratio of whole cell extracts is estimated from 100 to 700.[41] Those ratios represent a mixture from the glutathione pools of different redox states from different subcellular compartments (e.g. more oxidized in the ER, more reduced in the mitochondrial matrix), however. In vivo GSH-to-GSSG ratios can be measured with subcellular accuracy using fluorescent protein-based redox sensors, which have revealed ratios from 50,000 to 500,000 in the cytosol, which implies that GSSG concentration is maintained in the pM range.[42]

Uses

Winemaking

The content of glutathione in must, the first raw form of wine, determines the browning, or caramelizing effect, during the production of white wine by trapping the caffeoyltartaric acid quinones generated by enzymic oxidation as grape reaction product.[43] Its concentration in wine can be determined by UPLC-MRM mass spectrometry.[44]

See also

References

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External links

  • Glutathione bound to proteins in the PDB
  • Risk Factors


January 30, 2023
glutathione, antioxidant, plants, animals, fungi, some, bacteria, archaea, capable, preventing, damage, important, cellular, components, caused, sources, such, reactive, oxygen, species, free, radicals, peroxides, lipid, peroxides, heavy, metals, tripeptide, w. Glutathione GSH ˌ ɡ l uː t e ˈ 8 aɪ oʊ n is an antioxidant in plants animals fungi and some bacteria and archaea Glutathione is capable of preventing damage to important cellular components caused by sources such as reactive oxygen species free radicals peroxides lipid peroxides and heavy metals 2 It is a tripeptide with a gamma peptide linkage between the carboxyl group of the glutamate side chain and cysteine The carboxyl group of the cysteine residue is attached by normal peptide linkage to glycine Glutathione 1 NamesPreferred IUPAC name 2S 2 Amino 5 2R 1 carboxymethyl amino 1 oxo 3 sulfanylpropan 2 yl amino 5 oxopentanoic acidOther names g L Glutamyl L cysteinylglycine 2S 2 Amino 4 1R 1 carboxymethyl carbamoyl 2 sulfanylethyl carbamoyl butanoic acidIdentifiersCAS Number 70 18 8 Y3D model JSmol Interactive imageAbbreviations GSHChEBI CHEBI 16856 YChEMBL ChEMBL1543 YChemSpider 111188 YDrugBank DB00143 YECHA InfoCard 100 000 660IUPHAR BPS 6737KEGG C00051 YMeSH GlutathionePubChem CID 124886UNII GAN16C9B8O YCompTox Dashboard EPA DTXSID6023101InChI InChI 1S C10H17N3O6S c11 5 10 18 19 1 2 7 14 13 6 4 20 9 17 12 3 8 15 16 h5 6 20H 1 4 11H2 H 12 17 H 13 14 H 15 16 H 18 19 t5 6 m0 s1 YKey RWSXRVCMGQZWBV WDSKDSINSA N YSMILES C CC O N C H CS C O NCC O O C H C O O NPropertiesChemical formula C 10H 17N 3O 6SMolar mass 307 32 g mol 1Melting point 195 C 383 F 468 K 1 Solubility in water Freely soluble 1 Solubility in methanol diethyl ether Insoluble 1 PharmacologyATC code V03AB32 WHO Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references Contents 1 Biosynthesis and occurrence 1 1 Occurrence 2 Biochemical function 3 Roles 3 1 Antioxidant 3 2 Regulation 3 3 Metabolism 3 4 Conjugation 3 5 Potential neurotransmitters 3 6 In plants 4 Bioavailability 5 Determination of glutathione 5 1 Ellman s reagent and monobromobimane 5 2 Monochlorobimane 5 3 ThiolQuant Green 5 4 RealThiol 5 5 Protein based glutathione probes 6 Uses 6 1 Winemaking 7 See also 8 References 9 External linksBiosynthesis and occurrence EditGlutathione biosynthesis involves two adenosine triphosphate dependent steps First g glutamylcysteine is synthesized from L glutamate and cysteine This conversion requires the enzyme glutamate cysteine ligase GCL glutamate cysteine synthase This reaction is the rate limiting step in glutathione synthesis 3 Second glycine is added to the C terminal of g glutamylcysteine This condensation is catalyzed by glutathione synthetase While all animal cells are capable of synthesizing glutathione glutathione synthesis in the liver has been shown to be essential GCLC knockout mice die within a month of birth due to the absence of hepatic GSH synthesis 4 5 The unusual gamma amide linkage in glutathione protects it from hydrolysis by peptidases 6 Occurrence Edit Glutathione is the most abundant thiol in animal cells ranging from 0 5 to 10 mmol L It is present in the cytosol and the organelles 6 Human beings synthesize glutathione but a few eukaryotes do not including some members of Fabaceae Entamoeba and Giardia The only known archaea that make glutathione are halobacteria Some bacteria such as Cyanobacteria and Pseudomonadota can biosynthesize glutathione 7 8 Biochemical function EditGlutathione exists in reduced GSH and oxidized GSSG states The ratio of reduced glutathione to oxidized glutathione within cells is a measure of cellular oxidative stress 9 10 where increased GSSG to GSH ratio is indicative of greater oxidative stress In healthy cells and tissue more than 90 of the total glutathione pool is in the reduced form GSH with the remainder in the disulfide form GSSG 11 In the reduced state the thiol group of cysteinyl residue is a source of one reducing equivalent Glutathione disulfide GSSG is thereby generated The oxidized state is converted to the reduced state by NADPH 12 This conversion is catalyzed by glutathione reductase NADPH GSSG H2O 2 GSH NADP OH Roles EditAntioxidant Edit GSH protects cells by neutralising reducing reactive oxygen species 13 6 This conversion is illustrated by the reduction of peroxides 2 GSH R2O2 GSSG 2 ROH R H alkyl and with free radicals GSH R 1 2 GSSG RHRegulation Edit Aside from deactivating radicals and reactive oxidants glutathione participates in thiol protection and redox regulation of cellular thiol proteins under oxidative stress by protein S glutathionylation a redox regulated post translational thiol modification The general reaction involves formation of an unsymmetrical disulfide from the protectable protein RSH and GSH 14 RSH GSH O GSSR H2OGlutathione is also employed for the detoxification of methylglyoxal and formaldehyde toxic metabolites produced under oxidative stress This detoxification reaction is carried out by the glyoxalase system Glyoxalase I EC 4 4 1 5 catalyzes the conversion of methylglyoxal and reduced glutathione to S D lactoylglutathione Glyoxalase II EC 3 1 2 6 catalyzes the hydrolysis of S D lactoylglutathione to glutathione and D lactic acid It maintains exogenous antioxidants such as vitamins C and E in their reduced active states 15 16 17 Metabolism Edit Among the many metabolic processes in which it participates glutathione is required for the biosynthesis of leukotrienes and prostaglandins It plays a role in the storage of cysteine Glutathione enhances the function of citrulline as part of the nitric oxide cycle 18 It is a cofactor and acts on glutathione peroxidase 19 Conjugation Edit Glutathione facilitates metabolism of xenobiotics Glutathione S transferase enzymes catalyze its conjugation to lipophilic xenobiotics facilitating their excretion or further metabolism 20 The conjugation process is illustrated by the metabolism of N acetyl p benzoquinone imine NAPQI NAPQI is a reactive metabolite formed by the action of cytochrome P450 on paracetamol acetaminophen Glutathione conjugates to NAPQI and the resulting ensemble is excreted Potential neurotransmitters Edit Glutathione along with oxidized glutathione GSSG and S nitrosoglutathione GSNO bind to the glutamate recognition site of the NMDA and AMPA receptors via their g glutamyl moieties GSH and GSSG may be neuromodulators 21 22 23 At millimolar concentrations GSH and GSSG may also modulate the redox state of the NMDA receptor complex 22 Glutathione binds and activates ionotropic receptors potentially making it a neurotransmitter 24 GSH activates the purinergic P2X7 receptor from Muller glia inducing acute calcium transient signals and GABA release from both retinal neurons and glial cells 25 26 In plants Edit In plants glutathione is involved in stress management It is a component of the glutathione ascorbate cycle a system that reduces poisonous hydrogen peroxide 27 It is the precursor of phytochelatins glutathione oligomers that chelate heavy metals such as cadmium 28 Glutathione is required for efficient defence against plant pathogens such as Pseudomonas syringae and Phytophthora brassicae 29 Adenylyl sulfate reductase an enzyme of the sulfur assimilation pathway uses glutathione as an electron donor Other enzymes using glutathione as a substrate are glutaredoxins These small oxidoreductases are involved in flower development salicylic acid and plant defence signalling 30 Bioavailability EditSystemic availability of orally consumed glutathione is poor because the tripeptide is the substrate of proteases peptidases of the alimentary canal and due to the absence of a specific carrier of glutathione at the level of cell membrane 31 32 Determination of glutathione EditEllman s reagent and monobromobimane Edit Reduced glutathione may be visualized using Ellman s reagent or bimane derivatives such as monobromobimane The monobromobimane method is more sensitive In this procedure cells are lysed and thiols extracted using a HCl buffer The thiols are then reduced with dithiothreitol and labelled by monobromobimane Monobromobimane becomes fluorescent after binding to GSH The thiols are then separated by HPLC and the fluorescence quantified with a fluorescence detector Monochlorobimane Edit Using monochlorobimane the quantification is done by confocal laser scanning microscopy after application of the dye to living cells 33 This quantification process relies on measuring the rates of fluorescence changes and is limited to plant cells CMFDA has also been mistakenly used as a glutathione probe Unlike monochlorobimane whose fluorescence increases upon reacting with glutathione the fluorescence increase of CMFDA is due to the hydrolysis of the acetate groups inside cells Although CMFDA may react with glutathione in cells the fluorescence increase does not reflect the reaction Therefore studies using CMFDA as a glutathione probe should be revisited and reinterpreted 34 35 ThiolQuant Green Edit The major limitation of these bimane based probes and many other reported probes is that these probes are based on irreversible chemical reactions with glutathione which renders these probes incapable of monitoring the real time glutathione dynamics Recently the first reversible reaction based fluorescent probe ThiolQuant Green TQG for glutathione was reported 36 ThiolQuant Green can not only perform high resolution measurements of glutathione levels in single cells using a confocal microscope but also be applied in flow cytometry to perform bulk measurements RealThiol Edit The RealThiol RT probe is a second generation reversible reaction based GSH probe A few key features of RealThiol it has a much faster forward and backward reaction kinetics compared to ThiolQuant Green which enables real time monitoring of GSH dynamics in live cells only micromolar to sub micromolar RealThiol is needed for staining in cell based experiments which induces minimal perturbation to GSH level in cells a high quantum yield coumarin fluorophore was implemented so that background noise can be minimized and the equilibrium constant of the reaction between RealThiol and GSH has been fine tuned to respond to physiologically relevant concentration of GSH 37 RealThiol can be used to perform measurements of glutathione levels in single cells using a high resolution confocal microscope as well as be applied in flow cytometry to perform bulk measurements in high throughput manner An organelle targeted RT probe has also been developed A mitochondria targeted version MitoRT was reported and demonstrated in monitoring the dynamic of mitochondrial glutathione both on confocoal microscope and FACS based analysis 38 Protein based glutathione probes Edit Another approach which allows measurement of the glutathione redox potential at a high spatial and temporal resolution in living cells is based on redox imaging using the redox sensitive green fluorescent protein roGFP 39 or redox sensitive yellow fluorescent protein rxYFP 40 Because of its very low physiological concentration GSSG is difficult to measure accurately GSSG concentration ranges from 10 to 50 mM in all solid tissues and from 2 to 5 mM in blood 13 33 nmol g Hb GSH to GSSG ratio of whole cell extracts is estimated from 100 to 700 41 Those ratios represent a mixture from the glutathione pools of different redox states from different subcellular compartments e g more oxidized in the ER more reduced in the mitochondrial matrix however In vivo GSH to GSSG ratios can be measured with subcellular accuracy using fluorescent protein based redox sensors which have revealed ratios from 50 000 to 500 000 in the cytosol which implies that GSSG concentration is maintained in the pM range 42 Uses EditWinemaking Edit The content of glutathione in must the first raw form of wine determines the browning or caramelizing effect during the production of white wine by trapping the caffeoyltartaric acid quinones generated by enzymic oxidation as grape reaction product 43 Its concentration in wine can be determined by UPLC MRM mass spectrometry 44 See also EditReductive stress Glutathione synthetase deficiency Ophthalmic acid roGFP a tool to measure the cellular glutathione redox potential Glutathione ascorbate cycle Bacterial glutathione transferase Thioredoxin a cysteine containing small proteins with very similar functions as reducing agents Glutaredoxin an antioxidant protein that uses reduced glutathione as a cofactor and is reduced nonenzymatically by it Bacillithiol Mycothiol g L Glutamyl L cysteineReferences Edit a b c d Haynes William M ed 2016 CRC Handbook of Chemistry and Physics 97th ed CRC Press p 3 284 ISBN 9781498754293 Pompella A Visvikis A Paolicchi A De Tata V Casini AF October 2003 The changing faces of glutathione a cellular protagonist Biochemical Pharmacology 66 8 1499 1503 doi 10 1016 S0006 2952 03 00504 5 PMID 14555227 White CC Viernes H Krejsa CM Botta D Kavanagh TJ July 2003 Fluorescence based microtiter plate assay for glutamate cysteine ligase activity Analytical Biochemistry 318 2 175 180 doi 10 1016 S0003 2697 03 00143 X PMID 12814619 Chen Y Yang Y Miller ML Shen D Shertzer HG Stringer KF Wang B Schneider SN Nebert DW Dalton TP May 2007 Hepatocyte specific Gclc deletion leads to rapid onset of steatosis with mitochondrial injury and liver failure Hepatology 45 5 1118 1128 doi 10 1002 hep 21635 PMID 17464988 S2CID 25000753 Sies H 1999 Glutathione and its role in cellular functions Free Radical Biology amp Medicine 27 9 10 916 921 doi 10 1016 S0891 5849 99 00177 X PMID 10569624 a b c Guoyao Wu Yun Zhong Fang Sheng Yang Joanne R Lupton Nancy D Turner 2004 Glutathione Metabolism and its Implications for Health Journal of Nutrition 134 3 489 492 doi 10 1093 jn 134 3 489 PMID 14988435 Copley SD Dhillon JK 29 April 2002 Lateral gene transfer and parallel evolution in the history of glutathione biosynthesis genes Genome Biology 3 5 research0025 doi 10 1186 gb 2002 3 5 research0025 PMC 115227 PMID 12049666 Wonisch W Schaur RJ 2001 Chapter 2 Chemistry of Glutathione In Grill D Tausz T De Kok L eds Significance of glutathione in plant adaptation to the environment Springer ISBN 978 1 4020 0178 9 via Google Books Pastore A Piemonte F Locatelli M Lo Russo A Gaeta LM Tozzi G Federici G August 2001 Determination of blood total reduced and oxidized glutathione in pediatric subjects Clinical Chemistry 47 8 1467 1469 doi 10 1093 clinchem 47 8 1467 PMID 11468240 Lu SC May 2013 Glutathione synthesis Biochimica et Biophysica Acta BBA General Subjects 1830 5 3143 3153 doi 10 1016 j bbagen 2012 09 008 PMC 3549305 PMID 22995213 Halprin KM Ohkawara A 1967 The measurement of glutathione in human epidermis using glutathione reductase The Journal of Investigative Dermatology 48 2 149 152 doi 10 1038 jid 1967 24 PMID 6020678 Couto N Malys N Gaskell SJ Barber J June 2013 Partition and turnover of glutathione reductase from Saccharomyces cerevisiae a proteomic approach Journal of Proteome Research 12 6 2885 2894 doi 10 1021 pr4001948 PMID 23631642 Michael Brownlee 2005 The pathobiology of diabetic complications A unifying mechanism Diabetes 54 6 1615 1625 doi 10 2337 diabetes 54 6 1615 PMID 15919781 Dalle Donne Isabella Rossi Ranieri Colombo Graziano Giustarini Daniela Milzani Aldo 2009 Protein S glutathionylation a regulatory device from bacteria to humans Trends in Biochemical Sciences 34 2 85 96 doi 10 1016 j tibs 2008 11 002 PMID 19135374 Dringen R December 2000 Metabolism and functions of glutathione in brain Progress in Neurobiology 62 6 649 671 doi 10 1016 s0301 0082 99 00060 x PMID 10880854 S2CID 452394 Scholz RW Graham KS Gumpricht E Reddy CC 1989 Mechanism of interaction of vitamin E and glutathione in the protection against membrane lipid peroxidation Annals of the New York Academy of Sciences 570 1 514 517 Bibcode 1989NYASA 570 514S doi 10 1111 j 1749 6632 1989 tb14973 x S2CID 85414084 Hughes RE 1964 Reduction of dehydroascorbic acid by animal tissues Nature 203 4949 1068 1069 Bibcode 1964Natur 203 1068H doi 10 1038 2031068a0 PMID 14223080 S2CID 4273230 Ha SB Smith AP Howden R Dietrich WM Bugg S O Connell MJ Goldsbrough PB Cobbett CS June 1999 Phytochelatin synthase genes from Arabidopsis and the yeast Schizosaccharomyces pombe The Plant Cell 11 6 1153 1164 doi 10 1105 tpc 11 6 1153 JSTOR 3870806 PMC 144235 PMID 10368185 Grant CM 2001 Role of the glutathione glutaredoxin and thioredoxin systems in yeast growth and response to stress conditions Molecular Microbiology 39 3 533 541 doi 10 1046 j 1365 2958 2001 02283 x PMID 11169096 S2CID 6467802 Hayes John D Flanagan Jack U Jowsey Ian R 2005 Glutathione transferases Annual Review of Pharmacology and Toxicology 45 51 88 doi 10 1146 annurev pharmtox 45 120403 095857 PMID 15822171 Steullet P Neijt HC Cuenod M Do KQ February 2006 Synaptic plasticity impairment and hypofunction of NMDA receptors induced by glutathione deficit relevance to schizophrenia Neuroscience 137 3 807 819 doi 10 1016 j neuroscience 2005 10 014 PMID 16330153 S2CID 1417873 a b Varga V Jenei Z Janaky R Saransaari P Oja SS September 1997 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PMC 4831842 PMID 27078878 Freitas HR Reis RA 1 January 2017 Glutathione induces GABA release through P2X7R activation on Muller glia Neurogenesis 4 1 e1283188 doi 10 1080 23262133 2017 1283188 PMC 5305167 PMID 28229088 Noctor G Foyer CH June 1998 Ascorbate and Glutathione Keeping Active Oxygen Under Control Annual Review of Plant Physiology and Plant Molecular Biology 49 1 249 279 doi 10 1146 annurev arplant 49 1 249 PMID 15012235 Ha SB Smith AP Howden R Dietrich WM Bugg S O Connell MJ Goldsbrough PB Cobbett CS June 1999 Phytochelatin synthase genes from Arabidopsis and the yeast Schizosaccharomyces pombe The Plant Cell 11 6 1153 1164 doi 10 1105 tpc 11 6 1153 PMC 144235 PMID 10368185 Parisy V Poinssot B Owsianowski L Buchala A Glazebrook J Mauch F January 2007 Identification of PAD2 as a gamma glutamylcysteine synthetase highlights the importance of glutathione in disease resistance of Arabidopsis PDF The Plant Journal 49 1 159 172 doi 10 1111 j 1365 313X 2006 02938 x PMID 17144898 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24681280 Lantz RC Lemus R Lange RW Karol MH April 2001 Rapid reduction of intracellular glutathione in human bronchial epithelial cells exposed to occupational levels of toluene diisocyanate Toxicological Sciences 60 2 348 355 doi 10 1093 toxsci 60 2 348 PMID 11248147 Jiang X Yu Y Chen J Zhao M Chen H Song X Matzuk AJ Carroll SL Tan X Sizovs A Cheng N Wang MC Wang J March 2015 Quantitative imaging of glutathione in live cells using a reversible reaction based ratiometric fluorescent probe ACS Chemical Biology 10 3 864 874 doi 10 1021 cb500986w PMC 4371605 PMID 25531746 Jiang X Chen J Bajic A Zhang C Song X Carroll SL Cai ZL Tang M Xue M Cheng N Schaaf CP Li F MacKenzie KR Ferreon AC Xia F Wang MC Maletic Savatic M Wang J July 2017 Quantitative imaging of glutathione Nature Communications 8 16087 doi 10 1038 ncomms16087 PMC 5511354 PMID 28703127 Chen J Jiang X Zhang C MacKenzie KR Stossi F Palzkill T Wang MC Wang J 2017 Reversible Reaction Based Fluorescent Probe for Real Time Imaging of Glutathione Dynamics in Mitochondria ACS Sensors 2 9 1257 1261 doi 10 1021 acssensors 7b00425 PMC 5771714 PMID 28809477 Meyer AJ Brach T Marty L Kreye S Rouhier N Jacquot JP Hell R December 2007 Redox sensitive GFP in Arabidopsis thaliana is a quantitative biosensor for the redox potential of the cellular glutathione redox buffer The Plant Journal 52 5 973 986 doi 10 1111 j 1365 313X 2007 03280 x PMID 17892447 Maulucci G Labate V Mele M Panieri E Arcovito G Galeotti T Ostergaard H Winther JR De Spirito M Pani G October 2008 High resolution imaging of redox signaling in live cells through an oxidation sensitive yellow fluorescent protein Science Signaling 1 43 pl3 doi 10 1126 scisignal 143pl3 PMID 18957692 S2CID 206670068 Giustarini D Dalle Donne I Milzani A Fanti P Rossi R September 2013 Analysis of GSH and GSSG after derivatization with N ethylmaleimide Nature Protocols 8 9 1660 1669 doi 10 1038 nprot 2013 095 PMID 23928499 S2CID 22645510 Schwarzlander M Dick T Meyer AJ Morgan B April 2016 Dissecting Redox Biology Using Fluorescent Protein Sensors Antioxidants amp Redox Signaling 24 13 680 712 doi 10 1089 ars 2015 6266 PMID 25867539 Rigaud J Cheynier V Souquet JM Moutounet M 1991 Influence of must composition on phenolic oxidation kinetics Journal of the Science of Food and Agriculture 57 1 55 63 doi 10 1002 jsfa 2740570107 Vallverdu Queralt A Verbaere A Meudec E Cheynier V Sommerer N January 2015 Straightforward method to quantify GSH GSSG GRP and hydroxycinnamic acids in wines by UPLC MRM MS Journal of Agricultural and Food Chemistry 63 1 142 149 doi 10 1021 jf504383g PMID 25457918 External links EditGlutathione bound to proteins in the PDB Risk Factors Retrieved from https en wikipedia org w index php title Glutathione amp oldid 1135360258, wikipedia, wiki, book, books, library,

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