Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C1260386 (
GSH
)
38,102
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Protein-thiol mixed disulfide formation has been implicated as a possible mechanism for the protein-protein aggregation in cataractogenesis. Previously we have found that two species of thiols are bound to proteins:
GSH
(PSSG) and cysteine (
PSSC
). In this study we found these molecules are ubiquitous in animal lenses with the highest levels in human, dog and rat, and lowest in monkey. However, the relative amount of PSSG to
PSSC
is quite different in each animal species. The ratio of PSSG/
PSSC
was 1/10 in rat lens, 4/1 in human and dog lenses and 2/1 in monkey lens. We also studied the effect of aging on the protein-thiol mixed disulfide levels in human donor lenses between 3 months and 88 years. Lens
GSH
levels were inversely related to age, similar to earlier reports, but
PSSC
levels increased linearly with age. PSSG levels showed a triphasic pattern with an initial sharp and linear increase from a low content in infants to a highest level at age 20; fell back about 50% to a new steady state level that was maintained for four more decades; finally, above 60 years, the levels in some lenses were two to three-fold higher while some lenses remained at the same low value.
PSSC
in human lens appeared to concentrate in the nuclear region and in the water insoluble proteins while PSSG was more evenly distributed. Besides the aging effect on the protein-thiol mixed disulfides, oxidative stress also potentiated protein modification in the human lens.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Protein-thiol mixed disulfides in human lens. 148 43
Oxidative stress has long been speculated to play an important role in cataractogenesis. In the H2O2-induced cataract model, rat lens showed extensive biochemical damage but very mild morphological changes after being exposed to H2O2 (0.5 mM) for 24 hr in culture. This damage included reduced glutathione (
GSH
) depletion, protein-
GSH
mixed disulfide (PSSG) elevation but not protein-protein disulfide (PSSP) formation. In order to understand the role of protein-thiol mixed disulfide formation in relation to the sequence of events during cataract induction, we conducted a long term H2O2 exposure study for up to 96 hr to monitor the dynamic changes in
GSH
and PSSG levels, the formation of PSSP aggregate, protein solubility, and the progression in lens opacity. Rat lenses were cultured in 0.5 mM H2O2 and harvested at intervals of 24, 48, 72 and 96 hr for the examination of morphological and biochemical changes. Contralateral lenses cultured in H2O2-free media were used as controls. It was found that the lenses had only patchy opacity at the equator after 24 hr, but became hydrated suddenly at 48 hr (31% heavier than the control), with an opacity which involved the entire outer cortical region. By 72 hr incubation, the nucleus was opacified. Lens
GSH
progressively decreased with time of H2O2 exposure, 40% was lost by 24 hr and over 95% by 48 hr. There was a concomitant elevation of PSSG, 16-fold over the controls by 24 hr and 45-fold by 48 hr followed by a decline to 34-fold after 72 hr. In addition, the level of protein-cysteine mixed disulfide (
PSSC
) was elevated after 48 hr incubation in H2O2. At this time point, PSSP aggregates began to appear both in water soluble (WS) and urea soluble (US) fractions along with a drastic reduction in protein solubility. Western blot analysis of the protein fractions identified beta and gamma, but not alpha-crystallin in the disulfide-containing aggregates. The lens clarity and biochemical changes partially recovered if the oxidant was removed within 24 hr, indicating a potential therapeutic role for antioxidants. The complete normalization of PSSG level under this recovery condition signifies that cells may have a natural defense system for controlling PSSG elevation.
...
PMID:The effect and recovery of long-term H2O2 exposure on lens morphology and biochemistry. 840 82
It has been previously shown in H2O2-induced cataract model in the rat lens that protein-
GSH
(PSSG) formation precedes protein-protein disulfide (PSSP) conjugation and lens opacity. This elevated PSSG spontaneously reduces to a normal level when H2O2 is removed. To verify if thioltransferase (TTase), an enzyme that is known in other tissues to dethiolate PSSG, takes part in this recovery process, we examined the relationship of PSSG and TTase in this cataract model. To ensure enough tissue would be available for various biochemical studies, H2O2 induced cataract in pig lens was established and validated with the rat lens model. The study was divided into two parts. One part was to examine the effect of H2O2 concentration, ranging from 0.1 mM-10 mM, during 24 hr. Another part was to study the H2O2 (1.5 mM) induced cataract progression and recovery, parallel to the long-term study in rat lenses reported previously. These lenses were compared for transparency, wet weight,
GSH
, PSSG levels and the activity of two redox regulating enzymes, glutathione reductase (GR) and TTase. For the most part, pig lens responded to oxidation parallel to the rat lens except that a higher concentration of H2O2 was needed to achieve the same results. Damage induced by H2O3 was concentration dependent. In general TTase activity and
GSH
level were depleted with a concomitant increase in PSSG. The D50 (50% damage) for
GSH
in pig lens was 1.5 mM H2O2 (0.5 mM for rat lens) which was chosen for further studies in cataract progression and recovery. At 1.5 mM H2O2, pig lens showed superficial opacity within 24 hr and deeper cortical opacity in 48 hr. The pre-exposed lens became less cloudy when H2O3 was removed from the medium. Incubation of the lens in 1.5 mM H2O2 for one day also induced 50%
GSH
depletion and four fold PSSG elevations. This accumulated PSSG was dethiolated spontaneously in the absence of H2O2, similar to the findings in the rat lens and human lens models. In contrast protein-cysteine (
PSSC
) showed little change and did not respond to the recovery condition. TTase lost 50% activity in these lenses during 24-hr H2O3 exposure but regained most of it under recovery. The study on rat lens showed similar results as before, therefore only data on the relationship of TTase activity to PSSG level during cataract development and recovery is reported here. It was found that in the H2O2 (0.5 mM)-exposed rat lenses, the TTase activity was depleted but PSSG accumulation was accelerated within 8 hr. Both recovered quickly (within 8 hr) as soon as the oxidant was removed. Therefore, protein thiolation and dethiolation processes in the cultured rat or pig lenses display a mirror image with the activity pattern of TTase. Based on the close relationship between lens TTase and PSSG indicated above, it is speculated that TTase may regulate PSSG and maintain it at a low concentration in situ. This repair process may contribute to the improved transparency during recovery. Further studies are planned to substantiate this hypothesis.
...
PMID:Relationship of protein-glutathione mixed disulfide and thioltransferase in H2O2-induced cataract in cultured pig lens. 924 98
Lead (Pb) is known to disrupt the pro-oxidant/anti-oxidant balance of tissues which leads to biochemical and physiological dysfunction. The present study investigated the effects of exposure on the redox status of the lenses of Fisher 344 rats and examined whether antioxidant or chelator administration reversed these changes. Animals were given 5 weeks of 2000 ppm Pb exposure followed by 1 week of either antioxidant, chelator or distilled water administration. Glutathione (
GSH
) and cysteine (CYS) levels decreased in the Pb-exposed group. N-acetylcysteine or 2,3-dimercaptopsuccinic acid (Succimer) supplementation following Pb intoxication resulted in increases in the
GSH
and CYS levels. Protein bound glutathione (PSSG) and cysteine (
PSSC
) increased following Pb exposure. In the Succimer-treated animals, the PSSG decreased significantly. The glutathione disulfide (GSSG) levels remained unchanged. Malondialdehyde (MDA) levels, a major lipid peroxidation byproduct, increased following Pb exposure and decreased following Succimer treatment. Our results suggest that antioxidant supplementation, as well as chelation, following Pb exposure may enhance the reductive status of lenses.
...
PMID:Effects of N-acetylcysteine and 2,3-dimercaptosuccinic acid on lead induced oxidative stress in rat lenses. 986 83
This study describes a new methodology by which the concentrations of non-protein (NP) thiols glutathione (
GSH
), cysteine (CSH), N-acetylcysteine (AcCSH), and protein (P) thiols (PSH), as well as the contribution of these components to symmetric and mixed disulfides (NPSSR, NPSSC, NPSSCAc, PSSR,
PSSC
, PSSCAc, PSSP) can reliably be measured. The methodology consists of a strict sequence of methods which are applied to every sample. Free thiols at any given state of the procedure are measured by Ellman's assay, the CSH fraction is measured by its unique response in the ninhydrin assay, AcCSH is selectively measured with ninhydrin after enzymatic deacylation, proteins are separated from non-protein thiols/disulfides by precipitation with trichloroacetic or perchloric acid, disulfides are reduced into free thiols with borohydride, mixed disulfides between a protein and a non-protein component are measured by extracting the non-protein thiol from the protein pellet after borohydride treatment, and protein thiols/disulfides are measured after resolubilization of the protein pellet. When this method was applied to animal and fungal tissue, new molecular indicators of the thiol redox state of living cells were identified. The findings of the present study clearly show that the new parameters are very sensitive indicators of redox state, while at the same time the traditional parameters
GSH
and GSSG often remain constant even upon dramatic changes in the overall redox state of biological tissue. Therefore, unbiased assessment of the redox state also requires explicit measurement of its most sensitive thiol indicators.
...
PMID:Determination of the thiol redox state of organisms: new oxidative stress indicators. 1498 9
In the present study we examined the effects of pentylenetetrazol (PTZ) administration on the thiol redox state (TRS), lipid peroxidation and protein oxidation in left and right mouse cerebral cortex in order (a) to quantitate the major components of the thiol redox state and relate them with oxidative stress and cortical laterality, and (b) to investigate whether neuronal activation without synchronization, induced by subconvulsive doses of PTZ, can cause similar qualitative effects on the thiol redox state. Specifically, we examined the TRS components [glutathione (
GSH
), glutathione disulfide (GSSG), cysteine (CSH), protein (P) thiols (PSH) and protein and non-protein (NP) mixed/symmetric disulfides (PSSR, NPSSR, NPSSC, PSSP)]. At 15 min after seizure,
GSH
, GSSG, CSH, NPSSC, PSSR and
PSSC
levels are decreased in left (14-50%) and right (11-53%) cortex while PSSP levels are increased in both left (1400%) and right (1600%) cortex. At 30 min after seizure, GSSG, CSH, NPSSC, PSSR and
PSSC
levels are decreased in left (14-51%) and right (18-56%) cortex while PSSP and protein carbonyl levels are increased in left (2300% and 20%, respectively) and right (2800% and 21%, respectively) cortex. At 24 h after seizure, the TRS components return to normal and protein carbonyl levels are decreased in left (16%) and right (20%) cortex. The significant decrease in
GSH
, GSSG, CSH, NPSSC, PSSR and
PSSC
, as well as the increase in protein carbonyl and the high increase in PSSP levels after PTZ-induced seizure indicate increased oxidative stress in cerebral cortex of mice, and of similar magnitude and TRS-component profiles between left and right cerebral cortex.
...
PMID:Effect of pentylenetetrazol-induced epileptic seizure on thiol redox state in the mouse cerebral cortex. 1551 33
In this study we measured thiol redox state (TRS) and the oxidative stress indicator lipid peroxidation in midbrain and striatum of adult (4 months old) male control (+/+) and weaver (wv/wv) mice in order to relate them with oxidative stress in conditions of progressive and severe (approximately 70%) nigrostriatal dopaminergic neurodegeneration. Specifically, we measured the specific TRS components glutathione (
GSH
), glutathione disulfide (GSSG), cysteine (CSH), and the general classes of TRS components. The latter are the protein thiols (PSH) and the disulfides between (a) protein (P) and protein thiols (PSSP), (b) protein and non-protein (NP/R) thiols (PSSR,
PSSC
) and (c) non-protein and non-protein thiols (NPSSR, NPSSC). In addition, the main product of lipid peroxidation malonyl dialdehyde (MDA) was estimated. In the midbrain of wv/wv,
GSH
and NPSSC levels are decreased (44% and 64%, respectively) and GSSG, NPSSR, CSH, PSH, PSSP, PSSR and MDA levels are increased (23%, 660%, 110%, 51%, 68%, 18% and 44%, respectively). In the striatum of male wv/wv, protein and non-protein thiol/disulfide and MDA levels do not change, possibly due to the high decrease in striatal dopamine level versus midbrain. Our data show that the high degeneration of the dopaminergic nigrostriatal neurons in male adult wv/wv mice is accompanied by significant changes in TRS and an increase in lipid peroxidation in the midbrain, suggesting involvement of oxidative stress in the degeneration of dopaminergic neurons. They also strengthen the possible use of thiol antioxidants for the development of new neuroprotective therapeutic strategies for neurodegenerative diseases, such as Parkinson's disease.
...
PMID:Thiol redox state and oxidative stress in midbrain and striatum of weaver mutant mice, a genetic model of nigrostriatal dopamine deficiency. 1569 68
Thiol redox state (TRS) evaluation is mostly restricted to the estimation of
GSH
and GSSG. However, these TRS parameters can estimate the GSSG/
GSH
potential, which might be useful for indicating abnormalities in redox metabolism. Nonetheless, evaluation of the multiparameric nature of TRS is required for a more accurate assessment of its physiological role. The present protocol extends the partial assessment of TRS by current methodologies. It measures 15 key parameters of TRS by two modular subprotocols: one for the glutathione (
GSH
)- and cysteine (CSH)-based nonprotein (NP) thiols/mixed disulfides (i.e.,
GSH
, GSSG, GSSNP, CSH, CSSNP, NPSH, NPSSNP, NP(x)SH(NPSSNP), NP(x)SH(NPSH)), and the other for their protein (P) thiols/mixed disulfides (i.e., PSH, PSSG,
PSSC
, PSSNP, PSSP, NP(x)SH(PSSNP)). The protocol eliminates autoxidation of
GSH
and CSH (and thus overestimation of GSSG and CSSNP). Its modularity allows the determination
GSH
and GSSG also by other published specific assays. The protocol uses three assays; two are based on the photometric reagents 4,4'-dithiopyridine (DTP) and ninhydrin (NHD), and the third on the fluorometric reagent o-phthaldialdehyde (OPT). The initial assays employing these reagents have been extensively modified and redesigned for increased specificity, sensitivity, and simplicity. TRS parameter values and their standard errors are estimated automatically by sets of Excel-adapted algebraic equations. Protocol sensitivity for NPSH, PSH, NPSSNP, PSSP, PSSNP, CSH, CSSNP,
PSSC
, NP(x)SH(NPSSNP), and NP(x)SH(NPSH) is 1 nmol -SH/CSH, for GSSNP 0.2 nmol, for
GSH
and GSSG 0.4 nmol, and for PSSG 0.6 nmol. The protocol was applied on human plasma, a sample of high clinical value, and can be also applied in any organism.
...
PMID:Multiparametric protocol for the determination of thiol redox state in living matter. 2499 3
