Glutathione: a vital lens
antioxidant.
Giblin FJ. [J Ocul Pharmacol Ther. 2000 Apr;16(2):121-35.] The
reducing compound glutathione (GSH) exists in an unusually high concentration in
the lens where it functions as an essential antioxidant vital for maintenance of
the tissue's transparency. In conjunction with an active glutathione
redox cycle located in the lens epithelium and superficial cortex, GSH
detoxifies potentially damaging oxidants such as H2O2 and dehydroascorbic acid.
Recent studies have indicated an important hydroxyl radical-scavenging function
for GSH in lens epithelial cells, independent of the cells' ability to detoxify
H2O2. Depletion of GSH or inhibition of the redox cycle allows low levels of
oxidant to damage lens epithelial targets such as Na/K-ATPase, certain
cytoskeletal proteins and proteins associated with normal membrane permeability.
The level of GSH in the nucleus of the lens is relatively low, particularly in
the aging lens, and exactly how the compound travels from the epithelium to the
central region of the organ is not known. Recently, a cortical/nuclear barrier
to GSH migration in older human lenses was demonstrated by Sweeney et al. The
relatively low ratio of GSH to protein -SH in the nucleus of the lens, combined
with low activity of the glutathione redox cycle in this region, makes the
nucleus especially vulnerable to oxidative stress, as has been demonstrated with
use of in vivo experimental animal models such as hyperbaric oxygen, UVA light
and the glutathione peroxidase knockout mouse. Effects observed in these models,
which are currently being utilized to investigate the mechanism of formation of
human senile nuclear cataract, include an increase in lens nuclear disulfide,
damage to nuclear membranes and an increase in nuclear light scattering.
A need exists for development of therapeutic agents to slow age-related loss of
antioxidant activity in the nucleus of the human lens to delay the onset of
cataract.
Protection of retinal pigment epithelium from oxidative injury by glutathione
and precursors.
Sternberg P Jr, Davidson PC, Jones DP, Hagen TM, Reed RL, Drews-Botsch C.
[Invest Ophthalmol Vis Sci. 1993 Dec;34(13):3661-8.]
This study was performed to examine the effect of exogenous glutathione (GSH) or
its precursor amino acids on oxidative injury in cultured human retinal pigment
epithelium (RPE). Added GSH provided protection at concentrations of 0.01 mM and
higher. The amino acid precursors for GSH, glutamate, cysteine, and glycine also
protected against injury, but this required at least 0.1 mM of each amino acid.
These results indicate that protection by the amino acid precursors is
mediated through synthesis of GSH, and they also show that exogenous GSH can
provide protection against oxidative injury.
Glutathione in human
plasma: Decline in association with aging, age- related macular degeneration,
and diabetes
Samiec PS,
Drews-Botsch C, and others. [Free Radic Biol Med 1998 Mar 15;24(5):699-704.]
Blood samples were analyzed for GSH and GSH redox state in 40 age-related
macular degeneration (ARMD) patients (> 60 y), 33 non-ARMD diabetic patients (>
60 years), 27 similarly aged non-ARMD and nondiabetic individuals (> 60 years),
and 19 younger individuals (< 60 years) without ARMD or diabetes. Results showed
a significantly lower plasma GSH in older individuals (ARMD, diabetes, and
controls) than in younger individuals. The results suggest that in studies of
age-related pathologies, oxidation of GSH may be a more important parameter than
a decline in pool size, while in specific pathologies such as diabetes, both
oxidation and a decline in pool size may be important.
Publication
Types:
Clinical Trial
Controlled Clinical Trial
Glutathione peroxidase-1
deficiency leads to increased nuclear light scattering, membrane damage, and
cataract formation in gene-knockout mice.
Reddy VN, Giblin FJ, Lin LR, Dang L, Unakar NJ, Musch DC, Boyle DL, Takemoto
LJ, Ho YS, Knoernschild T, Juenemann A, Lutjen-Drecoll E. [Invest
Ophthalmol Vis Sci. 2001 Dec;42(13):3247-55.] Previous in vitro studies with
transgenic and gene-knockout mice have shown that lenses with elevated levels of
glutathione peroxidase (GPX)-1 activity are able to resist the cytotoxic effect
of H(2)O(2), compared with normal lenses and lenses from GPX-1-deficient
animals. The purpose of this study was to investigate the functional role of
this enzyme in antioxidant mechanisms of lens in vivo by comparing lens changes
of gene-knockout mice with age-matched control animals. The results
demonstrate the critical role of GPX-1 in antioxidant defense mechanisms of the
lens nucleus.
Specialized protective role of mucosal glutathione in pigmented rabbit
conjunctiva.
Gukasyan HJ, Kim KJ, Kannan R, Farley RA, Lee VH. [Invest Ophthalmol
Vis Sci. 2003 Oct;44(10):4427-38.] To investigate mechanisms of H(2)O(2)-induced
reduction in rates of active ion transport (I(sc)) across the pigmented rabbit
conjunctival tissue and the protective role afforded by mucosal glutathione (GSH).
...actively secreted GSH by conjunctival epithelial cells may help reduce the
injury by mucosally applied H(2)O(2). Injury by H(2)O(2) may directly affect
vital membrane components (e.g., Na(+),K(+)-ATPase) involved in active ion
transport across conjunctiva. Mucosal protection by GSH (or its
analogues) of active conjunctival ion transport may be useful in maintaining the
physiological functions of conjunctiva under oxidative stress.
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Prog Retin Eye Res 2000 Mar;19(2):205-21 |
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Oxidative damage and protection of the RPE.
Cai J, Nelson KC, Wu M, Sternberg P Jr, Jones DP.
Department of Biochemistry,
This review provides a model for the role of oxidative stress in the etiology
of age-related macular degeneration (AMD). Epidemiological studies of diet,
environmental and behavioral risk factors suggest that oxidative stress is a
contributing factor of AMD. Pathological studies indicate that damage to the
retinal pigment epithelium (RPE) is an early event in AMD. In vitro studies
show that oxidant treated RPE cells undergo apoptosis, a possible mechanism by
which RPE cells are lost during early phase of AMD. The main target of
oxidative injury seems to be mitochondria, an organelle known to accumulate
genomic damages in other postmitotic tissues during aging. The thiol
antioxidant GSH and its amino acid precursors protect RPE cells from
oxidant-induced apoptosis. Similar protection occurs with dietary enzyme
inducers which increase GSH synthesis. These results indicate that therapeutic
or nutritional intervention to enhance the GSH antioxidant capacity of RPE may
provide an effective way to prevent or treat AMD.
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Oxidative damage and age-related macular
degeneration.
Winkler BS, Boulton ME, Gottsch JD, Sternberg P.
Eye Research Institute,
This article provides current information on the potential role of oxidation
in relation to age-related macular degeneration (AMD). The emphasis is
placed on the generation of oxidants and free radicals and the protective
effects of antioxidants in the outer retina, with specific emphasis on the
photoreceptor cells, the retinal pigment epithelium and the choriocapillaris.
The starting points include a discussion and a definition of what radicals
are, their endogenous sources, how they react, and what damage they may cause.
The photoreceptor/pigment epithelium complex is exposed to sunlight, is bathed
in a near-arterial level of oxygen, and membranes in this complex contain high
concentrations of polyunsaturated fatty acids, all considered to be potential
factors leading to oxidative damage. Actions of antioxidants such as
glutathione, vitamin C, superoxide dismutase, catalase, vitamin E and the
carotenoids are discussed in terms of their mechanisms of preventing oxidative
damage. The phototoxicity of lipofuscin, a group of complex
autofluorescent lipid/protein aggregates that accumulate in the retinal
pigment epithelium, is described and evidence is presented suggesting that
intracellular lipofuscin is toxic to these cells, thus supporting a role for
lipofuscin in aging and AMD. The theory that AMD is primarily due to a
photosensitizing injury to the choriocapillaris is evaluated. Results are
presented showing that when protoporphyric mice are exposed to blue light
there is an induction in the synthesis of Type IV collagen synthesis by the
choriocapillary endothelium, which leads to a thickened Bruch's membrane and
to the appearance of sub-retinal pigment epithelial fibrillogranular deposits,
which are similar to basal laminar deposits. The hypothesis that AMD may
result from oxidative injury to the retinal pigment epithelium is further
evaluated in experiments designed to test the protective effects of
glutathione in preventing damage to cultured human pigment epithelial cells
exposed to an oxidant. Experiments designed to increase the concentration of
glutathione in pigment epithelial cells using dimethylfumarate, a
monofunctional inducer, are described in relation to the ability of these
cells to survive an oxidative challenge. While all these models provide
undisputed evidence of oxidative damage to the retinal pigment epithelium and
the choriocapillaris that is both light- and oxygen-dependent, it nevertheless
is still unclear at this time what the precise linkage is between
oxidation-induced events and the onset and progression of AMD.
Studies on the mechanism of early onset macular degeneration in cynomolgus monkeys. II. Suppression of metallothionein synthesis in the retina in oxidative stress.
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