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Query: UMLS:C0086543 (
cataract
)
29,165
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
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
