UMLS:C0086543 - FACTA Search

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

NADPH and NADP+ levels were measured in rat lens from normal controls, from galactose-fed and diabetic rats during the first week of cataract formation. The level of NADPH in normal rat lens was determined to be 12.3 +/- 0.4 nmol/g wet weight, and that of NADP+ 4.6 +/- 0.2 nmol/g wet weight. In early cataract formation NADPH levels decreased rapidly during the first 2 days and then remained stable at 76% of control for galactose-fed and 84% for diabetic rats. NADP+ levels increased by 38% of control for galactose-fed and 54% for diabetic rats. Calculated NADPH/NADP+ ratios dropped from 3.36 +/- 0.21 to 1.86 +/- 0.16 in galactose fed rats, and from 2.81 +/- 0.15 to 1.61 +/- 0.16 in diabetic rats (P less than 0.001 for both experimental groups). These data are consistent with rapid NADPH oxidation during onset of lens cataracts. No significant changes in aldose reductase enzymatic activity levels were observed in either the galactosemic or the diabetic rats during the times measured.
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PMID:Aldose reductase, NADPH and NADP+ in normal, galactose-fed and diabetic rat lens. 392 85

The rapid conversion of glucose to sorbitol by aldose reductase and the consequent hyperosmolarity of the cytoplasm has been shown to be the primary cause of the so-called "sugar" or "osmotic" cataract in many animal lenses. It is not as clear, however, that hyperosmolarity is the principal factor in the etiology of cataracts in human diabetic subjects. In fact, the comparatively low activity of aldose reductase in the human lens as compared with several animal lenses, and the osmotically insignificant levels of sorbitol pathway products (sorbitol and fructose), suggest that hyperosmolarity, per se, may not be as important a factor in human cataract formation as it is in animals. We present evidence that the flux of glucose and sorbitol through the rat lens is markedly reduced by oxidative stress (0.1 mM H2O2). Sorbitol accumulation is reduced by 114%, sorbitol turnover is reduced by 78%, sorbitol production is reduced by 90%, fructose accumulation is reduced by 60%, and fructose turnover is reduced by 76% in the presence of 36 mM glucose. H2O2 does not affect glucose turnover, the glucose rate constant, or the ATP level significantly at 36 mM glucose, but at 5.5 mM glucose, 0.2 mM H2O2 leads to a rapid loss of ATP that can be prevented by 0.04 mM sorbinil, an aldose reductase inhibitor. These results suggest that inhibition of aldose reductase by sorbinil renders rat lenses better able to cope with oxidative stress. In the absence of an aldose reductase inhibitor, elevating ambient glucose may render a lens less able to scavenge oxidants by diverting NADPH into sorbitol production.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The effect of oxidation on sorbitol pathway kinetics. 395 80

The possibility that vitamin E or other antioxidants might prevent cataracts was tested by incubating rat lenses in vitro in galactose-enriched medium or by treating rats fed a diet containing 50% galactose (w/w). The vitamin E was added to the medium at 2.4 microM, and to the diet at a level of 5 g kg-1 diet. In vitro, lenses incubated with 55.6 mM galactose underwent globular degeneration, which was partially prevented by addition of vitamin E (2.4 microM). Even in such vitamin E-protected lenses, which appeared clear, many small globules could be seen in the region of interdigitation at the 'corners' where hexagonal cells intersected. In vivo, in dietary experiments, a dense nuclear opacity of the lens was observed after approximately 5 weeks; unlike diabetic cataracts, this was not prevented by the addition of vitamin E to the diet. The extensive globular degeneration observed was typical of that found in long-term (21-week diabetic) cataracts. Although no significant difference in cataract incidence was observed, the extent of damage in vitamin E-treated rat lenses appeared to be less. The difference in effectiveness of vitamin E in galactose-induced cataracts, as compared to diabetic cataracts, is tentatively ascribed to (1) the more severe osmotic stress expected from the products of the aldose reductase pathway for galactose and (2) the greater depletion of reduced pyridine nucleotides (NADPH + NADH) expected of galactose as compared to glucose.
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PMID:Modelling cortical cataractogenesis VII: Effects of vitamin E treatment on galactose-induced cataracts. 397 62

Levels of lens aldose reductase, aldehyde dehydrogenase activity, and erythrocyte NADPH-oxidising (or glyceraldehyde reductase) activity were determined in 17 diabetic and 16 nondiabetic patients undergoing cataract extraction. Lens aldose reductase and aldehyde dehydrogenase activities were significantly lower in diabetics than in nondiabetics. Both enzymes showed significant inverse correlations with grouped HbA1c and fasting blood glucose levels. By contrast, erythrocyte NADPH-oxidising activity showed a significant positive correlation with grouped HbA1C. It is suggested that a direct effect of the glycaemic status on the lens enzymes is masked by a loss of enzymes secondary to the development of cataract. It is not yet possible to say whether erythrocyte NADPH-oxidising activity can be used to monitor aldose reductase activity in the lens or other tissues in clinical trials of aldose reductase inhibitors.
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PMID:NADPH-oxidising activity in lens and erythrocytes in diabetic and nondiabetic patients with cataract. 641 39

The mammalian lens contains an unusually high concentration of glutathione (GSH), the highest level being in the epithelium. GSH is present largely in the reduced state. The high concentration of GSH in a normal lens and the decreased concentration in most types of cataracts have led to many hypotheses on its role in cataract formation. These hypotheses are considered in the light of current evidence. GSH is synthesized and degraded in the lens. Both processes require ATP, derived largely from glycolysis. Carbohydrate metabolism is also involved in the maintenance of GSH in the reduced state. There is a direct link between the rate of formation of oxidized glutathione (GSSG) and the stimulation of the hexose monophosphate shunt through the generation of NADPH. One possible function of GSH in the lens is to maintain the thiol (SH) groups of proteins in the reduced state, thus preventing formation of high molecular weight (HMW) protein aggregates. The formation of HMW proteins in X-ray-induced cataracts through disulphide bond formation and the involvement of SH oxidation in HMW proteins isolated from human cataractous lenses suggest a role for GSH in protecting protein SH groups. GSH in the lens may also protect critical SH groups involved in regulating cation transport and permeability. Studies with mammalian lenses indicate that lowering the lens GSH concentration leads to increased permeability to cations and inactivation of Na+,K+-ATPase. A consequence of the changes in ion distribution is the inhibition of protein synthesis, which may explain the cessation of growth in cataractous lenses. GSH may also protect against oxidative damage to the lens. GSH metabolism is intimately involved in detoxification of H2O2, normally present in the aqueous humour. Lenses with impaired shunt activity or inhibited glutathione reductase are more susceptible to oxidative damage by peroxide. This may contribute to the formation of cataract.
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PMID:Metabolism and function of glutathione in the lens. 656 81

Steroids that inhibit glucose-6-phosphate dehydrogenase (G6PD) were used to examine the correlation between the loss of GSSG-reducing activity and G6PD deficiency in the lens. The correlation was found to be nonlinear. In senile cataracts, which had lost 36% of NADPH-generating activity as compared to clear lenses, the estimated loss of GSSG reduction was only 20%. On the other hand, lenses with severe G6PD deficiency (i.e. 93% loss) retained at least 28% GSSG-reducing activity. The declined reducing activity, however, suggested a possible role of G6PD deficiency in cataract formation in young patients.
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PMID:GSSG-reducing activity in lenses deficient in glucose-6-phosphate dehydrogenase. 662 60

Two monomeric NADPH enzymes from pig lens, an aldehyde reductase and an aldose reductase, have been characterized. The aldose reductase is obtained in a pure form. The aldehyde reductase, usually called hexonate dehydrogenase, is the same protein as that was recently isolated from pig liver [Branlant, G. and Biellmann, J.F. (1980) Eur. J. Biochem. 105, 611-621]. The aldose reductase is shown to have a number of properties in common with the aldehyde reductase, namely its physico-chemical properties, its tendency to be inhibited by quercitine derivatives and its substrate specificity. These two enzymes differ in their immunological properties. Only aldose reductase has a reactive Cys residue, localized in or near the substrate binding site. In contrast to that shown for aldehyde reductase [Branlant, G. et al. (1981) Eur. J. Biochem. 116, 505-512; Branlant, G. (1982) Eur. J. Biochem. 121, 407-411], no anion-recognition sites are in the substrate binding site of aldose reductase. The fact that also sugars are substrates for aldose reductase support the idea that this enzyme is implicated in the formation of sugar cataract as suggested by Kinoshita, J.H. et al. [J. Am. Med. Ass. 246, 257-261 (1981)]. Pig lens aldose reductase does not show homotropic cooperative effects with respect to either substrate or coenzyme.
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PMID:Properties of an aldose reductase from pig lens. Comparative studies of an aldehyde reductase from pig lens. 681 41

The effects of acarbose on cataract development, lens aldose reductase (EC 1.1.1.21) activity and lenticular reduced-glutathione content in diabetic sand rats (Psammomys obesus) were determined. Diabetic sand rats (diet-induced) were fed on diets with or without acarbose (0.4 g/kg) for 39 d. Daily plasma glucose, cataract incidence, aldose reductase and glutathione content were evaluated. After 19 d on acarbose, daily plasma glucose profile was significantly reduced compared with that of sand rats not receiving acarbose. Cataract incidence was markedly lower in sand rats treated with acarbose. After 20 d, cataracts had developed in 90% of the animals fed without acarbose, whereas none was observed in sand rats fed with acarbose. After 37 d acarbose treatment the incidence of cataracts reached only 30%. Compared with untreated animals, lens aldose reductase activity was significantly lower in sand rats fed with acarbose for 39 d (7.6 (SE 0.78) v. 3.5 (SE 0.55) mumol NADPH/mg protein per min respectively, P < 0.001). Concomitantly, significantly higher lenticular protein and reduced-glutathione contents (90 (SE 23) v. 240 (SE 23.5) micrograms/mg tissue respectively, P < 0.001 and 369 (SE 48.6) v. 645 (SE 71.1) micrograms/mg tissue respectively, P < 0.001) were found. These results suggest that decreasing hyperglycaemia, accompanied by lower aldose reductase activity obtained by acarbose, led to a significant preventive effect on cataract development in sand rats.
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PMID:Aldose reductase (EC 1.1.1.21) activity and reduced-glutathione content in lenses of diabetic sand rats (Psammomys obesus) fed with acarbose. 854 Dec 68

Aldose reductase initiated sugar cataract formation in 9-month old galactose-fed dogs has been documented to progress from an accentuation of lens sutures (1 month after initial feeding) to the appearance of cortical vacuoles (3 months), cortical opacities (4-6 months) and eventually the progressive formation of a clear zone at the cortical equatorial regions of the cataractous lenses (> 12 months). Here, the effect of age on the onset and degree of sugar cataract formation has been investigated in beagles fed a 30% galactose diet starting at 2, 6, and 24 months of age. Cataract formation was monitored by slit lamp and retroillumination microscopy. Compared to 9-month old dogs, cataract formation in the younger dogs was more rapid and the lens changes were more severe. In the 2-month old group of dogs, galactose-feeding resulted in a rapid formation of dense cataracts which began to resorb after 106 days of galactose feeding with only opaque nuclear remnants remaining after eight months. These changes were mirrored by age-dependent reductions of lenticular NADPH-dependent reductase activity.
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PMID:Age-dependent lens changes in galactose-fed dogs. 919 95

In diabetic cataract, sorbitol pathway flux perturbs intracellular metabolism by two putative mechanisms. The osmolyte hypothesis implicates the aldose reductase enzyme, increased rate of reduction of glucose of sorbitol and reciprocal osmoregulatory depletion of organic osmolytes (myo-inositol). Redox hypothesis favors alterations in the ratios (NADP+/NADPH and/or NADH/NAD+ as the primary cause of glucose-induced aldose reductase related defects. Increase in NADH/NAD+ promotes increased oxidation of sorbitol to fructose by polyol dehydrogenase; potential normalization of this ratio by coadministration of pyruvate (which reoxidizes NADH to NAD+ via lactate dehydrogenases reaction) was investigated. Effects of exogenous pyruvate on lens polyol formation and sodium-dependent myo-inositol (MI) cotransporter using two in vitro models of sugar cataract were determined. Rat lenses were incubated for 16 h in either normal (5.5 mM) or high sugar medium, 35.5 mM glucose or 30 mM galactose. Then lens MI influx was compared to polyol, MI and fructose content. Pyruvate did not affect MI influx or sorbitol content in lenses incubated in control medium. In 35.5 mM glucose, coadministration of pyruvate maintained lens MI influx at 76% of control values vs. 43% for lenses without pyruvate. Furthermore, pyruvate treatment diminished lens sorbitol content by 50% and increased lens sugar content (myo-inositol, fructose, lactate) and media lactate levels. Lenses incubated in high galactose medium formed galactitol with a corresponding decreased MI content. Coadministration of pyruvate had no effect on either lens sugar content (galactitol, myo-inositol, fructose) or MI influx, consistent with the fact that galactitol was not metabolized to fructose. In conclusion, pyruvate did not exert a direct effect on the MI co-transporter or prevent galactitol inhibition of MI influx. Coadministration of pyruvate with high glucose altered lens metabolism and promoted reduction of pyruvate to lactate, increased fructose, decreased sorbitol, enhanced MI influx, maintained lens MI content, implicating both osmotic and redox systems.
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PMID:Effect of pyruvate on lens myo-inositol transport and polyol formation in diabetic cataract. 932 7

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