Enzyme-induced posterior vitreous detachment in the rat produces increased lens nuclear pO2 levels.

It has been proposed that disruption of normal vitreous humor may permit O(2) to travel more easily from the retina to the center of the lens where it may cause nuclear cataract (Barbazetto, I.A., Liang, J., Chang, S., Zheng, L., Spector, A., Dillon, J.P., 2004. Oxygen tension in the rabbit lens and vitreous before and after vitrectomy. Exp. Eye Res. 78, 917-924; Harocopos, G.J., Shui, Y.B., McKinnon, M., Holekamp, N.M., Gordon, M.O., Beebe, D.C., 2004. Importance of vitreous liquefaction in age-related cataract. Invest. Ophthalmol. Vis. Sci. 45, 77-85). In the present study, we injected enzymes intravitreally into guinea pigs (which possess an avascular retina) and rats (which possess a vascular retina) to produce either vitreous humor liquefaction plus a posterior vitreous detachment (PVD) (with use of microplasmin) or vitreous humor liquefaction only (with use of hyaluronidase), and 1-2 weeks later measured lens nuclear pO(2) levels in vivo using a platinum-based fluorophore O(2) sensor (Oxford-Optronix, Ltd.). Experiments were also conducted in which the animals were allowed to breathe 100% O(2) following intravitreal injection with either microplasmin or hyaluronidase in order to investigate possible effects on O(2) exchange within the eye. Injection of guinea pigs with either of the two enzymes produced no significant differences in lens pO(2) levels 1-2 weeks later, compared to controls. However, for the rat, injection of microplasmin produced a 68% increase in O(2) level in the center of the lens, compared to the controls (5.6mm Hg increasing to 9.4mm Hg, p<0.05), with no corresponding effect observed following similar use of hyaluronidase. Treatment of guinea pigs with microplasmin dramatically accelerated movement of O(2) across the vitreal space when the animals were later allowed to breathe 100% O(2) (for example, O(2) traveled to a location directly behind the lens 5x faster than control; p<0.01); however, the effect following treatment with hyaluronidase was significantly less. When microplasmin-injected rats breathed 100% O(2), the time required for O(2) to reach the center of the lens was 3x faster than control (0.4 min compared to 1.4 min, p<0.01). The results have implication with regard to the occurrence of age-related PVD in the human, and a possible acceleration of maturity-onset nuclear cataract. In addition, enzymatic creation of a PVD to increase the rate of O(2) exchange within the vitreal space may have potential application for treatment of retinal ischemic disease.

The effect of inhibition of glutathione reductase on the detoxification of H2O2 by rabbit lens.

Mechanisms by which the lens protects against H2O2 are believed to include the metabolism of glutathione (GSH). In the present study, rabbit lenses were exposed to constant concentrations of H2O2 (0.01 to 0.1 mM) that were maintained in culture media with the use of a peristaltic pump. The rate at which H2O2 entered the lens was proportional to its concentration in the medium and reached 2.6 mumol H2O2/lens/3 hr at 0.1 mM H2O2. Up to 0.06 mM H2O2, a concentration that approximates that present in normal rabbit aqueous humor, the activity of the hexose monophosphate shunt (HMPS) increased linearly with no significant decrease in the concentration of lens GSH. However, at 0.1 mM H2O2, there was indication of oxidative damage to the lens as shown by a sharp decrease in HMPS activity and a coincident drop in the concentration of GSH. Pretreatment of lenses with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), an inhibitor of glutathione reductase (GR), blocked the normal threefold stimulation of HMPS activity occurring in the presence of 0.06 mM H2O2 and resulted in accumulation of oxidized GSH. This result demonstrated the inability of H2O2 to react directly with NADPH in the lens. BCNU was shown not to affect the potential of the HMPS to respond to compounds other than H2O2 since it did not alter methylene blue-stimulation of HMPS activity. The study supports the hypothesis that detoxification of H2O2 in the aqueous humor is linked to the metabolism of GSH in the lens and demonstrates that lenses with impaired GR activity are more susceptible to oxidative damage by peroxide.

The effect of X-irradiation on Na-K ATPase and cation distribution in rabbit lens.

The Na-K ATPase activity of rabbit lens was measured at various times after exposure to a single dose of 2000 rads of X-ray and was compared with that in contralateral control eyes. A decrease in enzyme activity in both whole lens and in isolated capsule-epithelium was first observed 3 to 4 weeks after irradiation and became increasingly marked at 7.5 weeks after X-ray. These findings are consistent with our earlier observations that active transport of cations is reduced in these lenses and support the view that loss of membrane ATPase is responsible for the impairment of the cation pump in X-irradiated lenses. Despite a significant loss of the enzyme, X-irradiated lenses were able to maintain near normal levels of total cations (Na+ + K+), thus accounting for their normal hydration. The results of the changes in lens Na+ and K+ levels revealed that between 4 and 7.5 weeks after X-ray, the gain in Na+ was compensated by an equivalent loss of K+. A breakdown of this relationship of 1:1 exchange of Na+ for K+ is accompanied by a disproportionate increase in Na+ and water.

The effects of X-irradiation on lens reducing systems.

Studies have been made of the effects of X-ray on various lens reducing systems, including the levels of NADPH and glutathione (GSH), the activity of the hexose monophosphate shunt (HMS) and of certain enzymes, including GSH reductase, GSH peroxidase, and glucose-6-phosphate dehydrogenase (G-6-PG). It was found that during several weeks following X-irradiation but prior to cataract formation, there was very little change in the number of reduced -SH groups per unit weight of lens protein but that, with the appearance of cataract, there was a sudden loss of protein -SH groups. In contrast, the concentration of GSH in the X-rayed lens decreased throughout the experimental period. Similarly, the concentration of NADPH in the X-rayed lens was found to decrease significantly relative to controls 1 week prior to cataract formation, and the ratio of NADPH to NADP+ in the lens shifted at this time period from a value greater than 1.0 in the control lens to less than 1.0 in the X-rayed lens. A corresponding decrease occurred in the activity of the HMS in X-rayed lenses as measured by culture in the presence of 1-14C-labeled glucose, G-6-PD was partially inactivated in the X-rayed lens. Of the eight enzymes studied, G-6-PD appeared to be the most sensitive to X-irradiation. The data indicate that X-irradiation results in a steady decrease in the effectiveness of lens reducing systems and that when these systems reach a critically low point, sudden oxidation of protein -SH groups and formation of high-molecular-weight protein aggregates may be initiated.

Exposure of rabbit lens to hyperbaric oxygen in vitro: regional effects on GSH level.

Previous studies have indicated that in vivo exposure to hyperbaric O2 may be associated with the development of nuclear cataract. In the present work, in vitro effects of hyperbaric O2 on rabbit lenses were investigated following culture of the lenses in an atmosphere of 99% O2 at pressures ranging between 1 and 100 atm. Treatment with O2 resulted in a significant decrease in the level of reduced glutathione (GSH) in the lenses even at the lower pressures studied (less than 8 atm). At 100 atm O2 the loss of GSH was 85% after a 3 hr exposure. At 8 atm O2 a significant drop in GSH concentration was shown to occur in the lens nucleus prior to loss of the tripeptide in the superficial cortex. O2-treated lenses became hazy in appearance, especially at the higher pressures, but did not become densely opaque. Pressures of N2 up to 100 atm had no effect on either lens transparency or on the concentration of GSH. Although oxidized glutathione (GSSG) was detected in the whole lens at pressures of O2 as low as 4 atm, no change in GSH level or evidence for GSSG accumulation was observed in the capsule-epithelium of the lens at pressures as high as 50 atm O2. Ninety percent of the GSSG present in lenses after exposure to 100 atm O2 could be reconverted to GSH by subsequent culture of the lenses under normal conditions. Exposure of lenses to 50 atm O2 produced a three-fold stimulation of hexose monophosphate shunt activity, equal to that which has been reported for treatment of lenses with 0.06 mM H2O2.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in the distribution of lens calcium during development of x-ray cataract.

The present study was designed to examine the possible role of calcium in the opacification of x-ray-induced cataract in rabbit. The results demonstrate that the concentration of calcium in x-rayed lenses, just prior to lens hydration (7.5 weeks postirradiation), was twice that present in contralateral control lenses. At this stage of immature cataract, the lens nucleus remained transparent and maintained a normal level of calcium, but the lens cortex, containing regions of subcapsular opacification, accumulated a level of calcium that was twice that of the control. In the completely opaque mature cataract, (8-9 weeks postx-ray), both the cortex and nucleus had gained significant amounts of calcium. As the concentration of total calcium increased in the immature x-ray cataract, the amount of the cation bound to membranes and insoluble proteins of the cytosol also increased comparably. However, the relative proportion of calcium in the various fractions remained unaltered in the immature cataract; in both control lenses and immature cataracts, 20% of the total calcium remained in the membrane pellet and 70% was located in the soluble protein fraction. Only in the mature stage of cataract was a shift in the distribution of calcium apparent, as the proportion of calcium in the soluble protein fraction increased to 90%. Although only 7% of the total calcium in a mature cataract was bound to membrane, the amount represented a fivefold increase over the control. The results of this study demonstrate that an elevation in lens calcium accompanies the opacification process in x-ray cataract. The work also suggests that changes in calcium levels are not likely to result from inactivation of Ca-ATPase.

Glutathione in calf trabecular meshwork and its relation to aqueous humor outflow facility.

Previous studies have shown that sulfhydryl reagents can alter the facility of aqueous humor outflow but little is known about the sulfhydryl constituents of the aqueous outflow system or the effect of oxidants upon outflow facility. In the present study the concentration of glutathione (GSH) was measured in excised calf trabecular meshwork (TM) and found to be 0.40 mu mol/g wet wt (0.027 mu mol/mg protein). Oxidized glutathione was not detectable in the tissue. TM was found to have significant hexose monophosphate shunt activity as determined by measurement of the oxidation of 14C-1 and 14C-6-labeled glucose in tissue homogenates. The concentration of GSH in TM of enucleated calf eyes could be totally depleted by infusion of medium containing both diamide, which is an oxidant of GSH, and 1,3bis(2-chlorethyl)-1-nitrosourea (BCNU), which is an inhibitor of the enzyme glutathione reductase. The depletion of GSH was found to have no effect on the facility of aqueous outflow. Experiments were also done in which normal and TM GSH-depleted eyes were perfused with medium containing H202. Exposure to H202 produced no effect on outflow facility in the normal eyes but caused a 33% decrease in facility in eyes with the GSH-depleted TM. The results indicate that GSH may not participate directly in regulating aqueous humor outflow but is able to protect TM against H202-induced oxidative damage that would otherwise lead to a decrease in outflow facility.

The effect of aqueous humor ascorbate on ultraviolet-B-induced DNA damage in lens epithelium.

PURPOSE: High levels of ascorbic acid are known to be present in the aqueous humor of many diurnal species, whereas nocturnal animals have low concentrations of the compound. The purpose of this study was to test the hypothesis that the high concentration of aqueous ascorbate in diurnal animals protects the lens against ultraviolet (UV)-induced damage to the eye. This study compares the effect of UV-B-induced DNA strand breaks on the lens epithelia of guinea pigs and rats after depletion or elevation of aqueous humor ascorbate, respectively. METHODS: Eyes of guinea pigs and rats were exposed to UV-B radiation (0.25-0.75 J/cm2 on the cornea) for 10 minutes, and DNA strand breaks in lens epithelium were measured by single-cell gel electrophoresis. Ascorbic acid concentration in the aqueous humor, lens, and lens-capsule epithelium were assayed by spectrophotometric and electrochemical methods. For depletion of aqueous humor and lens ascorbate in guinea pigs, the animals were maintained on an ascorbate-deficient diet. Aqueous ascorbic acid was elevated in the rat by intraperitoneal injections of sodium ascorbate (1 g/kg). RESULTS: The ascorbate concentration in the aqueous humor of the normal rat was approximately 3% that of the guinea pig, whereas the concentration of the compound in the lens of the normal rat was 10% that of the guinea pig. Guinea pigs fed an ascorbate-deficient diet showed a dramatic drop of more than 80% in aqueous humor ascorbate in the first week, whereas lens ascorbate decreased by approximately 25% during this time period. After a single intraperitoneal injection of sodium ascorbate in the rat, aqueous humor ascorbic acid increased nearly 30 times that in the control, whereas lens ascorbate increased by approximately 30%. The extent of DNA damage in the lens epithelium of a normal rat exposed to UV-B was significantly greater than that occurring in lenses of normal guinea pigs after exposure to the same dose of radiation. Lenses from ascorbate-deficient guinea pigs showed 50% more DNA damage than those from normal guinea pigs after UV exposure, whereas the lenses in ascorbate-injected rats exhibited significant protection against UV-induced DNA strand breaks. CONCLUSIONS: High levels of ascorbic acid in the aqueous humor had a protective effect against UV-induced DNA damage to lens epithelium. The results were consistent with the hypothesis that high ascorbic acid in diurnal animals protects the lens against the cataractogenic effect of UV radiation in sunlight.

Protein synthesis in x-irradiated rabbit lens.

The present study deals with the incorporation of 35S methionine into lens crystallins as a function of time after x-irradiation. Crystallin synthesis is first affected approximately 4 weeks following x-irradiation. This coincides with the time period at which the ratio of the two cations in the lens is affected, as shown in earlier studies. A greater decrease in 35S-methionine incorporation into crystallins is observed between 5-7 weeks following x-irradiation in good agreement with a cation imbalance at these time intervals. These studies also revealed for the first time that the change in cation distribution can affect not only crystallin synthesis, but also the synthesis of certain polypeptides of lens membranes. No alteration in protein synthesis could be detected in lens epithelium even after 7 weeks following irradiation. In addition to the effect of Na+ and K+ levels on protein synthesis, an impaired transport of amino acids into the x-rayed lens was also found to be a factor in the observed reduction in synthesis of the crystallin, cytoskeletal and membrane proteins of the fiber cells. It is concluded that Na+/K+ ratio as well as the availability of amino acids in the lens are important factors in protein synthesis of x-ray cataracts.

The role of glutathione metabolism in the detoxification of H2O2 in rabbit lens.

Aqueous humor is known to contain a significant level of H2O2, but the mechanisms by which ocular tissues protect against oxidative damage are not well understood. With the use of C-1-, C-2-, and C-6-labeled glucose, the contribution of glutathione (GSH) metabolism and the hexose monophosphate shunt (HMS) to the detoxification of peroxide in the lens has been evaluated. It was observed that H2O2 in the culture medium disappeared rapidly (0.5 mumol H2O2/lens/hr) upon incubation of a rabbit lens at 37 degrees C. At 0 degrees to 3 degrees C, however, the rate of disappearance of H2O2 was only one fifth of that observed at the higher temperature. In the absence of a lens or after pretreatment of the lens with methyl mercuric hydroxide, the rate of disappearance of peroxide from the medium was reduced to nearly zero. When a nearly constant level of H2O2 (0.05 to 0.07 mM) was maintained in the medium by means of a peristaltic pump, the amount of CO2 liberated by the HMS at 37 degrees C was found to be three times that liberated from lenses cultured in the absence of peroxide. No change was noted in the level of GSH in the H2O2-treated lenses at 37 degrees C. A significant decrease in GSH was observed, however, at 0 degrees to 3 degrees C, suggesting nonenzymatic oxidation of the tripeptide at the lower temperature. The results indicate that GSH metabolism and the HMS pathway contribute significantly to the detoxification of H2O2 in the lens.

Hydrogen peroxide affects specific epithelial subpopulations in cultured rabbit lenses.

PURPOSE: To investigate the effect of hydrogen peroxide on the epithelial cells of cultured rabbit lenses. METHODS: Lenses were cultured in minimum essential medium containing a single dose of 0.03, 0.1, or 0.2 mM H2O2. Three hours later the medium was replaced with peroxide-free minimum essential medium. Lenses were also treated with 0.5 mM 1,3-bis(2-chloroethyl)-1 nitrosourea (BCNU) to lower the activity of glutathione reductase and then exposed to 0.03 mM H2O2 maintained nearly constant by glucose oxidase. After H2O2 treatment, lenses were fixed and whole mounts of the epithelium were prepared or lenses were processed for electron microscopy. RESULTS: Cells exposed to a single dose of 0.03 mM H2O2 appeared normal; 0.1 mM H2O2 was not cytotoxic. Exposure to 0.2 mM H2O2 elicited swelling in cells in the pre-equatorial region (30 minutes) followed by the formation of islands of cells in the pre-equatorial region at 1 hour. Central epithelial cells appeared normal at 1 hour, were swollen at 3 hours and dead at 24 hours. By 48 hours, dead cells were found in the pre-equatorial and central regions. Cells in the peripheral region of the epithelium did not exhibit cytotoxicity. If lenses were pretreated with BCNU and then challenged with a maintained level of 0.03 mM H2O2, cytotoxicity was induced in the central and pre-equatorial regions. Cells in the peripheral region survived BCNU-H2O2 treatment. CONCLUSIONS: Cells in the peripheral region of cultured lenses were more resistant to H2O2 cytotoxicity than cells in the central and pre-equatorial regions. The antioxidant defense or repair systems for H2O2-induced damage do not appear to be uniformly distributed in subpopulations of the lens epithelium.

A protective role for glutathione-dependent reduction of dehydroascorbic acid in lens epithelium.

PURPOSE: In view of the antioxidant role of ascorbic acid and the glutathione redox cycle in the lens, the authors have studied the relationship of the cycle to reduction of the oxidized product of ascorbic acid, dehydroascorbic acid (DHA), in lens epithelium. METHODS: Cultured dog lens epithelial cells and intact rabbit lenses were exposed to various concentrations of DHA in experiments performed at 20 degrees C to minimize hydrolysis of the compound (t1/2 of 5 minutes at 37 degrees C). Levels of glutathione (GSH) and oxidized glutathione (GSSG) were measured in lens cells and whole lens epithelial by electrochemical detection. RESULTS: Treatment of lens cells with 1 mM DHA for 0.5 to 3 hours in the absence of glucose (glucose is required for the reduction of GSSG through the glutathione redox cycle) produced from 60% to complete oxidation of GSH (controls contained negligible GSSG) and distinct morphologic changes (cell contraction and blebbing), as shown by scanning electron microscopy. Glucose prevented these effects and allowed nearly immediate recovery of GSH after DHA exposure in the absence of glucose. A dose-dependent response was observed for the formation of GSSG in cultured cells from 0.05 to 0.5 mM DHA in the absence of glucose. The results of experiments performed with DHA plus an inhibitor of glutathione reductase mimicked those obtained using DHA minus glucose. DHA produced a 3- to 10-fold stimulation of hexose monophosphate shunt activity in cultured lens cells and whole lenses, which was prevented by the inhibition of glutathione reductase. Treatment of whole lenses with DHA minus glucose also produced oxidation of epithelial GSH and was accompanied by the loss of lens transparency. No evidence was found for dehydroascorbate reductase activity in the lens epithelium. CONCLUSIONS: The exposure of lenses and lens epithelial cells to DHA under conditions in which the glutathione redox cycle was compromised resulted in the disappearance of GSH in the tissues and the appearance of GSSG. The reduction of DHA was shown to be linked to the glutathione redox cycle by a nonenzymatic interaction between GSH and DHA. Reduction of DHA in the lens is important because of the potential toxicity of this oxidant and/or its degradation products.

Study of the polyol pathway and cell permeability changes in human lens and retinal pigment epithelium in tissue culture.

The polyol pathway was investigated in primary cultures of human retinal pigment epithelial (HRPE) cells and the results were compared with those in human lens epithelial (HLE) cells cultured under similar conditions. Significant levels of galactitol were formed in HRPE cells cultured for 72 hr in a medium containing 30 mmol/l D-galactose. Polyol accumulation was accompanied by the appearance of vacuoles as seen by transmission electron microscopy (TEM). Biochemical analysis revealed a significant depletion of cellular myoinositol, taurine, and a number of other free amino acids similar to those in HLE cells. These morphologic and biochemical changes observed in HRPE cells cultured in high galactose medium were inhibited or prevented by the inclusion of an aldose reductase inhibitor in the medium, further supporting the view that vacuole formation is due to the osmotic effect of polyol formation mediated by aldose reductase. The similarity of intracellular vacuole formation resulting from polyol accumulation and the biochemical changes in HRPE and HLE cells strongly suggests that a common mechanism is involved.

Phase separation of X-irradiated lenses of rabbit.

The phase separation temperature (Tcat) was studied as a function of time (age) after the administration of a single dose of radiation (2000 rad), which induces cataract in the rabbit lens. In the normal unirradiated lens, Tcat decreases linearly with age at a rate (DTcat/dt) approximately 2.2 degrees/week. In the irradiated lens, Tcat initially decreases with age much less than the normal lens, then rises sharply with age at the time of the appearance of opacity in the living rabbit eye. We suggest that the phase separation temperature may serve as a sensitive and early indicator of cataractogenic processes in the lens.

TEMPOL protects against lens DNA strand breaks and cataract in the x-rayed rabbit.

PURPOSE: To investigate the ability of the nitroxide free radical and superoxide dismutase mimic 4-hydroxy-2,2,6,6-tetramethylpiperidine-n-oxyl (TEMPOL) to protect against x-ray-induced lens DNA damage and cataract formation in the rabbit. METHODS: Eleven gray (Gy) x-rays was delivered twice, with a 48-hour interval, to the same eye of 5-week-old rabbits. Fifteen minutes before each x-ray, 150 microliters aqueous humor was removed from the anterior chamber and replaced with 150 microliters citrate buffer containing 0 mM or 100 mM TEMPOL. The development of cataract was classified into seven stages by slit-lamp examination. DNA strand breaks were measured in the lens epithelium of x-rayed rabbits using a single-cell gel electrophoresis method. RESULTS: The level of total TEMPOL in the aqueous humor of rabbits at 15 minutes after intracameral injection of the compound was 21 mM with 84% present in the oxidized form (determined by electron paramagnetic resonance spectroscopy). At 19 weeks after x-ray, rabbits irradiated without TEMPOL showed either stage 5 (complete posterior subcapsular opacity) or stage 6 (mature) cataracts, whereas the animals that had first been injected with TEMPOL developed only stage 2 to stage 4 cataracts (the difference between the two groups was significant at P < 0.01). Intracameral injection of TEMPOL resulted in a decrease of nearly 70% in the level of DNA strand breaks produced by a single 11-Gy dose of x-ray. In vitro studies showed that TEMPOL was reduced rapidly by ascorbic acid but not by reduced glutathione. Oxidized but not reduced TEMPOL (TEMPOL-H) was an effective radioprotector in cultured rabbit lenses, and TEMPOL was nearly completely bioreduced in the plasma and aqueous humor of animals that were fed the compound in drinking water. CONCLUSIONS: TEMPOL was effective in protecting against lens epithelial DNA damage and cataract formation in x-rayed rabbits. Although a number of mechanisms are possible, the protective effect may be associated with the ability of TEMPOL to protect against radiation-produced peroxides by acting as a superoxide dismutase mimic and to oxidize Fe2+ bound to DNA, thus preventing formation of the hydroxyl radical and subsequent DNA damage through the Haber-Weiss mechanism.

Impact of aging and hyperbaric oxygen in vivo on guinea pig lens lipids and nuclear light scatter.

PURPOSE: To measure lipid compositional and structural changes in lenses as a result of hyperbaric oxygen (HBO) treatment in vivo. HBO treatment in vivo has been shown to produce increased lens nuclear light scattering. METHODS: Guinea pigs, approximately 650 days old at death, were given 30 and 50 HBO treatments over 10- and 17-week periods, respectively, and the lenses were sectioned into equatorial, cortical, and nuclear regions. Lipid oxidation, composition, and structure were measured using infrared spectroscopy. Phospholipid composition was measured using (31)P-NMR spectroscopy. Data were compared with those obtained from lenses of 29- and 644-day-old untreated guinea pigs. RESULTS: The percentage of sphingolipid approximately doubled with increasing age (29-544 days old). Concomitant with an increase in sphingolipid was an increase in hydrocarbon chain saturation. The extent of normal lens lipid hydrocarbon chain order increased with age from the equatorial and cortical regions to the nucleus. These order data support the hypothesis that the degree of lipid hydrocarbon order is determined by the amount of lipid saturation, as regulated by the content of saturated sphingolipid. Products of lipid oxidation (including lipid hydroxyl, hydroperoxyl, and aldehydes) and lipid disorder increased only in the nuclear region of lenses after 30 HBO treatments, compared with control lenses. Enhanced oxidation correlated with the observed loss of transparency in the central region. HBO treatment in vivo appeared to accelerate age-related changes in lens lipid oxidation, particularly in the nucleus, which possesses less antioxidant capability. CONCLUSIONS: Oxidation could account for the lipid compositional changes that are observed to occur in the lens with age and cataract. Increased lipid oxidation and hydrocarbon chain disorder correlate with increased lens nuclear opacity in the in vivo HBO model.

AlphaB-crystallin in lens development and muscle integrity: a gene knockout approach.

PURPOSE: To study the role of alphaB-crystallin (alphaB) in the developing lens and its importance in lens structure and function. METHODS: Gene targeting in embryonic stem cells was used to generate mouse lines in which the alphaB gene and its protein product were absent. Gene structure and expression were characterized by genomic Southern blot, immunoblot, and Northern blot analyses, and two-dimensional gel electrophoresis. The gene knockout mice were screened for cataract with slit lamp biomicroscopy, and dissected lenses were examined with dark-field microscopy. Lenses and other tissues were analyzed by standard histology and immunohistochemistry. Chaperone activity was determined by heating lens homogenate supernatants and measuring absorbance changes. RESULTS: In an unexpected result, lenses in the alphaB gene knockout mice developed normally and were remarkably similar to wild-type mouse lenses. All the other crystallins were present. The thermal stability of a lens homogenate supernatant was mildly compromised, and when oxidatively stressed in vivo with hyperbaric oxygen, the knockout lenses reacted similarly to wild type. In targeting the alphaB gene, the adjacent HSPB2 gene, which is not expressed in the lens, was also disrupted. Loss of alphaB and/or HSPB2 function leads to degeneration of some skeletal muscles. CONCLUSIONS: AlphaB is not essential for normal development of a transparent lens in the mouse, and therefore is more dispensable to the lens than the closely related alphaA-crystallin. It may play a small role in maintaining transparency throughout life. alphaB and/or the closely related HSPB2 is required to maintain muscle cell integrity in some skeletal muscles.

Glutathione peroxidase-1 deficiency leads to increased nuclear light scattering, membrane damage, and cataract formation in gene-knockout mice.

PURPOSE: 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. METHODS: In vivo lens changes were monitored by slit lamp biomicroscopy, and enucleated lenses were examined under a stereomicroscope in gene-knockout animals and age-matched control animals ranging in age from 3 weeks to 18 months. Transmission (TEM) and confocal microscopy were performed on different regions of lenses after the mice were killed at various times. RESULTS: Slit lamp images showed an increase in nuclear light scattering (NLS) in gene-knockout mice compared with control animals. TEM revealed changes in the nucleus as early as 3 weeks of age by the appearance of waviness of fiber membranes. With increasing age, there was greater distortion of fiber membranes and distension of interfiber space at the apex of fiber cells compared with control mice. The changes in nuclear fiber membranes were even more dramatic, as observed by confocal microscopy, which was performed on thicker sections. In contrast to the changes in the lens nucleus, the morphology of the epithelium and superficial cortex remained unchanged in knockout animals during the same experimental period, consistent with slit lamp observations. Stereomicroscopy of ex vivo lenses demonstrated a significant increase in opacification in gene-knockout mice relative to control animals of the same age. This effect became evident in mice aged 5 to 9.9 months and persisted thereafter in older animals, resulting in mature cataracts after 15 months. CONCLUSIONS: The results demonstrate the critical role of GPX-1 in antioxidant defense mechanisms of the lens nucleus. The increased NLS appears to be associated with damage to fiber membranes in the nucleus, which is particularly susceptible to oxidative challenge because of the deficiency of GPX-1. It is suggested that the lens membrane changes in the knockout animals may be due to the formation of lipid peroxides, which serve as substrates for GPX-1. Cataract development in gene-knockout mice appeared to progress from focal opacities, apparent at an earlier age, to lamellar cataracts between 6 and 10 months, and finally to complete opacification in animals older than 15 months. This is the first reported phenotype in GPX-1-knockout mice.

Genes and susceptible loci of Alzheimer's disease.

Alzheimer's disease (AD) is the most common and devastating neurodegenerative disease of the elderly. Many research findings on familial AD suggest that the mechanisms of the pathogenesis of the disorder is more complex although the overall neuropathology of all cases of AD is surprisingly very similar. Genetic studies on some families have shown that mutations in the genes encoding beta-amyloid precursor protein and presenilins 1 and 2 are responsible for early-onset AD. In addition, apolipoprotein E gene allele E4 and the bleomycin hydrolase locus are shown to be genetic risk factors for late-onset AD in certain sporadic cases. Mitochondrial dysfunctions and age-related oxidative stress may also contribute to degenerative processes in AD. Although several studies support the amyloid cascade hypothesis as the mechanism of the disease, transgenic experiments and recent findings on a variant form of an AD family suggest that A beta deposition may not be sufficient to cause AD. Identification in the future of other genetic, environmental, and age-related factors, may provide additional targets for therapies.

The erythrocyte transport and transfer of methylmercury to the tissues of the rainbow trout (Salmo gairdneri).

Methylmercury (MeHg) was found to be taken up rapidly and almost completely by trout red blood cells (RBC) both in vitro and in vivo. The binding of MeHg within the RBC was freely reversible both in vitro, as shown by the efflux of MeHg from RBCs suspended in protein solutions, and in vivo following intracardial (i.c.) injection of RBC-bound MeHg. Hemoglobin (Hb) appeared to be the main MeHg transport protein in trout blood since it bound 90% of whole blood Hg following an intragastric dose of Me203HgCl. MeHg, injected i.c. as MeHgS-cysteine, was found to be present in blood bound almost completely to hemoglobin 10 days post-injection. This suggests an ability of hemoglobin to compete for and bind MeHg bound to other sulfhydryl (-SH) compounds. The number of reactive -SH groups per molecule of trout Hb was determined to be 4 by amperometric titration with MeHgCl. The concentration of Hb reactive -SH groups in the trout RBC was calculated to be at least 20 mM. This accounts for the high affinity of the RBC for MeHg.