Modelling cortical cataractogenesis. XXIX. Calpain proteolysis of lens fodrin in cataract

The relation between cataract and calpain proteolysis of lens fodrin was studied in two systems: elevated glucose (55.6 mM, diabetic model), and cytochalasin D (CD, 10(-2) mM, actin depolymerization-induced opacity model). Glucose treatment (48 h) caused a visible opaque layer and enzyme leakage, with a concomitant accumulation of ([Ca2+]i) around the lens equatorial cortex. CD caused both earlier and greater opacity and enzyme leakage than glucose. Lens fodrin digestion occurred in parallel with the timing and extent of calcium elevation. A calpain inhibitor peptide (CIP, 10(-2) mM) reduced the proteolysis of fodrin, opacity, and enzyme leakage in glucose-treated lenses but only partially retarded them in CD-treated lenses. These results suggest a mechanism in which calpain proteolysis of fodrin is a critical event in lens damage during opacification of cortical cataract.     

Antioxidants and cataract: (cataract induction in space environment and application to terrestrial aging cataract)

The effect of several antioxidants and cysteine-elevating precursor drugs (prodrugs) was tested on lens damage occurring after in vitro exposure to low levels of 60Co-gamma-irradiation, to simulate in vitro the exposure to radiation in vivo of (1) astronauts (2) jet crews (3) military radiation accident personnel. Tocopherol (100 microM), ascorbic acid (1 mM), R-alpha-lipoic acid (1 mM), and taurine (0.5 mM) protected against radiation-associated protein leakage. MTCA and ribocysteine protected lenses against opacification, LDH and protein leakage, indicating that antioxidants and prodrugs of cysteine appear to offer protection against lens damage caused by low level radiation.     

Physiological investigations by image analysis

Cataract formation in diabetic lenses has been attributed to polyol-osmotic pressure-generated influx of water. The ensuing swelling in the form of pocket and lake accumulations cause light scattering. The authors tested whether clear lenses of diabetic patients show different hydration properties than age matched normal lenses. Normal and diabetic human lenses were investigated for their nonfreezable water content by differential scanning calorimetry. The total water content of the lens sections were studied by thermogravimetric analysis. Non-cataractous diabetic lenses in all three regions showed a higher total water content than normal lenses. The nonfreezable water content, seems to increase with age in diabetic lenses and decrease with age in normal human lenses. Thus, hydration changes in human diabetic lenses precede cataract formation. While syneresis, the release of bound water into the bulk, is part of the normal aging process, it appears to occur in the younger diabetics only. In older diabetics syneresis is halted or even reversed. This may be due to the glycation of lens proteins in diabetic patients which tends to immobilize water and therefore, reverse the syneresis due to aging.     

Prevention of acetaminophen- and naphthalene-induced cataract and glutathione loss by CySSME

PURPOSES: To assess the efficacy of 2-mercaptoethanol/L-cysteine mixed disulfide (CySSME) as an L-cysteine prodrug suitable for glutathione biosynthesis in rat lenses in vitro, as an agent for the prevention of acetaminophen- and naphthalene-induced murine cataract in genetically-susceptible mice, and as an agent for maintenance of near-normal glutathione levels in lenses and livers of mice subjected to acetaminophen and naphthalene at cataractogenic doses. METHODS: Synthetic CySSME was added as a prodrug to rat lens culture medium devoid of L-cystine and L-methionine but containing [14C(U)]-glycine. After a 48-hour period of incubation, extracts of rat lenses were prepared for separation of [14C]-glutathione by high-performance liquid chromatography (HPLC) with a radioisotope detector to determine the extent of its biosynthesis. Cytochrome P-450 isozymes were induced in C57 bl/6 mice by either beta-naphthoflavone or phenobarbital. Cataracts were induced by administration of either acetaminophen or naphthalene to the pretreated mice. CySSME was coadministered with either acetaminophen or naphthalene to other groups of mice. Both oxidized and reduced glutathione were determined in extracts of livers and lenses using the HPLC method above. RESULTS: CySSME served as an effective L-cysteine precursor for glutathione biosynthesis in cultured rat lenses. This L-Cysteine prodrug was also highly effective in preventing acetaminophen- and naphthalene-induced cataract in mice and in maintaining near-normal glutathione levels in lenses and livers of such treated animals. CONCLUSIONS: This investigation demonstrates that maintenance of adequate physiological levels of glutathione in the presence of specific known cataractogenic agents by pharmacologic intervention with CySSME, an L-cysteine prodrug, is sufficient to prevent cataract formation.     

Lens epithelium: a primary target of UVB irradiation

Cultured rabbit lenses and cultured rabbit lens epithelial cells were irradiated with UV to correlate morphological changes in the epithelium with physiological changes in the whole lens during the development of UV-induced cataract. Two UV spectral ranges were utilized; one spanned 290 to 340 nm and was designated near-UV, the other was a narrower, pure UVB region: 303 to 313 nm, designated UVB. Irradiation with either spectrum of the anterior surface of whole lenses caused opacification and a dose-dependent loss of ion homeostasis as measured by Na+ and Ca2+ concentrations in whole lenses. It was determined that cation pump activity, assessed by 86Rb uptake, continued to decline steadily during culture after UV irradiation. Whole mount preparations of the epithelial cell layer of UVB-irradiated lenses revealed morphological changes within 2 hr of irradiation and cell death after 20 hr. Following posterior irradiation of whole lenses, the epithelial cells remained viable and lenses remained transparent during 3 days of culture, presumably because UV photons did not reach the epithelium. Absorption of UV photons by posterior fiber cell membranes and proteins did not cause opacification. To learn more about the epithelial damage, cultured rabbit lens epithelial cells were irradiated, UVB treatment retarded growth over a 7-day period in cultured cells. The surviving cells at day 7 were abnormal in appearance and the potassium concentration was approximately 50% less than controls, a finding which may explain the previously reported reduction in protein synthesis by UVB irradiation. Collectively, the data suggest that UV cataract is initiated by damage to the epithelium, including a change in membrane permeability leading to loss of ion homeostasis in the lens.     

Perspective on allogeneic melanoma lysates in active specific immunotherapy

PURPOSE: To compare calcium ionophore-induced cataract formation and in vitro light scattering in cultured lenses from guinea pig and rabbit. METHODS: Lenses from guinea pig and rabbit were cultured for 5 or 6 days with calcium ionophore A23187. To assess the involvement of calpain in cataract formation; SDS-PAGE, immunoblotting and calcium determinations were performed. For in vitro light scattering, lens soluble proteins from rabbit were hydrolyzed for 24 h by either endogenous lens calpain, or by addition of purified m-calpain and then further incubated for up to 10 days. Light scattering was measured daily at 405 nm. RESULTS: Lenses from younger guinea pigs cultured in A23187 first developed outer cortical opacities followed by nuclear cataract. Total calcium was markedly increased by A23187 in lenses of all ages. Proteolysis of crystallins and alpha-spectrin were observed in nuclear cataract in younger guinea pigs. This was attenuated with age, in association with the attenuation of cataract formation with age. Calpain 80 kDa subunit in the lenses cultured with A23187 was also decreased. Co-culture with SJA6017 or E64d (reversible and irreversible inhibitors of calpain, respectively) reduced A23187-induced nuclear opacities, proteolysis of crystallins and alpha-spectrin, and loss of calpain without affecting increased total calcium. In contrast, rabbit lenses cultured in A23187 did not develop nuclear cataract, although biochemical changes in cultured rabbit lenses were similar to those in cultured guinea pig lenses. Furthermore, no appreciable in vitro light scattering occurred in soluble proteins from rabbit lenses after activation of endogenous m-calpain, or after addition of exogenous purified m-calpain, although crystallins were partially hydrolyzed by calpain. CONCLUSIONS: Both rabbit and guinea pig lenses undergo calpain-induced proteolysis upon elevation of lenticular calcium. However, factors in intact guinea pig lenses may promote light scattering and insolubilization after proteolysis by calpain, but these factors were not functional in rabbit lenses. Discovery of the factors promoting light scatter and insolubilization after proteolysis will help to explain the role of certain crystallin polypeptides in cataract formation.     

Lens glutathione, lens protein glycation and electrophoretic patterns of lens proteins in STZ induced diabetic rats

As diabetes is a very complex disease, with the pathological symptoms varying with age, diabetic type and means of control, it still warrants many in vivo and in vitro studies. During hyperglycaemia, increases in the sorbitol pathway, nonenzymatic glycosylation of lens proteins and damage to antioxidant systems have been reported to cause opacification of the lens leading to cataract formation. In this study, intracapsular extracts of lenses from STZ induced diabetic female rats were examined. Total protein, glutathione and nonenzymatic glycosylation were determined by the Lowry, Ellman reagent and thiobarbituric acid methods respectively. Laemmli protein electrophoresis was also carried out on the lens homogenates. After a period of as short as 5 weeks, a decrease in lens glutathione, and an increase in nonenzymatic glycosylation of lens proteins were found. The electrophoresis showed an increase in proteins of high molecular weight.     

Ketamine and nifedipine protect cultured cortical neurons against injurious effect of glutamate]

The effects of glutamate on cultured cortical neurons and the protective effect of ketamine and nifedipine were studied. On day 10 after plating of the cortical cells from 16-18 day-old fetal rats, the cultures were exposed to 50 mumol.L-1 glutamate and low glucose (1 g.L-1) for 10 min-24 h. The results showed that a release of lactate dehydrogenase (LDH) into the culture supernatant was observed as a function of time. The values of LDH efflux in culture medium was significantly lower than those of controls when the cells were pretreated with ketamine or nifedipine 10 min prior to addition of glutamate. More significant decrease of LDH activity in culture medium was observed when the two drugs were used in combination. These results demonstrate that the dissociated cultured cortical neurons from fetal rat are seriously damaged by glutamate. Such damage could be attenuated by ketamine and nifedipine, suggesting that ketamine and nifedipine may protect neurons from the glutamate toxicity, and the effect of combining ketamine and nifedipine was greater than either ketamine or nifedipine alone.     

Calcium-induced changes on crystallins in organ-cultured porcine lens

In this study, intact porcine lenses were cultured in vitro for 7 days supplemented with commercial balanced salt solution (BSS) which is usually used as an irrigation solution during intraocular surgery, and the lenses were maintained under various culture conditions, e.g. temperature and CO2 concentration. The intact porcine lenses after 7 days culture were analyzed with optical density scanner, gel permeation chromatography on TSK HM-55 column and SDS-PAGE (polyacrylamide gel electrophoresis). It was found that lenses exhibited the least opacity when lenses were cultured with Ca(+2)-free BSS buffer, CO2-free incubator and maintained at a temperature of 25 degrees C. After the lenses were cultured with Ca(+2)-free BSS or BSS medium, the composition of crystallins in lenses was separated with TSK HM-55 column. It was indicated that the percentage of high molecular weight (HMW) protein and (alpha-crystallin increased, and gamma-crystallin decreased in lenses incubated with BSS medium compared with lenses incubated with Ca(+2)-free BSS medium. Following an increase in the concentration of calcium in the medium from 4.3 mM, 20 mM, 50 mM, 100 mM to 200 mM, the opacity of the lens was measured with a densitometer. The changed percentage of various crystallins was similar to lenses with BSS media that increased in HMW protein and alpha-crystallin, decreasing in gamma-crystallin. In the case of lens protein pattern, the crystallin washed from TSK HM-55 gel was separated with SDS-PAGE (polyacrylamide gel electrophoresis). It was indicated that some of proteins disappeared when lenses were incubated with various concentrations of calcium. The vanished pH proteins were 20.5 kDa at 50 mM calcium, 20.5 kDa and 21 kDa at 100 mM, 20.5 kDa, 21 kDa, 22 kDa and 23 kDa at 200 mM which were compared with the protein bands in the presence of 20 mM calcium in BSS medium. This study indicates that the commercial balanced salt solution (BSS) which is usually used as an irrigating solution during intraocular operations may increase the risk for lens opacity because of the calcium contained in the solution.     

Malonaldehyde, superoxide dismutase and human cataract

UV-spectrophotometry and fluorometry were used to study Malonaldehyde (MDA) and Superoxide Dismutase (SOD) in normal, cataractous human lenses and red blood cells of the patients with cataract. MDA content of senile and complicated cataractous lenses was significantly higher than that of normal human lenses, while that of complicated cataract was significantly higher than that of senile cataract. SOD activity of senile and complicated cataractous lenses was significantly lower than that of normal human lenses, while there was no marked difference between senile and complicated cataractous lenses. Significant correlation between cataractous lenses and red blood cells was not found in MDA content and SOD activity. There was a negative correlation between SOD and MDA in normal human lenses, but no correlation between SOD and MDA in cataractous lenses. The study shows that lipid peroxidation may be one of the possible mechanisms of cataractogenesis in human, and emphasizes the role of SOD in prevention of photoperoxidative damages to the tissues.     

Membrane damage and the Ca(2+)-paradox in the perfused rat kidney

Lactate dehydrogenase (LDH) leaks from the perfused rat kidney under the artificial conditions of a Ca(2+)-paradox protocol, namely Ca(2+)-repletion following a 20 minute period of Ca(2+)-depletion. LDH leakage was markedly suppressed by perfusion at 25 degrees C or with 0.1 mM dibucaine or 2 mM lidocaine. Lidocaine inhibited leakage only during Ca(2+)-depletion. Lowering the perfusion rate significantly reduced LDH escape. No LDH loss occurred if the osmotic pressure of the perfusion fluid was raised by 420 mOsm during either Ca(2+)-depletion or Ca(2+)-repletion. Amiloride (2 mM) significantly reduced LDH leakage to 43%. Reduction of the pH of the perfusion fluid to 6.8 significantly inhibited LDH loss, and at pH 6.4 this leakage was almost completely suppressed. LDH loss was equally suppressed at pH 6.4 only during Ca(2+)-depletion, whereas pH 6.4 was markedly less effective when perfused only during Ca(2+)-repletion. Ouabain (5 x 10(-6) M) had only a limited effect in exacerbating LDH leakage. Raising [K+]o significantly protected against LDH leakage, which fell to 36% at 16 mM [K+]. These features correspond with the Ca(2+)-paradox of the perfused rat heart an it is suggested that: (i) a Ca(2+)-paradox can be produced in the rat kidney; (ii) a similar mechanism governs the release of cytosolic proteins in these two preparations; and (iii) the damage mechanism of the plasmalemma is a transmembrane oxidoreductase-diaphorase molecular complex which generates H+ when activated by Ca(2+)-depletion.     

Thiolation of the gammaB-crystallins in intact bovine lens exposed to hydrogen peroxide

Oxidative damage of the lens causes disulfide bonds between cysteinyl residues of lens proteins and thiols such as glutathione and cysteine, which may lead to cataract. The effect of H2O2 oxidation was determined by comparing bovine lenses incubated with and without 30 mM H2O2. The H2O2 treatment decreased the glutathione and increased the protein-glutathione and protein-cysteine disulfides in the lens. The molecular mass of the gammaB-crystallin isolated from lenses, not treated with H2O2, agreed with the published sequence (Mr 20,966). Some lenses also had a less abundant gammaB-crystallin component 305 Da higher (Mr 21,270), suggesting the presence of a glutathione adduct. The gammaB-crystallins from H2O2 treated lenses had three components, the major one with one GSH adduct, another one with the mass of unmodified gammaB-crystallin, and a third with a mass consistent with addition of two GSH adducts. Mass spectrometric analysis of tryptic peptides of gammaB-crystallins from different lenses indicated that the +305 Da modifications were not at a specific cysteine. For the lenses incubated without H2O2, there was evidence of adducts at Cys-41 and in peptide 10-31, which includes 3 cysteines. Analysis of modified peptide 10-31 by tandem mass spectrometry showed GSH adducts at Cys-15, Cys-18, and Cys-22. In addition, gammaB-crystallins from H2O2-treated lenses had an adduct at Cys-109, partial oxidation at all 7 Met residues, and evidence for two disulfide bonds.     

Neuroprotective effects of NMDA receptor glycine recognition site antagonism: dependence on glycine concentration

High-affinity NMDA receptor glycine recognition site antagonists protect brain tissue from ischemic damage. The neuroprotective effect of 5-nitro-6,7-dichloro-2,3-quinoxalinedione (ACEA 1021), a selective NMDA receptor antagonist with nanomolar affinity for the glycine binding site, was examined in rat cortical mixed neuronal/glial cultures. ACEA 1021 alone did not alter spontaneous lactate dehydrogenase (LDH) release. Treatment with ACEA 1021 (0.1-10 microM) before 500 microM glutamate, 30 microM NMDA, or 300 microM kainate exposure was found to reduce LDH release in a concentration-dependent fashion. These effects were altered by adding glycine to the medium. Glycine (1 mM) partially reversed the effect of ACEA 1021 on kainate cytotoxicity. Glycine (100 microM-1 mM) completely blocked the effects of ACEA 1021 on glutamate and NMDA cytotoxicity. The glycine concentration that produced a half-maximal potentiation of excitotoxin-induced LDH release in the presence of 1.0 microM ACEA 1021 was similar for glutamate and NMDA (18 +/- 3 and 29 +/- 9 microM, respectively). ACEA 1021 also reduced kainate toxicity in cultures treated with MK-801. The effects of glycine and ACEA 1021 on glutamate-induced LDH release were consistent with a model of simple competitive interaction for the strychnine-insensitive NMDA receptor glycine recognition site, although nonspecific effects at the kainate receptor may be of lesser importance.     

Transcranial Doppler ultrasonography to evaluate need for cerebrospinal fluid drainage in hydrocephalic children

We measured the metabolic changes in aldose and phosphorus metabolites in rabbit lenses incubated with tissue culture medium 199 (TCM 199) containing 20 mM glucose-1-13C, using 13C, 31P-NMR Spectroscopy (13C, 31P-MRS). Then we investigated the effects of aldose reductase inhibitor (ARI) on those metabolic changes, using the same method. In the incubated rabbit lenses, rapid increases were recognized in sorbitol, sorbitol-3-phosphate, and alpha-glycerophosphate. The levels of glucose, lactate, and adenosin triphosphate (ATP) did not change significantly. Once ARI was added, the levels of sorbitol and sorbitol-3-phosphate were reduced immediately, but the reduction of alpha-glycerophosphate needed some time after the addition of ARI. On the other hand, the levels of lactate increased approximately two-fold, and the levels of glucose and ATP did not change significantly. Considered with our other observations on the metabolic changes in alloxan induced diabetic rabbit lenses, and in rabbit lenses incubated with high concentrations (5-40 mM) of glucose-TCM 199 or 20 mM galactose-TCM 199, these results suggest that aldose reductase not only activates the polyol pathway but also controls the Embden-Meyerhof pathway, energetic metabolic changes, or phospholipid-associated metabolic changes.     

Human age-related cataract and lens epithelial cell death

PURPOSE: To evaluate the importance of lens epithelial cell death in age-related cataract. To determine whether the large percentage of terminal deoxynucleotidyl transferase (TdT)-mediated dUTP nick-end labeling (TUNEL)-positive lens epithelial cells previously reported in human capsulotomy specimens results from apoptosis or necrosis. METHODS: Capsulotomy specimens from patients who had undergone cataract surgery and epithelia from cataractous lenses of eye bank eyes were compared with epithelia from noncataractous lenses of eye bank eyes. DNA fragmentation was assayed using the TUNEL method. Cell membrane integrity was tested using a fluorescent stain for DNA, BOBO-3, that is excluded from living cells. Cell proliferation was assayed by labeling with 5-bromo-2'-deoxyuridine (BrdU). The number of cells in different regions of the lens epithelium was measured by digital imaging and computerized counting of nuclei after staining with methyl green. RESULTS: TUNEL-positive cells were sometimes detected adjacent to denuded regions of capsulotomy specimens, especially when epithelia were not fixed immediately after surgery. TUNEL-stained cells usually stained with BOBO-3, indicating loss of plasma membrane integrity. No BrdU-labeled cells were detected in capsulotomy specimens. Cell density in cataractous lens epithelia was similar to that in normal lens epithelia. In cataractous lenses from eye bank eyes, cell density in the region of the epithelium overlying the cataract was higher than cell density in the region of the epithelium overlying the transparent part of the lens. No correlation was found between cell density and cataract severity or between cell density and age. CONCLUSIONS: TUNEL staining of lens epithelial cells in capsulotomy specimens most likely results from necrotic cell death caused by damage during or soon after cataract surgery. Loss of cells from the lens epithelium, by apoptosis or other mechanisms of cell death, does not seem to play a major role in age-related cataract formation.     

Stabilization of lactate dehydrogenase following freeze thawing and vacuum-drying in the presence of trehalose and borate

PURPOSE: The purpose of this work was to investigate the effects of trehalose and trehalose/sodium tetraborate mixtures on recovery of lactate dehydrogenase (LDH) activity following freeze-thawing and centrifugal vacuum-drying/rehydration. The storage stability of LDH under conditions of either high relative humidity or high temperature was also studied. METHODS: LDH was prepared in buffered aqueous formulations containing trehalose alone and trehalose/"borate" mixtures. Enzymatic activity was measured immediately following freeze-thawing and vacuum-drying/rehydration processes, and also after vacuum-dried formulations were stored in either high humidity or high temperature environments. Also, glass transition temperatures (Tg) were measured for both freeze-dried and vacuum-dried formulations. RESULTS: The Tg values of freeze-dried trehalose/borate mixtures are considerably higher than that of trehalose alone. Freezing and vacuum-drying LDH in the presence of 300 mM trehalose resulted in the recovery of 80% and 65% of the original activity, respectively. For vacuum-dried mixtures, boron concentrations below 1.2 mole boron/ mole trehalose had no effect on recovered LDH. After several weeks storage in either humid (100% relative humidity) or warm (45 degrees C) environments, vacuum-dried formulations that included trehalose and borate showed greater enzymatic activities than those prepared with trehalose alone. We attribute this stability to the formation of a chemical complex between trehalose and borate. CONCLUSIONS: The high Tg values of trehalose/borate mixtures offer several advantages over the use of trehalose alone. Most notable is the storage stability under conditions of high temperature and high relative humidity. In these cases, formulations that contain trehalose and borate are superior to those containing trehalose alone. These results have practical implications for long-term storage of biological materials.     

The oxidative stress in the cataract formation

The lens of the eye is an avascular tissue surrounded by fluids such as the aqueous humor and vitreous body, with one side facing toward the outside of the body. We investigated peroxidative reactions occurring in cataractous lenses, examining changes within the lens tissues as well as in the surrounding environment. 1. Peroxidative reactions in lenses. 1) Aging and peroxidative reactions. The activity of superoxide dismutase (SOD) began to decrease in the lenses of rats at six months of age. Moreover, the level of lipid peroxide increased significantly in the lenses of rats at 24 months of age. Lipoproteins became increasingly oxidized with age. The levels of Na+, K+, and Ca++, ions that are important to the maintenance of membrane function, also varied significantly with age. In the lenses of six-month-old Senescence Accelerated Mice (SAM), there was a marked decrease in the ability of scavenge active oxygen and a marked increase in the amount of lipid peroxide. In human lenses, the level of autofluorescence increased as the lens fiber structure changed with age. 2) Generation of free radicals inside the lens. We verified that HO. and ascorbic acid radicals were being generated inside cataractous lenses using electron spin resonance (ESR). 3) Changes in oxidation-related substances in cataractous lenses. Senile cataractous lenses and diabetic cataractous lenses were classified as four types, cortical, nuclear, posterior subcapsular, and mature. In cataractous lenses from all types of diabetic patients, the levels of glucose, glycated protein, and lipid peroxide were higher than in senile cataractous lenses. Among the four types of cataracts, the accumulation of peroxides was the greatest in the nuclear type both diabetic and senile cataractous lenses. 4) Transitional metals. Iron ions and copper ions existed in lens tissue. In particular, the subepithelial region of the lens stained strongly for copper ions. The increased level of copper ions in cataractous lenses is likely to be related to the increased peroxidation in this tissue. 5) Changes in membrane. Lowered levels of phospholipids and a higher degree of saturation of fatty acids were observed in senile cataractous lenses as compared with normal lenses. The increased saturation of fatty acids indicated that there was a damage to the membrane structure due to peroxidative reactions. The receptors for low density lipoprotein (LDL) were shown to exist on the epithelium of normal lenses. Acetyl-LDL, a denatured lipoprotein was incorporated into senile cataractous lenses but not into normal lenses, suggesting that the barrier function of the membrane deteriorates in cataractous lenses. Moreover, in diabetic cataractous lenses, the levels of very low density lipoprotein (VLDL) and LDL significantly increased. 2. Change in the environment surrounding the lens and peroxidative reactions. 1) Changes in the levels of oxidation-related substances in blood, aqueous humor, and vitreous body from diabetic patients: all had decreased levels of reduced glutathione and superoxide scavenging activity, and increased levels of lipid peroxide and glycated protein. This may have been due to a reduction in the anti-oxidative potential in the environment surrounding the lens due to the enhanced glycation. Changes in the level of oxidation related substances in the vitreous body in particular, will likely have a significant impact on the lens. 2) Changes in lenses as the surrounding environment deteriorates. Human lenses were cultured for three weeks under conditions similar to those found in vivo utilizing the culture system that we had originally designed and constructed. When protective activity against peroxidation was reduced, the amount of lipid peroxide increased significantly. In the presence of high levels of glucose, the levels of lipid peroxide increased and the amount and activity of SOD decreased. 3. Effects of changes in the external environment on peroxidative reactions.     

Kinetic parameters of lactate dehydrogenase in liver and gastrocnemius determined by three quantitative histochemical methods

We determined the Michaelis constant (K(m)) and maximal velocity (Vmax) of lactate dehydrogenase (LDH) in periportal hepatocytes and skeletal muscle fibers by three different histochemical assay methods. Unfixed sections of mouse liver and gastrocnemius were incubated at 37C either on substrate (L-lactate)-containing agarose gel films or in aqueous assay media with and without 18% polyvinyl alcohol (PVA) as a tissue protectant. The absorbances of the formazan final reaction products were continuously measured at 584 nm in the cytoplasm of individual cells as a function of incubation time, using an image analysis system. The kinetic parameters of purified rabbit skeletal muscle LDH incorporated into polyacrylamide gel sections were similarly determined. The intrinsic initial velocities (vi) of LDH, corrected for "nothing dehydrogenase," were determined as described in the previous article. The Km and Vmax were calculated from Hanes plots of s/vi on L-lactate concentration (s). The Km values obtained with three assay methods were similar and in the range of 21.1-21.9 mM for pure LDH, 8.62-13.5 mM for LDH in mouse periportal hepatocytes, and 13.3-17.9 mM for LDH in mouse skeletal muscle fibers. The Vmax values determined on agarose gel substrate films and in aqueous assay media without PVA were in good agreement but were 53-65% lower when 18% PVA was included in the medium. These results indicate that catalytic center activity kcat of LDH is retarded by the high viscosity of PVA media because PVA hardly inhibited the enzyme. The K(m) values of LDH determined histochemically in skeletal muscle fibers and periportal hepatocytes were respectively three to five times and two to three times higher than those determined biochemically. These differences may be due to interactions of LDH with intracellular components.     

Role of small GTP-binding proteins in lovastatin-induced cataracts

PURPOSE: To investigate the biochemical mechanisms involved in the cataract induced by lovastatin, a commonly used cholesterol-lowering agent. METHODS: The effects of lovastatin on lens transparency and on lens epithelial cell proliferation and structure have been investigated using organ-cultured rat lenses and cultured epithelial cells from human and rabbit lenses, respectively. Lens histologic and morphologic changes were recorded microscopically. Small GTP-binding protein profiles were determined by [alpha-32P] GTP overlay assays. RESULTS: Rat lenses organ cultured for 7 days with lovastatin, a 3-hydroxy-3-methylglutaryl CoA reductase inhibitor, developed frank subcapsular opacity. Lens epithelial cells (both human and rabbit) demonstrated extensive morphologic changes and inhibition of proliferation when treated with lovastatin. Histologic sections of lovastatin-treated lenses showed partial to complete degeneration of the central epithelium, distortion of elongating epithelial cells, and extensive vacuole formation in the equatorial regions of the cortex. Supplementation of the medium with DL-mevalonic acid (a precursor of isoprenoids whose synthesis is inhibited by lovastatin) prevented the lovastatin-induced changes in whole lenses or in lens epithelial cell cultures, whereas supplementation with cholesterol had no such effect. GTP-binding proteins accumulated in the soluble fractions of lovastatin-treated lens epithelial cells. This was consistent with a blockade in isoprenylation preventing normal association with membranes. CONCLUSIONS: The findings suggest that impairment of the function of small GTP-binding proteins, due to a lovastatin-induced blockade in their isoprenylation, affects lens cell structure and proliferation in tissue culture and induces lens opacity in organ culture. These findings are consistent with the proposed roles of small GTP-binding proteins as molecular switches that regulate fundamental cellular processes, including growth, differentiation, and maintenance of cell structure.