Glutathione and the redox control system trypanothione/trypanothione reductase are involved in the protection of Leishmania spp. against nitrosothiol-induced cytotoxicity

Glutathione is the major intracellular antioxidant thiol protecting mammalian cells against oxidative stress induced by oxygen- and nitrogen-derived reactive species. In trypanosomes and leishmanias, trypanothione plays a central role in parasite protection against mammalian host defence systems by recycling trypanothione disulphide by the enzyme trypanothione reductase. Although Kinetoplastida parasites lack glutathione reductase, they maintain significant levels of glutathione. The aim of this study was to use Leishmania donovani trypanothione reductase gene mutant clones and different Leishmania species to examine the role of these two individual thiol systems in the protection mechanism against S-nitroso-N-acetyl-D,L-penicillamine (SNAP), a nitrogen-derived reactive species donor. We found that the resistance to SNAP of different species of Leishmania was inversely correlated with their glutathione concentration but not with their total low-molecular weight thiol content (about 0.18 nmol/10(7) parasites, regardless Leishmania species). The glutathione concentration in L. amazonensis, L. donovani, L. major, and L. braziliensis were 0.12, 0.10, 0.08, and 0.04 nmol/10(7) parasites, respectively. L. amazonensis, that have a higher level of glutathione, were less susceptible to SNAP (30 and 100 µM). The IC50 values of SNAP determined to L. amazonensis, L. donovani, L. major, and L. braziliensis were 207.8, 188.5, 160.9, and 83 µM, respectively. We also observed that L. donovani mutants carrying only one trypanothione reductase allele had a decreased capacity to survive (40 percent) in the presence of SNAP (30-150 µM). In conclusion, the present data suggest that both antioxidant systems, glutathione and trypanothione/trypanothione reductase, participate in protection of Leishmania against the toxic effect of nitrogen-derived reactive species.

Glutathione and the redox control system trypanothione/trypanothione reductase are involved in the protection of Leishmania spp. against nitrosothiol-induced cytotoxicity.

Glutathione is the major intracellular antioxidant thiol protecting mammalian cells against oxidative stress induced by oxygen- and nitrogen-derived reactive species. In trypanosomes and leishmanias, trypanothione plays a central role in parasite protection against mammalian host defence systems by recycling trypanothione disulphide by the enzyme trypanothione reductase. Although Kinetoplastida parasites lack glutathione reductase, they maintain significant levels of glutathione. The aim of this study was to use Leishmania donovani trypanothione reductase gene mutant clones and different Leishmania species to examine the role of these two individual thiol systems in the protection mechanism against S-nitroso-N-acetyl-D,L-penicillamine (SNAP), a nitrogen-derived reactive species donor. We found that the resistance to SNAP of different species of Leishmania was inversely correlated with their glutathione concentration but not with their total low-molecular weight thiol content (about 0.18 nmol/10(7) parasites, regardless Leishmania species). The glutathione concentration in L. amazonensis, L. donovani, L. major, and L. braziliensis were 0.12, 0.10, 0.08, and 0.04 nmol/10(7) parasites, respectively. L. amazonensis, that have a higher level of glutathione, were less susceptible to SNAP (30 and 100 microM). The IC50 values of SNAP determined to L. amazonensis, L. donovani, L. major, and L. braziliensis were 207.8, 188.5, 160.9, and 83 microM, respectively. We also observed that L. donovani mutants carrying only one trypanothione reductase allele had a decreased capacity to survive (approximately 40%) in the presence of SNAP (30-150 microM). In conclusion, the present data suggest that both antioxidant systems, glutathione and trypanothione/trypanothione reductase, participate in protection of Leishmania against the toxic effect of nitrogen-derived reactive species.

Mitochondrial superoxide production during oxalate-mediated oxidative stress in renal epithelial cells.

Crystals of calcium oxalate monohydrate (COM) in the renal tubule form the basis of most kidney stones. Tubular dysfunction resulting from COM-cell interactions occurs by mechanism(s) that are incompletely understood. We examined the production of reactive oxygen intermediates (ROI) by proximal (LLC-PK1) and distal (MDCK) tubular epithelial cells after treatment with COM (25-250 microg/ml) to determine whether ROI, specifically superoxide (O(2)(*-)), production was activated, and whether it was sufficient to induce oxidative stress. Employing inhibitors of cytosolic and mitochondrial systems, the source of ROI production was investigated. In addition, intracellular glutathione (total and oxidized), energy status (ATP), and NADH were measured. COM treatment for 1-24 h increased O(2)(*-) production 3-6-fold as measured by both lucigenin chemiluminescence in permeabilized cells and dihydrorhodamine fluorescence in intact cells. Using selective inhibitors we found no evidence of cytosolic production. The use of mitochondrial probes, substrates, and inhibitors indicated that increased O(2)(*-) production originated from mitochondria. Treatment with COM decreased glutathione (total and redox state), indicating a sustained oxidative insult. An increase in NADH in COM-treated cells suggested this cofactor could be responsible for elevating O(2)(*-) generation. In conclusion, COM increased mitochondrial O(2)(*-) production by epithelial cells, with a subsequent depletion of antioxidant status. These changes may contribute to the reported cellular transformations during the development of renal calculi.

Uremic concentrations of guanidino compounds inhibit neutrophil superoxide production.

BACKGROUND: In uremia, diminished reactive oxygen intermediate (ROI) production is an important consequence of impaired neutrophil function. We have studied the effect of guanidino compounds, known uremic toxins, on neutrophil ROI production in vitro. METHODS: Neutrophils from healthy volunteers were exposed for three hours to individual or mixed guanidino compounds (GCmix) at concentrations encountered in uremic plasma. After removal of guanidino compounds, neutrophils were activated by adhesion, N-formyl-methionyl-leucyl-phenyalanine (fMLP), phorbol 12-myristate 13-acetate (PMA), or opsonized zymosan, and superoxide production was measured by lucigenin chemiluminescence (CL). The direct effect of guanidino compounds on superoxide production in activated neutrophils was also measured. The energy status (ATP and creatine phosphate), antioxidant status (total glutathione), and glycolytic flux (lactate production) were measured. RESULTS: The GCmix pretreatment decreased the superoxide production in activated neutrophils (fMLP or zymosan) by 50% (P < 0.01) and the ATP concentration by 60% (P < 0.05), and it inhibited glycolytic flux (lactate production) by 45% (P < 0.01), but did not alter glutathione concentration. Simultaneous exposure to GCmix and activation did not inhibit nicotinamide adenine dinucleotide phosphate (NADPH) oxidase activity in cell lysates, but inhibited superoxide formation in zymosan-activated intact neutrophils, and this inhibition was reversed following removal of the guanidino compounds. CONCLUSION: Guanidino-succinate, -propionate, and -butyrate were individually as potent as the GCmix. Inhibition of neutrophil superoxide generation by guanidino compounds results from a depressed energy status. Uremic concentrations of guanidino compounds significantly inhibit neutrophil metabolism, and this has serious implications for their function in host defense.

Glutathione protects macrophages and Leishmania major against nitric oxide-mediated cytotoxicity.

The aim of this investigation was to examine whether macrophage and Leishmania major glutathione were involved in either host or parasite protection against NO cytotoxicity. Buthionine sulfoximine (BSO), an inhibitor of gamma-glutamylcysteine synthase, caused a complete and irreversible depletion of macrophage glutathione, but only a 20% and reversible decrease in L. major glutathione. Glutathione-depleted macrophages, when activated with IFN-gamma/LPS, released less than 60% of the NO produced by untreated macrophages, resulting in a corresponding decrease in their leishmanicidal activity. BSO-treated macrophages were more susceptible to the cytotoxic effects of the NO donor SNAP. Treatment of macrophages with 1,3-bis(chloroethyl)-1-nitrosourea (BCNU), an inhibitor of glutathione reductase and trypanothione reductase or with Br-Octane, a glutathione-S-transferase substrate, resulted in a transient decrease in glutathione levels and did not increase the susceptibility of the macrophages to SNAP. Treatment of the promastigote forms of L. major with BCNU resulted in an 80% decrease in total glutathione concentration with no concomitant change in viability. However, this treatment rendered the parasites more susceptible to SNAP. Finally, macrophage glutathione protected the internalized L. major from SNAP. Overall, these results demonstrate that glutathione is an essential protective component against NO cytotoxicity on both macrophages and parasites.

S-nitrosothiols are stored by platelets and released during platelet-neutrophil interactions.

Interaction between platelets and neutrophils is important in vascular injury. We have investigated the storage and release of nitric oxide (NO) by platelets interacting with neutrophils. Shear-activated platelets were added to neutrophils in suspension and both superoxide and peroxynitrite formations monitored by lucigenin- and luminol-enhanced chemiluminescence. In addition, intraplatelet S-nitrosothiols were measured by dichlorofluorescein fluorescence following displacement of NO by mercuric chloride. Addition of activated platelets to neutrophils caused free radical production and platelet-neutrophil rosette formation. Pretreatment of platelets with 20 microM S-nitrosoglutathione changed the balance between luminol and lucigenin chemiluminescence in favor of luminol, whereas S-nitrosoglutathione in platelet-free plasma did not produce these changes. This pattern was also observed both following inhibition of neutrophil NO synthase and in a neutrophil-free superoxide-generating system. Inhibition of platelet NO synthase decreased luminol and increased lucigenin chemiluminescence. These effects were reversed by L-arginine. Platelet activation increased intraplatelet S-nitrosothiols from 1.93+/-0.19 (mean +/- SD) to 4.9+/-1.10 x 10(-18) mol/platelet (P < 0.01); this increase halved following NO synthase inhibition, but was enhanced by approximately 220% following incubation with S-nitrosoglutathione. These results show that during shear stress platelets store S-nitrosothiols, which can be derived either endogenously from NO synthesis or exogenously by sequestration of S-nitrosoglutathione. Release of stored NO during platelet-neutrophil interaction alters the interaction of NO with superoxide and could modulate vascular inflammation.

Inhibition of NADPH supply by 6-aminonicotinamide: effect on glutathione, nitric oxide and superoxide in J774 cells.

We have examined the integrity of J774 cell nitric oxide (NO) production and glutathione maintenance, whilst NADPH supply was compromised by inhibition of the pentose pathway with 6-aminonicotinamide. In resting cells 6-phosphogluconate accumulation began after 4 h and glutathione depletion after 24 h of 6-aminonicotinamide treatment. Cellular activation by lipopolysaccharide/interferon-lambda decreased glutathione by approximately 50% and synchronous 6-aminonicotinamide treatment exacerbated this to 31.2% of control (P < 0.05). In activated cells NO2- production was inhibited by 60% with 6-aminonicotinamide (P < 0.01), and superoxide production by 50% (P < 0.01) in zymosan-activated cells. NADPH production via the pentose pathway is therefore important to sustain macrophage NO production whilst maintaining protective levels of glutathione.

Evidence for a cyclic GMP-independent mechanism in the anti-platelet action of S-nitrosoglutathione.

1. We have measured the ability of a range of NO donor compounds to stimulate cyclic GMP accumulation and inhibit collagen-induced aggregation of human washed platelets. In addition, the rate of spontaneous release of NO from each donor has been measured spectrophotometrically by the oxidation of oxyhaemoglobin to methaemoglobin. The NO donors used were five s-nitrosothiol compounds: S-nitrosoglutathione (GSNO), S-nitrosocysteine (cysNO), S-nitroso-N-acetyl-DL-penicillamine (SNAP), S-nitroso-N-acetyl-cysteine (SNAC), S-nitrosohomocysteine (homocysNO), and two non-nitrosothiol compounds: diethylamine NONOate (DEANO) and sodium nitroprusside (SNP). 2. Using 10 microM of each donor compound, mean+/-s.e.mean rate of NO release ranged from 0.04+/-0.001 nmol min(-1) (for SNP) to 3.15+/-0.29 nmol min(-1) (for cysNO); cyclic GMP accumulation ranged from 0.43+/-0.05 pmol per 10(8) platelets (for SNP) to 2.67+/-0.31 pmol per 10(8) platelets (for cysNO), and inhibition of platelet aggregation ranged from 40+/-6.4% (for SNP) to 90+/-3.8% (for SNAC). 3. There was a significant positive correlation between the rate of NO release and the ability of the different NO donors to stimulate intra-platelet cyclic GMP accumulation (r = 0.83; P = 0.02). However, no significant correlation was observed between the rate of NO release and the inhibition of platelet aggregation by the different NO donors (r= -0.17), nor was there a significant correlation between cyclic GMP accumulation and inhibition of aggregation by the different NO donor compounds (r = 0.34). 4. Comparison of the dose-response curves obtained with GSNO, DEANO and 8-bromo cyclic GMP showed DEANO to be the most potent stimulator of intraplatelet cyclic GMP accumulation (P < 0.001 vs both GSNO and 8-bromo cyclic GMP), but GSNO to be the most potent inhibitor of platelet aggregation (P < 0.01 vs DEANO, and P < 0.001 vs 8-bromo cyclic GMP). 5. The rate of NO release from GSNO, and its ability both to stimulate intra-platelet cyclic GMP accumulation and to inhibit platelet aggregation, were all significantly diminished by the copper (I) (Cu+) chelating agent bathocuproine disulphonic acid (BCS). In contrast, BCS had no effect on either the rate of NO release, or the anti-platelet action of the non-nitrosothiol compound DEANO. 6. Cyclic GMP accumulation in response to GSNO (10(-9) 10(-5) M) was undetectable following treatment of platelets with ODQ (100 microM), a selective inhibitor of soluble guanylate cyclase. Despite this abolition of guanylate cyclase stimulation, GSNO retained some ability to inhibit aggregation, indicating the presence of a cyclic GMP-independent component in its anti-platelet action. However, this component was abolished following treatment of platelets with a combination of both ODQ and BCS, suggesting that Cu+ ions were required for the cyclic GMP-independent pathway to operate. 7. The cyclic GMP-independent action of GSNO, observed in ODQ-treated platelets, could not be explained by an increase in intra-platelet cyclic AMP. 8. The impermeable thiol modifying agent p-chloromercuriphenylsulphonic acid (CMPS) produced a concentration-dependent inhibition of aggregation of ODQ-treated platelets, accompanied by a progressive loss of detectable platelet surface thiol groups. Additional treatment with GSNO failed to increase the degree of aggregation inhibition, suggesting that a common pathway of thiol modification might be utilized by both GSNO and CMPS to elicit cyclic GMP-independent inhibition of platelet aggregation. 9. We conclude that NO donor compounds mediate inhibition of platelet aggregation by both cyclic GMP-dependent and -independent pathways. Cyclic GMP generation is related to the rate of spontaneous release of NO from the donor compound, but transfer of the NO signal to the cyclic GMP-independent pathway may depend upon a cellular system which involves both copper (I) (Cu+) ions and surface membrane thiol groups. The potent anti-platelet action of GSNO

Cell-mediated biotransformation of S-nitrosoglutathione.

Spontaneous release of nitric oxide (NO) from S-nitrosothiols cannot explain their bioactivity, suggesting a role for cellular metabolism or receptors. Using immortalised cells and human platelets, we have identified a cell-mediated mechanism for the biotransformation of the physiological S-nitrosothiol compound S-nitrosoglutathione (GSNO) into nitrite. We suggest the name "GSNO lyase" for this activity. GSNO lyase activity varied between cell types, being highest in a fibroblast cell line and lowest in platelets. In NRK 49F fibroblasts, GSNO lyase mediated a saturable, GSNO concentration-dependent accumulation of nitrite in conditioned medium, which was inhibited both by transition metal chelators, and by subjecting cells to oxidative stress using a combination of the thiol oxidant diamide and Zn2+, a glutathione reductase inhibitor. Activity was resistant, however, to both acivicin, an inhibitor of gamma-glutamyl transpeptidase (EC 2.3.2.2), and to ethacrynic acid, an inhibitor of Pi class glutathione-S-transferases (EC 2.5.1.18), thus neither of these enzymes could account for NO release. Although GSNO lyase does not explain the platelet-selective pharmacological properties of GSNO, cellular biotransformation suggests therapeutic avenues for targeted delivery of NO to other tissues.

Nature and biological significance of free radicals generated during bicarbonate hemodialysis.

This study investigates evidence of oxidative stress during bicarbonate hemodialysis by measuring total glutathione and lipid peroxidation products in plasma, and characterizes the free radicals produced by neutrophils from healthy volunteers when incubated in vitro with increasing concentrations of bicarbonate. Blood samples were taken from nine hemodialysis patients before and after two hemodialysis sessions. Plasma hydroperoxides and total glutathione were measured. A significant increase was found in total glutathione (1.04 +/- 0.4 versus 2.11 +/- 0.9 microM, P < 0.001) and hydroperoxides by ferrous oxidation in xylenol orange version 2 method (4.6 +/- 0.53 versus 6.4 +/- 0.63 microM, P < 0.001) after hemodialysis, which indicated increased oxidative injury during hemodialysis. Normal neutrophils, activated by contact adhesion, produced a dose-dependent increase in free radical production (measured by luminol-enhanced chemiluminescence) when incubated with increasing concentrations of bicarbonate (up to 35 mM). Bicarbonate had the same effect on the chemiluminescence of a cell-free hypoxanthine/acetaldehyde system generating superoxide, but not on a glucose oxidase/myeloperoxidase system generating hydrogen peroxide and hypochlorous acid. These findings are consistent with (1) the hypothesis that superoxide generated during hemodialysis reacts with bicarbonate to form the toxic carbonate and formate radicals and (2) our previous observation that some patients undergoing bicarbonate (but not lactate) dialysis have increased plasma concentrations of formate after hemodialysis. It is suggested that the increased plasma total glutathione and hydroperoxide concentrations are a result of lipid peroxidation by these species. These reactive radicals can initiate lipid peroxidation and contribute to the cardiovascular complications of hemodialysis patients.

Induction of nitric oxide synthesis in J774 cells lowers intracellular glutathione: effect of modulated glutathione redox status on nitric oxide synthase induction.

Under pathological conditions, the induction of nitric oxide synthase (NOS) in macrophages is responsible for NO production to a cytotoxic concentration. We have investigated changes to, and the role of, intracellular glutathione in NO production by the activated murine macrophage cell line J774. Total glutathione concentrations (reduced, GSH, plus the disulphide, GSSG) were decreased to 45% of the control 48 h after cells were activated with bacterial lipopolysaccharide plus interferon gamma. This was accompanied by a decrease in the GSH/GSSG ratio from 12:1 to 2:1. The intracellular decrease was not accounted for by either GSH or GSSG efflux; on the contrary, rapid export of glutathione in control cells was abrogated during activation. The loss of intra- and extracellular glutathione indicates either a decrease in synthesis de novo, or an increase in utilization, rather than competition for available NADPH. All changes in activated cells were prevented by pretreatment with the NOS inhibitor L-N-(1-iminoethyl)ornithine. Basal glutathione levels in J774 cells were manipulated by pretreatment with (1) buthionine sulphoximine (glutathione synthase inhibitor), (2) acivicin (gamma-glutamyltranspeptidase inhibitor), (3) bromo-octane (glutathione S-transferase substrate) and (4) diamide/zinc (thiol oxidant and glutathione reductase inhibitor). All treatments significantly decreased the output of NO following activation. The degree of inhibition was dependent on (i) duration of treatment prior to activation, (ii) rate of depletion or subsequent recovery and (iii) thiol end product. The level of GSH did not significantly affect the production of NO, after induction of NOS. Thus, glutathione redox status appears to plays an important role in NOS induction during macrophage activation.

Role of a copper (I)-dependent enzyme in the anti-platelet action of S-nitrosoglutathione.

1. S-nitrosoglutathione (GSNO) is a potent and selective anti-platelet agent, despite the fact that its spontaneous rate of release of nitric oxide (NO) is very slow. Our aim was to investigate the mechanism of the anti-aggregatory action of GSNO. 2. The biological action of GSNO could be mediated by NO released from S-nitrosocystylglycine, following enzymatic cleavage of GSNO by gamma-glutamyl transpeptidase. The anti-aggregatory potency of GSNO was not, however, altered by treatment of target platelets with the gamma-glutamyl transpeptidase inhibitor acivicin (1 mM). gamma-Glutamyl transpeptidase is not, therefore, involved in mediating the action of GSNO. 3. The rate of breakdown of S-nitrosoalbumin was increased from 0.19 +/- 0.086 nmol min-1 to 1.52 +/- 0.24 nmol min-1 (mean +/- s.e.mean) in the presence of cysteine (P < 0.05, n = 4). Inhibition of platelet aggregation by S-nitrosoalbumin was also significantly increased by cysteine (P < 0.05, n = 4), suggesting that the biological activity of S-nitrosoalbumin is mediated by exchange of NO from the protein carrier to form the unstable compound cysNO. Breakdown of GSNO showed a non-significant acceleration in the presence of cysteine, from 0.56 +/- 0.22 to 1.77 +/- 0.27 nmol min-1 (mean +/- s.e.mean) (P = 0.064, n = 4), and its ability to inhibit platelet aggregation was not enhanced by cysteine. This indicates that the anti-platelet action of GSNO is not dependent upon transnitrosation to form cysNO. 4. Platelets pretreated with the copper (I)-specific chelator bathocuproine disulphonic acid (BCS), then resuspended in BCS-free buffer, showed resistance to the inhibitory effect of GSNO. These findings suggest that BCS impedes the action of GSNO by binding to structures on the platelet, rather than by chelating free copper in solution. 5. Release of NO from GSNO was catalysed enzymatically by ultrasonicated platelet suspensions. This enzyme had an apparent K(m) for GSNO of 12.4 +/- 2.64 microM and a Vmax of 0.21 +/- 0.03 nmol min-1 per 10(8) platelets (mean +/- s.e.mean, n = 5). It was inhibited by BCS, but not by the iron chelator bathophenathroline disulphonic acid, nor by acivicin. 6. We conclude that the stable S-nitrosothiol compound GSNO may exert its anti-platelet action via enzymatic, rather than spontaneous release of NO. This is mediated by a copper-dependent mechanism. The potency and platelet-selectivity of GSNO may result from targeted NO release at the platelet surface.

The effect of phenazine methosulphate on intermediary pathways of glucose metabolism in the lens at different glycaemic levels.

In this study changes in alternative pathways of glucose metabolism are examined in the rat lens using radiolabelled glucose in a 1 hr in vitro incubation of 50 mM or 10 mM glucose with or without 0.1 mM phenazine methosulphate (PMS). PMS which reoxidizes NADPH ensures that the pentose phosphate pathway (PPP) is not limited by the supply of NADP+. The data shows that maximal activation of the PPP (with PMS) is 40% greater at high glucose concentrations than normal glucose. This difference in maximal stimulation may be explained by the increase glucose uptake in the hyperglycaemic incubation. In the high-glucose incubation with PMS, hexokinase activity and the glucose 6-phosphate pool is not limiting for the PPP. Under these conditions, PMS alter the NAD+/NADH and NADP+/NADPH ratio. The change in the redox state alters the flux through the polyol pathway, the glycerol 3-phosphate shuttle and the glycolytic control sites, glyceraldehyde 3-phosphate, pyruvate and lactate dehydrogenases. These results are discussed in relation to hyperglycaemia-induced oxidative stress.

Changes in uridine nucleotides and uridine nucleotide sugars in diabetic rat lens: implications in membrane glycoprotein formation.

The lens has a very high content of UDP sugars. These are required for glycoprotein and proteoglycan synthesis, as components of fiber cell membranes and the capsule. In diabetes, changes in these sugar nucleotides are related to pathological changes in the basement membranes of cells from non-insulin-requiring tissues. We have investigated whether this is the case in the lens in diabetes and we report here that UDP-sugar levels are, in contrast to the norm in other non-insulin-requiring tissues, decreased at 2 and 4 weeks of diabetes. This is despite an elevation in the precursors of their formation, both of the pyrimidine (PPRibP) and carbohydrate (glucose, glucose 6-phosphate) components. Also reported here is the observation that lens pyrimidine biosynthesis occurs primarily by the de novo route, and that orotate phosphoribosyltransferase and orotidine-5'-phosphate decarboxylase are unchanged in diabetes. We have measured the energy charge of the adenine and uridine nucleotide pools and report both to be compromised under the diabetic condition. The fall in ATP provision is proposed to be responsible for the fall in UTP and hence leads to the recorded decrease in the UDP sugars. These changes are discussed in relation to the change in capsular and fiber cell composition and the functional significance of this in cataract formation.

Increased susceptibility to metal catalysed oxidation of diabetic lens beta L crystallin: possible protection by dietary supplementation with acetylsalicylic acid.

The effect of dietary supplementation with acetylsalicylic acid on the increased modification, and susceptibility to modification, of lens crystallins from the streptozocin diabetic rat, has been determined. This was done by the measurement of characteristic markers of protein post-translational oxidative modification and glycation, in beta L crystallins purified from the lenses of control, diabetic and acetylsalicylic acid-supplemented diabetic animals, with no further manipulations, and again following the application of an in vitro graded oxidative insult. Crystallins prepared from the diabetic, in comparison with control animals, exhibited a higher level of bityrosine- and AGEP-like fluorescence as well as a loss of tryptophan fluorescence and sulphydryl groups. Exposure to an oxidative insult (in the form of CuSO4 and ascorbate) increased all parameters in beta L crystallins, irrespective of their source. However, the effects were most pronounced in the diabetic in which the effects of oxidative stress were always greater than the control crystallin. Dietary supplementation of the diabetic group with acetylsalicylic acid (100 mg kg-1 body weight day-1) had a marked effect in decreasing the level of modification induced in diabetic crystallins, by in vitro metal catalysed oxidative stress, lowering the levels of AGEP- and bityrosine-like fluorescence and carbonyl group formation. Increasing the oxidative stress by addition of increasing concentrations of H2O2, induced stress proportional increases in the indicators of protein modification in all beta L crystallins, irrespective of source. The increase in damage in relation to H2O2 concentration was greater in those crystallins from diabetic animals, revealing a greater susceptibility to such oxidative stress.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of diabetes and dietary ascorbate supplementation on the oxidative modification of rat lens beta L crystallin.

The level of characteristic markers of protein oxidative modification (tryptophan oxidation and sulfhydryl group loss as well as carbonyl and bityrosine formation) and glycation (AGEP formation) have been measured in beta L crystallin purified from the lenses of control, diabetic, and ascorbate-supplemented diabetic animals. These markers were also determined following the application of an in vitro graded oxidative insult. Prior to the application of stress, diabetic lens crystallins, in comparison with control, exhibited a higher content of bityrosine and AGEPs, a lower level of nonoxidized tryptophan, and a loss of sulfhydryl groups. After exposure to the oxidative insult there was a stress-proportional increase of the parameters in all beta L crystallins, irrespective of their source. The effects were most pronounced in the diabetic, in which the already-elevated indicators of oxidative damage were further increased. Dietary supplementation of the diabetic group with ascorbate had a marked effect in preventing beta L crystallin modification in vivo, alleviating the loss of sulfhydryl groups and the oxidation of tryptophan, partially preventing the formation of AGEP and carbonyl groups, but not affecting the formation of bityrosine. Supplementation also inhibited the increase in susceptibility of diabetic beta L crystallin to in vitro oxidative stress, preventing sulfhydryl group loss as well as carbonyl and AGEP group formation. The results are discussed in relation to the proposal that diabetes renders lens crystallins more susceptible to oxidative stress and that this may be a causative factor in cataractogenesis. The possible role of ascorbate in the inhibition, or attenuation, of cataractogenesis is examined.

Anti-oxidant status in an in vitro model for hyperglycaemic lens cataract formation: competition for available nicotinamide adenine dinucleotide phosphate between glutathione reduction and the polyol pathway.

The level of NADPH, total glutathione and sorbitol have been measured in a normal (5mM) and hyperglycaemic (35mM glucose) in vitro rat lens model. In hyperglycaemic conditions, these intermediates are 50%, 84% and 3628% of the normal level. When oxidatively stressed with H2O2 (0.1mM-1.0mM) a gradation in the NADPH and total glutathione decrease is seen, at both glucose levels. This effect is most pronounced in lenses incubated in 35mM glucose, with levels already decreased, the NADPH falls to 15% of the normal lens. Sorbitol levels are correspondingly lower when the lens is oxidatively stressed. The inclusion of the ethyl ester of glutathione alleviates the disruption in anti-oxidant status caused by H2O2 but is unable to restore the NADPH level depleted by hyperglycaemia. These results are discussed in relation to the competitive requirements for NADPH between anti-oxidant preservation and sorbitol formation, as a mechanism for lens opacification in diabetes.

Effect of experimental diabetes on the activity of hexokinase isoenzymes in tissues of the rat.

The effect of experimental diabetes on the activity of hexokinase isoenzymes was studied in a wide range of tissues of the rat. In the tissues known to require insulin for glucose phosphorylation, the activity of hexokinase was markedly decreased; the fall being mainly in the Type IV (Glucokinase) in liver and Type II in other tissues, these tissues also exhibit glucose underutilization in diabetes. In the tissues which are commonly known not to require insulin, the activity of Type I hexokinase was significantly increased, these tissues exhibit aspects of glucose overutilization in diabetes in particular kidney and lens. These changes are discussed in relation to Spiro's hypothesis of glucose under and overutilization in tissues in diabetes.

The effect of amylin and calcitonin gene-related peptide on insulin-stimulated glucose transport in the diaphragm.

The two peptides calcitonin gene related peptide (CGRP) and amylin at 1 uM levels in an isolated rat diaphragm preparation inhibited insulin stimulated 2-deoxy[3H]glucose transport by 30 and 60 percent, respectively; this was the case at maximal (1 uM) and sub-maximal (0.5 mU) insulin concentrations. No effect was measured on the basal level of 2-deoxy[3H]glucose transport.