Effects of lipoic acid and dihydrolipoic acid on 4-aminophenol-mediated erythrocytic toxicity in vitro

The effects of the antioxidant lipoic acid and its reduced form, dihydrolipoic acid (DHLA), were studied on the process of the erythrocytic toxicity of 4-aminophenol in human erythrocytes in vitro. 4-Aminophenol alone caused a stepwise increase in methaemoglobin formation, along with a commensurate decrease in total thiols. At 10 min., in the presence of lipoic acid alone and the thiol depletor 1-chloro-2,4-dinitrobenzene (CDNB) alone, 4-aminophenol-mediated methaemoglobin formation was significantly increased, whilst thiol levels were significantly reduced compared with the 4-aminophenol alone. At 10 min., with DHLA and CDNB alone, 4-aminophenol was associated with significantly increased methaemoglobin formation. However, thiol levels were not significantly different in the presence of DHLA compared with 4-aminophenol alone, although thiol levels were different compared with control (4-aminophenol alone) in the incubations with CDNB alone. At 15 min., only CDNB/4-aminophenol methaemoglobin formation differed from control, whilst thiol levels were significantly lower in the presence of CDNB alone compared with 4-aminophenol alone. Lipoic acid enhanced the toxicity of 4-aminophenol in terms of increased methaemoglobin formation coupled with increased thiol depletion, whilst DHLA showed increased 4-aminophenol-mediated methaemoglobin formation without thiol depletion. Lipoic acid, and to a lesser extent its reduced derivative DHLA, acted as a prooxidant in the presence of 4-aminophenol, enhancing the oxidative stress effects of the amine in human erythrocytes.     

A preliminary evaluation of a novel method to monitor a triple antioxidant combination (vitamins E, C and α-lipoic acid) in diabetic volunteers using in vitro methaemoglobin formation

Eight otherwise healthy diabetic volunteers took a daily antioxidant supplement consisting of vitamin E (200 IU), vitamin C (250 mg) and α-lipoic acid (90 mg) for a period of 6 weeks. Diabetic dapsone hydroxylamine-mediated methaemoglobin formation and resistance to erythrocytic thiol depletion was compared with age and sex-matched non-diabetic subjects. At time zero, methaemoglobin formation in the non-diabetic subjects was greater at all four time points compared with that of the diabetic subjects. Resistance to glutathione depletion was initially greater in non-diabetic compared with diabetic samples. Half-way through the study (3 weeks), there were no differences between the two groups in methaemoglobin formation and thiol depletion in the diabetic samples was now lower than the non-diabetic samples at 10 and 20 min. At 6 weeks, diabetic erythrocytic thiol levels remained greater than those of non-diabetics. HbA(1c) values were significantly reduced in the diabetic subjects at 6 weeks compared with time zero values. At 10 weeks, 4 weeks after the end of supplementation, the diabetic HbA1(c) values significantly increased to the point where they were not significantly different from the time zero values. Total antioxidant status measurement (TAS) indicated that diabetic plasma antioxidant capacity was significantly improved during antioxidant supplementation. Conversion of α-lipoic acid to dihydrolipoic acid (DHLA) in vivo led to potent interference in a standard fructosamine assay kit, negating its use in this study. This report suggests that triple antioxidant therapy in diabetic volunteers attenuates the in vitro experimental oxidative stress of methaemoglobin formation and reduces haemoglobin glycation in vivo.     

Effects of the antioxidants dihydrolipoic acid (DHLA) and probucol on xenobiotic-mediated methaemoglobin formation in diabetic and non-diabetic human erythrocytes in vitro(1)

The antioxidant effects of dihydrolipoic acid (DHLA) and probucol were investigated in a human erythrocytic in-vitro model of diabetic oxidative stress, where xenobiotics were used to form methaemoglobin. 4-Aminophenol mediated haemoglobin oxidation in non-diabetic erythrocytes was not affected by the presence of either DHLA or probucol. However, with diabetic cells, there were significant increases (P<0.01) in 4-aminophenol-mediated haemoglobin oxidation in the presence of DHLA. Methaemoglobin formed by nitrite in non-diabetic and diabetic cells was not altered by either DHLA or probucol except at one time point in diabetic cells. In non-diabetic as well as diabetic cells, methaemoglobin formed by MADDS-NHOH was significantly reduced at all three time points in the presence of DHLA (P<0.0001) but unaffected by probucol. In the presence of DHLA only, methaemoglobin formed by the products of rat microsomal oxidation of both 4-aminopropiophenone and benzocaine was markedly reduced for both xenobiotics in diabetic and non-diabetic cells (P<0.0001) compared with cells incubated in the absence of DHLA. There were no significant differences between total cellular thiol levels determined between diabetic and non-diabetic erythrocytes, nor did DHLA or probucol affect resting thiol levels. MADDS-NHOH caused a significant thiol depletion in diabetic cells, which was restored in the presence of DHLA. A further study is required to determine how DHLA attenuates the potent REDOX reactions that occur during hydroxylamine-mediated methaemoglobin formation.     

Effects of the antioxidants dihydrolipoic acid (DHLA) and probucol on xenobiotic-mediated methaemoglobin formation in diabetic and non-diabetic human erythrocytes in vitro

The antioxidant effects of dihydrolipoic acid (DHLA) and probucol were investigated in a human erythrocytic in-vitro model of diabetic oxidative stress, where xenobiotics were used to form methaemoglobin. 4-Aminophenol mediated haemoglobin oxidation in non-diabetic erythrocytes was not affected by the presence of either DHLA or probucol. However, with diabetic cells, there were significant increases (P<0.01) in 4-aminophenol-mediated haemoglobin oxidation in the presence of DHLA. Methaemoglobin formed by nitrite in non-diabetic and diabetic cells was not altered by either DHLA or probucol except at one time point in diabetic cells. In non-diabetic as well as diabetic cells, methaemoglobin formed by MADDS-NHOH was significantly reduced at all three time points in the presence of DHLA (P<0.0001) but unaffected by probucol. In the presence of DHLA only, methaemoglobin formed by the products of rat microsomal oxidation of both 4-aminopropiophenone and benzocaine was markedly reduced for both xenobiotics in diabetic and non-diabetic cells (P<0.0001) compared with cells incubated in the absence of DHLA. There were no significant differences between total cellular thiol levels determined between diabetic and non-diabetic erythrocytes, nor did DHLA or probucol affect resting thiol levels. MADDS-NHOH caused a significant thiol depletion in diabetic cells, which was restored in the presence of DHLA. A further study is required to determine how DHLA attenuates the potent REDOX reactions that occur during hydroxylamine-mediated methaemoglobin formation.     

Monitoring diabetic antioxidant status: a role for in vitro methaemoglobin formation

Diabetes leads to premature organ and system failure and considerably shortens lifespan. Careful control of glucose levels may not be enough to prevent the onset of complications in most diabetics. Compared with non-diabetics, diabetic tissues must not only resist a much greater long-term threat from hyperglycaemia-mediated reactive species but also defend themselves with compromised antioxidant systems. Although antioxidant therapy is a logical step in the prevention of oxidant and carbonyl stresses in the face of intermittent hyperglycaemia, this approach is not yet universally accepted to be effective in preventing complications. Although there are many biochemical indices of oxidant stress, piecemeal elevations of individual markers may not necessarily reflect true diabetic cellular antioxidant status. A dynamic process such as in vitro methaemoglobin generation may provide an opportunity to compare the response of a diabetic erythrocyte with that of a non-diabetic before and after corrective antioxidant therapy. Due to compromised cellular antioxidant capacity, diabetic cells generate less methaemoglobin in the presence of aromatic amine hydroxylamines, 4-aminophenol and nitrite compared with non-diabetics. Agents such as dihydrolipoic acid have been shown to correct methaemoglobin formation-mediated thiol deficits during in vitro studies. It is hoped that the progress of antioxidant supplementation studies in diabetics can be monitored with the aid of in vitro methaemoglobin generation using agents such as hydroxylamines, 4-aminophenol and nitrite. The most appropriate antioxidants and dosages can thus be recommended to diabetics worldwide to attenuate the development of complications.     

Effects of oxidised alpha-lipoic acid and alpha-tocopherol on xenobiotic-mediated methaemoglobin formation in diabetic and non-diabetic human erythrocytes in-vitro

The effects of oxidised alpha-lipoic acid and alpha-tocopherol were investigated on a human erythrocytic in vitro model of diabetic metabolic stress. Preincubation of non-diabetic and diabetic erythrocytes with oxidised alpha-lipoic acid or alpha-tocopherol resulted in marked increases in nitrite-mediated methaemoglobin formation. In contrast, oxidised alpha-lipoic acid resulted in considerable reductions in 4-aminophenol-mediated methaemoglobin formation in both diabetic and non-diabetic cells. alpha-Tocopherol showed an increase only in diabetic cells, at one time point. Monoacetyl dapsone hydroxylamine (MADDS-NHOH)-mediated methaemoglobin formation was reduced by oxidised alpha-lipoic acid in non-diabetic and diabetic cells at all three time points, although alpha-tocopherol had no effect with MADDS-NHOH. In diabetic cells only, alpha-tocopherol incubation caused a reduction in GSH levels compared with non-diabetic cells. As the agents showed pro- as well as anti-oxidant effects in this study, further studies are required to demonstrate potential diabetic benefit from alpha-lipoic acid adminstration.     

The methaemoglobin forming and GSH depleting effects of dapsone and monoacetyl dapsone hydroxylamines in human diabetic and non-diabetic erythrocytes in vitro

The respective methaemoglobin forming and GSH depleting capabilities of monoacetyl dapsone hydroxylamine (MADDS-NHOH) and dapsone hydroxylamine (DDS-NHOH) were compared in human diabetic and non-diabetic erythrocytes in vitro with a view to select the most potent agent for future oxidative stress and antioxidant evaluation studies. Administration of both metabolites to non-diabetic erythrocytes over the 20min period of the study resulted in significantly more methaemoglobin formation at all four time points compared with the diabetic erythrocytes (P<0.0001). At all four time points, significantly more methaemoglobin was formed in response to MADDS-NHOH in non-diabetic cells compared with the effects of DDS-NHOH on diabetic erythrocytes (P<0.0001). At the 5 and 10min time points, significantly more methaemglobin was formed in non-diabetic cells in the presence of MADDS-NHOH compared with DDS-NHOH (P<0.05). At the 5min time point only, significantly more methaemoglobin was formed in the presence of MADDS-NHOH in diabetic cells compared with that of DDS-NHOH (P<0.01). However, compared with diabetic control GSH levels, the presence of DDS-NHOH caused a significant depletion in GSH at 5, 10 and 20min time points in diabetic cells (P<0.001). In addition, the presence of DDS-NHOH caused a significant reduction in GSH levels in diabetic cells in comparison with those of non-diabetics at the 5, 10 and 20min, (P<0.005). DDS-NHOH was also associated with a significant depletion of GSH levels in diabetic cells compared with those of non-diabetic control erythrocytes (P<0.0001). The presence of MADDS-NHOH in diabetic erythrocytes led to a significant reduction in GSH levels at the 20min time point compared with those of non-diabetics (P<0.001), but there were no significant differences at the 5, 10 and 15min points. Due to its greater GSH-depleting action, DDS-NHOH will be selected for future use in the oxidative stress assessment in diabetic erythrocytes.     

Resistance to glutathione depletion in diabetic and non-diabetic human erythrocytes in-vitro

We have investigated the resistance of erythrocytes from diabetics and non-diabetics to glutathione depletion caused by p-benzoquinone, 1-chloro-2,4-dinitrobenzene (CDNB), diethyl maleate and 4-aminophenol. Incubation of erythrocytes with 4-aminophenol (2 mM) caused a precipitous reduction (>80%) in cellular glutathione levels although there was no significant difference between 4-aminophenol-mediated glutathione depletion in the diabetic and non-diabetic cells. p-Benzoquinone and CDNB were both associated with a less severe initial reduction in glutathione levels (>50% at 30 min) although p-benzoquinone caused greater depletion (P < 0.001) at 4.5 h (21.1 +/- 3.1%, non-diabetic; 20.0 +/- 1.0%, diabetic) compared with CDNB (49.2 +/- 2.2%, non-diabetic; 51.3 +/- 1.1% diabetic). Although there was no significant difference between the two types of cell in terms of level of depletion, administration of diethyl maleate caused a significant reduction in glutathione levels at 30 min (P < 0.0005), 3.5 h (P < 0.05) and 4.5 h (P < 0.05) in erythrocytes from diabetic man compared with those from non-diabetic man. Co-administration of buthionine sulphoximine (20 mM) and 4-aminophenol (1 mM) also led to a significant reduction in glutathione levels in diabetic cells at 30 min (P < 0.05), 3.5 h (P < 0.02) and 4.5 h (P < 0.007) compared with those in non-diabetic cells. The observations that diabetic red cells' resistance to depletion was similar to that of nondiabetic cells for three of the four depletors, and that the combination of 4-aminophenol and buthionine sulphoximine-mediated inhibition of glutathione synthesis was required to illustrate differences suggests that diabetic complications might be a result of the long-term effect of small deficiencies in oxidative self-defence mechanisms such as glutathione.     

The role of lipoic acid in prevention of nitroglycerin tolerance

Besides other organic nitrates, nitroglycerin (glyceryl trinitrate; GTN) has been used to treat acute heart failure particularly due to ischemic heart disease. However, one of serious clinical problems of the GTN therapy, particularly a long-standing medication, is hemodynamic tolerance to GTN, manifested by the decreased therapeutic efficacy of the drug. The most recent studies have suggested that mitochondrial lipoate/dihydrolipoate system-dependent aldehyde dehydrogenase-2 plays a key role in nitric oxide release from GTN. The aldehyde dehydrogenase-2 performs three enzymatic activities of dehydrogenase, esterase and reductase. The reductase activity is responsible for bioactivation of organic nitrates, such as GTN yielding nitrite and dinitrate (1,2-GDN/1,3-GDN, approximately 8:1). In view of a large contribution of dihydrolipoic acid to stabilization and regeneration of thiol groups, necessary for the reductase activity of aldehyde dehydrogenase-2, we conducted studies aimed to determine whether lipoic acid administration to rats is able to prevent GTN tolerance. The studies were conducted on 4 groups of animals: control saline-treated, model GTN-tolerant, GTN + lipoic acid-treated, lipoic acid alone-administered groups. On the 9th day of experiment animals were given i.v. therapeutic dose of GTN. We measured in all animals systolic and diastolic blood pressure before injection of therapeutic dose of GTN into the cadual vein and during 20 min thereafter. Levels of nitric oxide and reactive oxygen species and activities of glutathione peroxidase and superoxide dismutase were assayed in the aorta, plasma and heart of all animals. In addition, levels of malondialdehyde, and non-protein thiols, and activities of glutathione S-transferase and gamma-glutamyl transpeptidase were evaluated in the heart and plasma. The obtained results indicate that treatment of rats with a combination of lipoic acid and GTN can efficiently counteract GTN tolerance.     

Use of in vitro methaemoglobin generation to study antioxidant status in the diabetic erythrocyte

Poor glycaemic control in diabetes and a combination of oxidative, metabolic, and carbonyl stresses are thought to lead to widespread non-enzymatic glycation and eventually to diabetic complications. Diabetic tissues can suffer both restriction in their supply of reducing power and excessive demand for reducing power. This contributes to compromised antioxidant status, particularly in the essential glutathione maintenance system. To study and ultimately correct deficiencies in diabetic glutathione maintenance, an experimental model would be desirable, which would provide in vitro a rapid, convenient, and dynamic reflection of the performance of diabetic GSH antioxidant capacity compared with that of non-diabetics. Xenobiotic-mediated in vitro methaemoglobin formation in erythrocytes drawn from diabetic volunteers is significantly lower than that in erythrocytes of non-diabetics. Aromatic hydroxylamine-mediated methaemoglobin formation is GSH-dependent and is indicative of the ability of an erythrocyte to maintain GSH levels during rapid thiol consumption. Although nitrite forms methaemoglobin through a complex GSH-independent pathway, it also reveals deficiencies in diabetic detoxification and antioxidant performance compared with non-diabetics. Together with efficient glycaemic monitoring, future therapy of diabetes may include trials of different antiglycation agents and antioxidant combinations. Equalization in vitro of diabetic methaemoglobin generation with that of age/sex-matched non-diabetic subjects might provide an early indication of diabetic antioxidant status improvement in these studies.     

Studies on the differential sensitivity between diabetic and non-diabetic human erythrocytes to monoacetyl dapsone hydroxylamine-mediated methaemoglobin formation in vitro

Methaemoglobin generation by monoacetyl dapsone hydroxylamine in non-diabetic and diabetic erythrocytes was investigated in vitro. Methaemoglobin formation in purified haemoglobin isolated from both types of erythrocytes as well as haemolysates from both diabetic and non-diabetic erythrocytes did not differ. Prior to 18 h incubation with 10 and 20 mM glucose diabetic erythrocytes were significantly less sensitive to monoacetyl dapsone-induced methaemoglobinaemia. After pre-incubation the differential was lost although significant change in glutathione concentrations could not be shown between the two cell types. NADH-diaphorase levels measured in diabetics and non-diabetics did not significantly differ. It is possible that diabetic cells display reduced hydroxylamine-mediated methaemoglobin generation due to differences in glutathione metabolism.     

The therapeutic use of lipoic acid in diabetes: a current perspective

Lipoic acid and its reduced derivative, dihydrolipoic acid (DHLA) are highly promising antioxidant agents, which are potent attenuators of reactive species-mediated damage in vitro and in animal studies. Lipoic acid is a universal antioxidant, effective in lipophilic and aqueous environments. In contrast to an equivalent endogenous agent, such as oxidised glutathione (GSSG), lipoic acid acts as an antioxidant in its oxidised form. Lipoic acid has been evaluated in diabetic polyneuropathy, a condition which is thought to result in part from oxidant damage caused by long-term hyperglycaemia. Diabetic patients are prone to incur enhanced cellular free radical formation and reduced antioxidant defence. Treatment with lipoic acid has improved nerve conduction velocity during studies in diabetic animals. Trials in diabetic patients have often observed some relief of neuropathic symptoms during treatment with lipoic acid, but consistent objective benefits have been difficult to establish. Lipoic acid is now used in Germany for the treatment of diabetic neuropathy and definitive evidence of efficacy should arise from postmarketing surveillance studies. It is possible that lipoic acid may be more effective as a long-term dietary supplement aimed at the prophylactic protection of diabetics from complications.     

In vitro effects of vitamin C, thioctic acid and dihydrolipoic acid on the cytotoxicity of post-ethanol serum.

The serum of subjects consuming ethanol contains a non-dialysable cytotoxic activity, which is thought to reside in unstable acetaldehyde-protein adducts: the cytotoxic effects have been attributed to the transfer of acetaldehyde molecules from such adducts to target cells. When post-alcohol sera are incubated for 3 hr with ascorbic acid, thioctic acid or dihydrolipoic acid at a concentration of 10-500 micrograms/mL, their cytotoxicity against A9 cells is reduced. Post-alcohol sera incubated with these concentrations of thioctic acid or dihydrolipoic acid also had reduced cytotoxic activity against phytohaemagglutinin-transformed normal human lymphocytes. Studies with artificially produced [14C]acetaldehyde-125I-albumin complexes showed that treatment with thioctic acid or dihydrolipoic acid resulted in a reduced transfer of [14C]acetaldehyde to K562 cells. If these in vitro data also apply in vivo and if circulating acetaldehyde-protein adducts play a role in alcohol-mediated tissue damage, vitamin C and, to a greater extent, thioctic acid may have a beneficial effect in patients with acute and chronic alcohol toxicity.     

Alpha-lipoic acid protects against hepatic ischemia-reperfusion injury in rats

BACKGROUND AND AIM: To evaluate the protective effect of alpha-lipoic acid in reducing oxidative damage after severe hepatic ischemia/reperfusion (IR) injury. METHODS: Wistar albino rats were subjected to 45 min of hepatic ischemia, followed by 60 min reperfusion period. Lipoic acid (100 mg/kg i.p.) was administered 15 min prior to ischemia and immediately before reperfusion period. At the end of the reperfusion period aspartate aminotransferase (AST), alanine aminotransferase (ALT), lactate dehydrogenase (LDH) activity, and cytokine, TNF-alpha and IL-1beta levels were determined in serum samples. Malondialdehyde (MDA), and glutathione (GSH) levels and myeloperoxidase (MPO) activity were determined in the liver tissue samples while formation of reactive oxygen species was monitored by using chemiluminescence (CL) technique with luminol and lucigenin probes. Tissues were also analyzed histologically. Results: Serum ALT, AST, and LDH activities and TNF-alpha and IL-1beta levels were elevated in the I/R group, while this increase was significantly lower in the group of animals treated concomitantly with lipoic acid. Hepatic GSH levels, significantly depressed by I/R, were elevated back to control levels in lipoic acid-treated I/R group. Furthermore, increases in tissue luminol and lucigenin CL, MDA levels and MPO activity due to I/R injury were reduced back to control levels with lipoic acid treatment. CONCLUSION: Since lipoic acid administration alleviated the I/R-induced liver injury and improved the hepatic structure and function, it seems likely that lipoic acid with its antioxidant and oxidant-scavenging properties may be of potential therapeutic value in protecting the liver against oxidative injury due to ischemia-reperfusion.     

Lipoic acid inhibits caspase-dependent and -independent cell death pathways and is neuroprotective against hippocampal damage after pilocarpine-induced seizures

Alpha-lipoic acid has some neuroprotective properties, but this action has not been investigated in models of epilepsy. The aim of the present study was to investigate the protective efficacy of α-lipoic acid (lipoic acid) against pilocarpine-induced cell death through the caspase-dependent or -independent mitochondrial apoptotic pathways. Wistar rats were injected intraperitoneally with 0.9% saline (control group), pilocarpine (400 mg/kg, pilocarpine group) alone, or α-lipoic acid (20 mg/kg) in association with pilocarpine (400 mg/kg) 30 min before administration of α-lipoic acid. After the treatments all groups were observed for 24 h. Cell death was reduced in lipoic acid-treated rats. Cytosolic translocation of cytochrome c and subsequent activation of caspase-3 were reduced by lipoic acid treatment. AIF nuclear translocation and subsequent large-scale DNA fragmentation were also decreased in lipoic acid-treated rats. Our study suggests that lipoic acid inhibits both caspase-dependent and -independent apoptotic pathways and may be neuroprotective against hippocampal damage during pilocarpine-induced seizures.     

硫辛酸联合甲钴胺治疗糖尿病神经源性膀胱的疗效观察

目的观察硫辛酸与甲钴胺联合应用治疗糖尿病神经源性膀胱的疗效。方法将56例糖尿病神经源性膀胱患者随机分为两组,治疗组联用硫辛酸与甲钴胺治疗,对照组单用甲钴胺治疗。结果治疗组有效率85.7%,对照组有效率60.7%,两组间比较,差异有统计学意义（P〈0.05）。膀胱残余尿量治疗前后比较,两组患者均有明显改善（P〈0.01）,而治疗组优于对照组（P〈0.05）。结论硫辛酸与甲钴胺联用治疗糖尿病神经源性膀胱优于单用甲钴胺治疗。     

Antioxidant and prooxidant activities of alpha-lipoic acid and dihydrolipoic acid

Reactive oxygen (ROS) and nitrogen oxide (RNOS) species are produced as by-products of oxidative metabolism. A major function for ROS and RNOS is immunological host defense. Recent evidence indicate that ROS and RNOS may also function as signaling molecules. However, high levels of ROS and RNOS have been considered to potentially damage cellular macromolecules and have been implicated in the pathogenesis and progression of various chronic diseases. alpha-Lipoic acid and dihydrolipoic acid exhibit direct free radical scavenging properties and as a redox couple, with a low redox potential of -0.32 V, is a strong reductant. Several studies provided evidence that alpha-lipoic acid supplementation decreases oxidative stress and restores reduced levels of other antioxidants in vivo. However, there is also evidence indicating that alpha-lipoic acid and dihydrolipoic acid may exert prooxidant properties in vitro. alpha-Lipoic acid and dihydrolipoic acid were shown to promote the mitochondrial permeability transition in permeabilized hepatocytes and isolated rat liver mitochondria. Dihydrolipoic acid also stimulated superoxide anion production in rat liver mitochondria and submitochondrial particles. alpha-Lipoic acid was recently shown to stimulate glucose uptake into 3T3-L1 adipocytes by increasing intracellular oxidant levels and/or facilitating insulin receptor autophosphorylation presumably by oxidation of critical thiol groups present in the insulin receptor beta-subunit. Whether alpha-lipoic acid and/or dihydrolipoic acid-induced oxidative protein modifications contribute to their versatile effects observed in vivo warrants further investigation.     

The use of xenobiotic-mediated methaemoglobin formation to assess the effects of thyroid hormones on diabetic and non-diabetic human erythrocytic oxidant defence mechanisms in vitro

Diabetes is associated with an abnormal incidence of hypothyroidism, which exacerbates hyperglycaemia, so further damaging already compromised erythrocytic defence mechanisms. Methaemoglobin formation is a useful measure of the health of these mechanisms, as it determines the resistance of diabetic erythrocytes to sustained oxidative stress. The effect of l-tri-iodothyronine (T(3)) was, therefore, studied on nitrite and monoacetyldapsone hydroxylamine (MADDS-NHOH) mediated methaemoglobin formation in diabetic and non-diabetic human erythrocytes. Diabetic erythrocytes showed less sensitivity compared with non-diabetics to methaemoglobin formation mediated by both compounds. A 30 min pre-incubation with T(3) at 3 and 30 nM did not affect nitrite-mediated methaemoglobin formation compared with control observations in both cell types. In diabetic erythrocytes incubated with T(3) at 30 nM, there were significant increases in MADDS-NHOH-mediated methaemoglobin formation compared with control in both diabetic and non-diabetic cells. Studies comparing blood isolated from diabetic patients stabilised on thyroxine (T(4); 50 μG/day), T(4)-free diabetics and non-diabetics, showed that T(4) supplementation significantly increased MADDS-NHOH-mediated methaemoglobin formation compared with T(4)-free diabetic cells so that for two time points, T(4)-treated diabetic erythrocytic methaemoglobin formation was indistinguishable from that of non-diabetics. These studies indicate that T(4) supplementation improves some erythrocytic oxidant defence mechanisms in a time dependent manner.     

Effects of pantothenic acid supplementation on adrenal steroid secretion from male rats

The effects of pantothenic acid-supplementation on the adrenal secretion of corticosterone and progesterone in male rats were investigated using an in vitro cell culture system. Male rats at 21 d of age were given 0.03% pantothenic acid in their drinking water for 9 weeks. After 9 weeks of treatment, the animals were decapitated, and adrenal cells were cultured in the absence or presence of rat adrenocorticotropic hormone (ACTH; 10(-15) to 10(-10) M) and/or ovine prolactin (oPRL; 10(-9) to 10(-7) M) for 4 h. Adrenal cells in pantothenic acid-treated rats exhibited higher basal levels of corticosterone and progesterone than control rats. The response of ACTH and/or PRL on corticosterone and progesterone release was higher in the pantothenic acid-treated rats than in the control rats. In addition, PRL increased the stimulatory effect of ACTH-induced corticosterone secretion in both normal and pantothenic acid-treated rats. These results clearly demonstrated that pantothenic acid supplementation stimulates the ability of adrenal cells in male rats to secrete corticosterone and progesterone. Additionally, these results also showed that pantothenic acid supplementation induced adrenal hyperresponsiveness to ACTH stimulation, and PRL further stimulated adrenal sensitivity to ACTH.     

Effect of lipoic acid on biliary excretion of glutathione and metals.

Several metals are excreted in bile as glutathione complexes, and their biliary excretion is facilitated by increased hepatobiliary transport of glutathione. The present study analyzed the effect of lipoic acid (LA; thioctic acid; 37.5-300 mumol/kg, iv), an endogenous disulfide which can be reduced in vivo to a dithiol, on the hepatobiliary disposition of glutathione-related thiols and the biliary excretion of metals (10 mumol/kg, iv) in rats. Administration of LA enhanced the biliary excretion of reduced glutathione in a dose-dependent fashion. Despite increasing glutathione output, LA (150 mumol/kg, iv) did not increase, but rather decreased, the biliary excretion of methylmercury, cadmium, zinc, and copper, which are transported into bile in a glutathione-dependent manner, as indicated by a marked reduction in their biliary excretion after diethyl maleate-induced glutathione depletion. In contrast, biliary excretion of inorganic mercury, which is minimally affected by glutathione depletion, was dramatically enhanced (12- to 37-fold) by LA administration. Following injection of LA, the concentrations of endogenous disulfides in arterial blood plasma (e.g., cystine, glutathione disulfide, cysteine-glutathione, protein-cysteine, and protein-glutathione mixed disulfides) were considerably diminished, while the levels of endogenous thiols (e.g., glutathione and cysteine) were increased. This finding indicates that LA, probably after enzymatic conversion to dihydrolipoic acid, can reduce endogenous disulfides to thiols. It appears that LA induces the transport of glutathione into bile by the temporary formation of dihydrolipoic acid-glutathione mixed disulfide, which after being translocated into bile is cleaved to LA and reduced glutathione. Because the glutathione molecule thus transported into bile cannot complex metals at the thiol group, this might be the mechanism for the observed failure of the LA-induced increase in biliary excretion of glutathione to enhance the hepatobiliary transport of metals that are transported into bile as glutathione complexes (i.e., methylmercury, cadmium, zinc, and copper). The observations also raise the possibility that endogenous dihydrolipoic acid, by forming a stable complex with mercuric ion, may play the role of a carrier molecule in the hepatobiliary transport of inorganic mercury.