The effect of acute alcohol exposure on hepatic oxidative stress and function: prevention by micronutrients

Alcohol binge drinking, especially in teenagers and young adults is a major public health issue in the UK, with the number of alcohol related liver disorders steadily increasing. Understanding the mechanisms behind liver disease arising from binge-drinking and finding ways to prevent such damage are currently important areas of research. In the present investigation the effect of acute ethanol administration on hepatic oxidative damage and apoptosis was examined using both an in vivo and in vitro approach; the effect of micronutrient supplementation prior and during ethanol exposure was also studied. The following studies were performed: (1) ethanol administration (75 mmol/kg body weight) and cyanamide pre-treatment followed by ethanol to study elevated acetaldehyde levels with liver tissue analysed 2.5, 6 and 24 hours post-alcohol; (2). Using juvenile animals, 2% betaine supplementation followed by acute ethanol with tissue analysed 24 hrs post ethanol; and (3). Micronutrient supplementation during concomitant ethanol exposure to hepG2 cells. It was found that a single dose of alcohol caused oxidative damage to the liver of rats at 2.5 hr post-alcohol as evidenced by decreased glutathione levels and increased malondialdehyde levels in both the cytosol and mitochondria. Liver function was also depressed but there were no findings of apoptosis as cytochrome c levels and caspase 3 activity was unchanged. At 6 hours, the effect of ethanol was reduced suggesting some degree of recovery, however, by 24 hours, increased mitochondrial oxidative stress was apparent. The effect of elevated acetaldehyde on hepatic damage was particularly evident at 24 hours, with some oxidative changes at earlier time points. At 24 hours, acetaldehyde caused a profound drop in glutathione levels in the cytosol and hepatic function was still deteriorating. Studies examining ethanol exposure to juvenile livers showed that glutathione levels were increased, suggesting an overtly protective response not seen in with older animals. It also showed that despite cytochrome c release into the cytosol, caspase-3 levels were not increased. This suggests that ATP depletion is preventing apoptosis initiation. Betaine supplementation prevented almost all of the alcohol-mediated changes, suggesting that the main mechanism behind alcohol-mediated liver damage is oxidative stress. Results using the hepG2 cell line model showed that micronutrients involved in glutathione synthesis can protect against hepatocyte damage caused by alcohol metabolism, with reduced reactive oxygen species and increased/maintained glutathione levels. In summary, these results demonstrate that both acute alcohol and acetaldehyde can have damaging effects to the liver, but that dietary intervention may be able to protect against ethanol induced oxidative stress.

Enhanced bio-decolourisation of acid orange 7 by Shewanella oneidensis through co-metabolism in a microbial fuel cell

The decolourisation of acid orange 7 (AO7) (C.I.15510) through co-metabolism in a microbial fuel cell by Shewanella oneidensis strain 14063 was investigated with respect to the kinetics of decolourisation, extent of degradation and toxicity of biotransformation products. Rapid decolourisation of AO7 (>98% within 30 h) was achieved at all tested dye concentrations with concomitant power production. The aromatic amine degradation products were recalcitrant under tested conditions. The first-order kinetic constant of decolourisation (k) decreased from 0.709 ± 0.05 h−1 to 0.05 ± 0.01 h−1 (co-substrate – pyruvate) when the dye concentration was raised from 35 mg l−1 to 350 mg l−1. The use of unrefined co-substrates such as rapeseed cake, corn-steep liquor and molasses also indicated comparable or better AO7 decolourisation kinetic constant values. The fully decolourised solutions indicated increased toxicity as the initial AO7 concentration was increased. This work highlights the possibility of using microbial fuel cells to achieve high kinetic rates of AO7 decolourisation through co-metabolism with concomitant electricity production and could potentially be utilised as the initial step of a two stage anaerobic/aerobic process for azo dye biotreatment.

Exercise training reduces fatty acid availability and improves the insulin sensitivity of glucose metabolism

Aims/hypothesis - It is not known whether the beneficial effects of exercise training on insulin sensitivity are due to changes in hepatic and peripheral insulin sensitivity or whether the changes in insulin sensitivity can be explained by adaptive changes in fatty acid metabolism, changes in visceral fat or changes in liver and muscle triacylglycerol content. We investigated the effects of 6 weeks of supervised exercise in sedentary men on these variables. Subjects and methods - We randomised 17 sedentary overweight male subjects (age 50 ± 2.6 years, BMI 27.6 ± 0.5 kg/m2) to a 6-week exercise programme (n = 10) or control group (n = 7). The insulin sensitivity of palmitic acid production rate (Ra), glycerol Ra, endogenous glucose Ra (EGP), glucose uptake and glucose metabolic clearance rate were measured at 0 and 6 weeks with a two-step hyperinsulinaemic–euglycaemic clamp [step 1, 0.3 (low dose); step 2, 1.5 (high dose) mU kg−1 min−1]. In the exercise group subjects were studied >72 h after the last training session. Liver and skeletal muscle triacylglycerol content was measured by magnetic resonance spectroscopy and visceral adipose tissue by cross-sectional computer tomography scanning. Results - After 6 weeks, fasting glycerol, palmitic acid Ra (p = 0.003, p = 0.042) and NEFA concentration (p = 0.005) were decreased in the exercise group with no change in the control group. The effects of low-dose insulin on EGP and of high-dose insulin on glucose uptake and metabolic clearance rate were enhanced in the exercise group but not in the control group (p = 0.026; p = 0.007 and p = 0.04). There was no change in muscle triacylglycerol and liver fat in either group. Conclusions/interpretation - Decreased availability of circulating NEFA may contribute to the observed improvement in the insulin sensitivity of EGP and glucose uptake following 6 weeks of moderate exercise.