Superoxide dismutase activity in lung from copper- and manganese-deficient mice exposed to ozone

Hohenheim consensus workshop: copper

Copper (Cu) is an essential trace element with many physiological functions. Homeostatic mechanisms exist to allow Cu to act as a cofactor in enzymatic processes and to prevent accumulation of Cu to toxic levels. The aim of this commentary is to better understand the role of dietary Cu supply in deficiency and under physiological and pathological conditions. The essentiality of Cu can be attributed to its role as a cofactor in a number of enzymes that are involved in the defence against oxidative stress. Cu, however, has a second face, that of a toxic compound as it is observed with accumulating evidence in hepatic, neurodegenerative and cardiovascular diseases. The destructive potential of Cu can be attributed to inherent physico-chemical properties. The main property is its ability to take part in Fenton-like reactions in which the highly reactive and extremely deleterious hydroxyl radical is formed. Diseases caused by dietary Cu overload could be based on a genetic predisposition. Thus, an assessment of risk-groups, such as infants with impaired mechanisms of Cu homeostasis regarding detoxification, is of special interest, as their Cu intake with resuspended formula milk may be very high. This implies the need for reliable diagnostic markers to determine the Cu status. These topics were introduced at the workshop by the participants followed by extensive group discussion. The consensus statements were agreed on by all members. One of the conclusions is that a re-assessment of published data is necessary and future research is required.

Newer aspects of micronutrients in chronic disease: copper

Cu ions are pro-oxidants when added to biological material in vitro and excessive levels of Cu in the body, such as in Wilson's Disease (Yarze et al. 1992) promote oxidant-related pathologies. In contrast there is now substantial evidence that an optimum level of Cu is required to maintain antioxidant defence and that Cu deficiency in animals increases oxidant stress. There are abundant mechanistic relationships linking Cu deficiency and processes associated with IHD, some of which do not directly involve oxidant damage. These mechanistic relationships, however, have mostly been demonstrated in animal models and more information is urgently required concerning possible chronic mild Cu deficiencies in human populations. A major hurdle to advances in this area is the lack of indices of Cu status which are sensitive enough to detect marginal Cu deficiency in humans. The question, therefore, of whether or not there is a role for mild Cu deficiency in the onset of chronic disease processes, including IHD, remains unanswered.

Influence of nicotine on tissue trace element concentrations and tissue antioxidant defense

Both altered trace element metabolism and cigarette smoking have been proposed to be risk factors for cardiovascular disease (CVD). Thus, it is important to identify the mechanisms by which cigarette smoke alters trace element metabolism. In the present study, serum trace element concentrations were measured in 19 smokers and 13 nonsmokers. In parallel studies, data from rats treated with 50 mg of nicotine over a 21-d period tested the hypothesis that nicotine induced altered trace element metabolism observed in smokers. Serum Cu and Zn concentrations were significantly higher in smokers than in nonsmokers. Serum nicotine concentrations in rats were comparable to those observed in heavy smokers, but serum trace element concentrations were not significantly altered by nicotine treatment. Tissue trace element concentrations were also not markedly affected by nicotine; however, trace element ratios in liver, kidney, lung, and brain were significantly altered by nicotine treatment. In addition, nicotine-treatment resulted in significantly lower liver glutathione concentrations and higher Cu, Zn superoxide dismutase activity than in controls. These data show that a 50-mg infusion of nicotine over 21 d does not produce in rats the serum trace element abnormalities observed in cigarette smokers. However, nicotine did affect the trace element relationships between tissues as well as components of the free radical defense system.

Influence of copper status on the response to acute ethanol exposure in rats

An acute dose of ethanol was used to investigate the biochemical response of tissues with a compromised antioxidant defense system to a surge of oxygen radical production. The copper (Cu)-deficient rat served as the animal model for this study based on its compromised antioxidant defense system. Rats were fed control (10 micrograms Cu/g) or Cu-deficient (0.2 microgram Cu/g) diet for 14 days. In order to minimize secondary effects associated with chronic Cu deficiency, the chelator triethylenetetramine was added to the Cu-deficient diet to shorten the time required for the induction of Cu deficiency. On day 14, rats were gavaged with ethanol (4.5 g/kg b.wt.) or saline and killed 9 hours postgavage. Rats fed the Cu-deficient diets had lower liver superoxide dismutase (SOD) and glutathione peroxidase (GPx) activities than controls. Ethanol treatment had no effect on liver CuZnSOD or Gpx activity, while MnSOD activity was higher than saline control levels following EtOH treatment. Despite low GPx and SOD activity, Cu-deficient rats did not exhibit higher hepatic thiobarbituric acid reacting substances (TBARS) than controls; in fact, hepatic microsomal TBARS were lower in saline-treated Cu-deficient rats relative to Cu-sufficient rats. Ethanol treatment resulted in higher whole homogenate and mitochondrial TBARS than in saline-gavaged rats. Copper status did not influence hepatic TBARS production in response to an acute EtOH load. These data suggest that compensatory mechanisms contribute to the protection of the liver from excessive free radical production in this model of Cu deficiency.