Effect of nutritional copper deficiency on carrageenin edema in the rat

The effects of nutritional copper deficiency on carrageenin edema in the rat were investigated with emphasis on studying the correlation between the degree of copper deficiency and the degree of edema. Carrageenin paw edema in both copper-sufficient and copper-deficient groups of rats was compared after either 20, 40, or 60 d on respective diets. The degree of copper deficiency was quantitated by analyzing total copper concentrations in a number of tissues. Other copper dependent parameters were also determined. Results indicated that: (1) although copper sufficient rats showed relatively little change in the degree of edema, copper-deficient rats showed a steady and significant increase in edema from d 20 to 40 to 60; (2) paw edema in copper-deficient animals was highly and negatively correlated to the concentrations of copper in the liver; the correlation with liver Cu,Zn-superoxide dismutase activity, however, was inconsistent; (3) paw edema was not correlated either to copper concentration in tissues other than liver or to plasma ceruloplasmin activity; and (4) aggravation of carrageenin edema in copper-deficient animals seemed to be mediated via an as yet unknown secondary effect of copper deficiency.     

Silicon facilitation of copper utilization in the rat

An eight-week, 2 x 4 factorial rat experiment using two levels of dietary copper and four levels of dietary silicon was conducted to further delineate a previously observed silicon-copper interaction in which silicon appears to mimic copper in its effect on the composition of the aorta. Dietary copper concentrations were 1.4 (deficient) and 5.4 (adequate) mg/kg diet, and silicon concentrations were 5, 135, 270, and 540 mg/kg diet. Compared with the lowest level of silicon and copper, weight gains were 15.5% higher for rats fed 540 mg silicon/kg diet and 14.3% higher for those fed 5.4 mg copper/kg diet. The growth-promoting effects of silicon and copper were additive. Evidence that silicon elevated the copper status of copper-deficient rats includes an increase in packed-cell volume by 540 mg silicon/kg diet in the otherwise packed-cell volume-depressed, copper-deficient rats, accompanied by a trend toward higher hemoglobin values and lower relative heart weights. In the copper-adequate rats, evidence that 540 mg silicon/kg diet elevated their copper status includes a two-fold increase in the blood-plasma copper concentration, a three-fold increase in ceruloplasmin activity, and an increase in cardiac, renal, and hepatic copper concentrations. In addition, 540 mg silicon/kg diet resulted in higher aortic dry mass and aortic elastin content in both copper-deficient and copper-adequate rats. While dietary silicon concentrations of 135, 270, and 540 mg/kg diet were all effective in increasing aortic elastin in the copper-adequate rats, only 540 mg silicon/kg diet increased aortic elastin in the copper-deficient rats. These data indicate that some of the metabolic effects attributed to silicon may be manifested through a silicon-facilitated increase in copper utilization.     

Composition of glycosaminoglycans in the lungs of copper-deficient chicks

Copper deficiency results in defective elastin and collagen maturation in most tissues. A close relationship also exists between these components and proteoglycans in connective tissue. In an effort to obtain information on the nature of proteoglycans in copper deficiency, the composition of glycosaminoglycans in lungs from copper-deficient (1 micrograms/g of diet) or -supplemented (25 micrograms/g diet) chicks was studied. The total glycosaminoglycan concentration in copper-deficient chick lungs did not differ from that in control chick lungs. However, variations in individual glycosaminoglycan concentrations between lungs from copper-deficient and -supplemented chicks were observed. Heparan sulfate and dermatan sulfate concentrations were lower in copper-deficient chick lungs than in controls. The glycosaminoglycans from lungs of copper-deficient chicks also had lower molecular weights than glycosaminoglycans from lungs of control birds.     

Submaximal,aerobic exercise training exacerbates the cardiomyopathy of postweanling Cu-depleted rats

To determine the dual effect of exercise training and copper depletion on myocardial function and ultrastructure, postweanling rats were either trained or sedentary while fed copper-adequate or copper-deficient diets for 8 wk. Rats developed characteristic myocardial subcellular degeneration and increased cardiac mitochondrial volume density when copper depleted, despite lack of overt cardiac hypertrophy, hypertension, or anemia. Training combined with copper depletion induced mild left ventricular hypertrophy. Basal laminae appeared fractionated in areas at capillary-myocyte interface, with focal pericapillary and interstitial collagen accumulation, where-as overt fibrosis was absent or minimal. Electrocardiograms revealed increased QRS wave and QT duration and notching of QRS complex with copper depletion, consistent with intraventricular conductance disturbances. The oxidative capacity of soleus muscle increased with training in copper-adequate rats, but was reduced with progressive copper depletion. These data suggest that copper depletion and training are synergistic in effecting focal accumulation of collagen, with deleterious effect on exercise capacity.     

Cu,Zn-superoxide dismutase is lower and copper chaperone CCS is higher in erythrocytes of copper-deficient rats and mice

Discovery of a sensitive blood biochemical marker of copper status would be valuable for assessing marginal copper intakes. Rodent models were used to investigate whether erythrocyte concentrations of copper,zinc-superoxide dismutase (SOD), and the copper metallochaperone for SOD (CCS) were sensitive to dietary copper changes. Several models of copper deficiency were studied in postweanling male Holtzman rats, male Swiss Webster mice offspring, and both rat and mouse dams. Treatment resulted in variable but significantly altered copper status as evaluated by the presence of anemia, and lower liver copper and higher liver iron concentrations in copper-deficient compared with copper-adequate animals. Associated with this copper deficiency were consistent reductions in immunoreactive SOD and robust enhancements in CCS. In most cases, the ratio of CCS:SOD was several-fold higher in red blood cell extracts from copper-deficient compared with copper-adequate rodents. Determination of red cell CCS:SOD may be useful for assessing copper status of humans.     

Development of copper deficiency in rats fed fructose or starch: weekly measurements of copper indices in blood

Copper deficiency was induced in weanling rats fed diets whose sole source of carbohydrates was starch or fructose for 7 weeks. Conventional parameters of copper status, plasma copper concentrations, ceruloplasmin activity, and erythrocyte superoxide dismutase (SOD) activity were longitudinally monitored weekly to follow the development of the deficiency and to correlate these indices with the degree of severity of the deficiency. Although 30% of the rats fed a copper-deficient fructose diet died and no deaths occurred in rats fed the copper-deficient starch diet, plasma copper, ceruloplasmin, and SOD activities were reduced to a similar extent in all rats fed copper-deficient diets regardless of the type of dietary carbohydrate. Thus, none of the indices used accurately reflected the greater degree of deficiency or mortality in rats fed the fructose diet deficient in copper. The results of the present study underscore the need for more sensitive tests or alternative parameters to assess copper status in living animals.     

Interaction between nickel and copper in the rat

Two 42-d experiments were conducted with weanling male rats to study interactions between nickel and copper. In Experiment 1, a low-copper basal diet was supplemented with copper at 0 or 30 ppm and nickel at 0 or 30 ppm. Copper was added in Experiment 2 to a basal copper-deficient diet at a level of 0 or 15 ppm and nickel was supplemented at 0, 15, or 225 ppm. Responses to dietary nickel were dependent upon copper nutriture and experimental duration. Nickel had little effect on growth during the first 21 d of either study when added at low levels (15 or 30 ppm) to copper-deficient diets. Nickel supplementation depressed gains between 21 and 42 d in rats fed copper-deficient, but not copper-adequate, diets. Hematocrits and hemoglobin concentrations were not significantly affected by dietary nickel at 21 d. Nickel supplementation decreased hematocrits and hemoglobin values in copper deficient rats at 42 d in Experiment 1, but not in Experiment 2. Absorption of copper apparently was not reduced by nickel, since tissue copper concentrations were generally not decreased by increasing dietary nickel. Nickel supplementation increased lung and heart copper concentrations in Experiment 2. Liver iron was not affected by nickel, but spleen iron concentrations were reduced by nickel supplementation in copper-deficient rats in Experiment 2. The present studies suggest that nickel acts antagonistically to copper in certain biological processes.     

Effects of dietary carbohydrate intake on antioxidant enzyme activity and copper status in the copper-deficient streptozotocin (STZ) diabetic rat

The aim of this study was to investigate how dietary lactose, compared with sucrose, in association with copper deficiency influences the antioxidant and copper status in the diabetic rat. Two groups of male rats (n = 12) were fed copper-deficient diets containing either 300 g/kg of sucrose or 300 g/kg of lactose in a pair-feeding regime for 35 days. Six rats from each group were injected with streptozotocin to induce diabetes. After a further 16 days the animals were killed and the liver, heart, and kidney removed for the measurement of copper levels and the activities of antioxidant and related enzymes. Diabetes resulted in higher hepatic and renal copper levels compared with controls. The copper content of the heart and kidney in diabetic rats consuming sucrose was also significantly higher than in those consuming lactose. Catalase activity in the liver, heart, and kidney was significantly increased in diabetic rats compared with controls. Hepatic glutathione S-transferase and glucose-6-phosphate dehydrogenase and cardiac copper zinc superoxide dismutase activities were also higher in diabetes. Sucrose, compared with lactose feeding, resulted in higher cytochrome c oxidase and glutathione peroxidase activities in the kidney while glucose-6-phosphate dehydrogenase activity was lower. The combination of lactose feeding and diabetes resulted in significantly higher activities of cardiac managanese superoxide dismutase and catalase and renal manganese superoxide dismutase and glucose-6-phosphate dehydrogenase. These results suggest that sucrose consumption compared with lactose appears to be associated with increased organ copper content and in general decreased antioxidant enzyme activities in copper-deficient diabetic rats.     

Composition of proteoglycans in the aortas of copper-deficient rats

Copper deficiency adversely affects the extracellular matrix of the arterial wall, leading to cardiovascular lesions. To study the lesions resulting from copper deficiency, the composition of proteoglycans from aortas of copper-deficient rats was compared with proteoglycans of aortas from copper-supplemented rats. Copper deficiency in rats was verified by copper levels in adrenal glands (mean +/- SE, 0.37 +/- 0.07 vs 1.03 +/- 0.17 micrograms/g wet wt in supplemented rats). The proteoglycans were isolated from the aorta by extraction with 4 M guanidine-HCl and by digestion of the tissue with elastase. The proteoglycans were purified by CsCl isopycnic centrifugation and fractionated by gel filtration. The fractions were characterized for molecular size and glycosaminoglycan composition. Total uronate in the aortas from copper-deficient rats was 25% greater than in aortas from copper-supplemented rats, and the proteoglycans from copper-deficient rat aortas were of greater molecular size. Among the glycosaminoglycans the concentration (microgram/mg tissue) of isomeric chondroitin sulfates, particularly dermatan sulfate, was greater in copper-deficient animals than in copper-supplemented animals. These observations are similar to earlier findings in experimental atherosclerosis and to a response of cardiovascular connective tissue to injury.     

Impaired cardiac mitochondrial membrane potential and respiration in copper-deficient rats

Cardiac mitochondrial respiration, ATP synthase activity, and membrane potential and intactness were evaluated in copper-deficient rats. In the presence of NADH, both copper-deficient and copper-adequate mitochondria had very low oxygen consumption rates, indicating membrane intactness. However copper-deficient mitochondria had significantly lower oxygen consumption rates with NADH than did copper-adequate mitochondria. Copper-deficient mitochondria had significantly lower membrane potential than did copper-adequate mitochondria using fluorescent dyes. Copper-deficient mitochondria had significantly lower state 3 oxygen consumption rates and were less sensitive to inhibition by oligomycin, an ATP synthase inhibitor. Copper-deficient and copper-adequate mitochondria responded similiarly to CCCP. No difference was observed in mitochondrial ATPase activity between copper-deficient and copper-adequate rats using submitochondrial particles. We conclude that cardiac mitochondrial respiration is compromised in copper-deficient rats, and may be related to an altered ATP synthase complex and/or a decreased mitochondrial membrane potential.     

Functional aspects of oxidative phosphorylation and electron transport in cardiac mitochondria of copper-deficient rats

Although dietary copper deficiency causes physiological, morphological, and biochemical abnormalities in cardiac mitochondria, the relationship observed between abnormalities of mitochondrial structure and function have been inconsistent in previous studies. The purpose of the present study was to re-evaluate the respiration rates of cardiac mitochondria from copper-deficient rats and to use several drugs that uncouple and inhibit mitochondrial respiration in order to clarify the mechanisms of mitochondrial dysfunction found in several laboratories. Copper deficiency reduced state 4 and state 3 cardiac mitochondrial respiration rates with all substrates tested. However, neither the ratio of ADP/oxygen consumed nor the acceptor control index was affected by copper deficiency. Cardiac mitochondria of copper-deficient rats showed a resistance to respiratory blockade by oligomycin and an increased ability to hydrolyze ATP in the presence of oligomycin compared with mitochondria of copper-adequate rats. This suggests that copper deficiency affects the function of the cardiac mitochondrial ATP synthase.     

Cardiac and splenic levels of norepinephrine and dopamine in copper deficient pigs and rats

1. Copper deficiency decreased the concentration and content of norepinephrine in the hearts of pigs and rats. 2. Concentration, but not content, of norepinephrine was decreased in spleen of copper-deficient pigs, while splenic norepinephrine levels in rats were not altered by copper deficiency. 3. Cardiac and splenic concentrations and contents of dopamine were elevated in copper-deficient pigs and rats. 4. Tissue concentrations of catecholamines and the magnitude of change due to copper deficiency were greater in pigs than rats.     

The effect of vitamin E on lipid peroxidation in the copper-deficient rat

The present study was designed to determine whether the supplementation of vitamin E in the copper-deficient diet would ameliorate the severity of copper deficiency in fructose-fed rats. Lipid peroxidation was measured in the livers and hearts of rats fed a copper-deficient diet (0.6 microg Cu/g) containing 62% fructose with adequate vitamin E (0.1 g/kg diet) or supplemented with vitamin E (1.0 g/kg diet). Hepatic lipid peroxidation was significantly reduced by vitamin E supplementation compared with the unsupplemented adequate rats. In contrast, myocardial lipid peroxidation was unaffected by the level of vitamin E. Regardless of vitamin E supplementation, all copper-deficient rats exhibited severe signs of copper deficiency, and some of the vitamin E-supplemented rats died of this deficiency. These findings suggest that although vitamin E provided protection against peroxidation in the liver, it did not protect the animals against the severity of copper deficiency induced by fructose consumption.     

Folate and homocysteine metabolism in copper-deficient rats.

To investigate the effect of copper deficiency on folate and homocysteine metabolism, we measured plasma, red-cell and hepatic folate, plasma homocysteine and vitamin B-12 concentrations, and hepatic methionine synthase activities in rats. Two groups of male Sprague-Dawley rats were fed semi-purified diets containing either 0. 1 mg (copper-deficient group) or 9.2 mg (control group) of copper per kg. After 6 weeks of dietary treatment, copper deficiency was established as evidenced by markedly decreased plasma and hepatic copper concentrations in rats fed the low-copper diet. Plasma, red-cell, hepatic folate, and plasma vitamin B-12 concentrations were similar in both groups, whereas plasma homocysteine concentrations in the copper-deficient group were significantly higher than in the control group (P<0.05). Copper deficiency resulted in a 21% reduction in hepatic methionine synthase activity as compared to the control group (P<0.01). This change most likely caused the increased hepatic 5-methyltetrahydrofolate and plasma homocysteine concentrations in the copper-deficient group. Our results indicate that hepatic methionine synthase may be a cuproenzyme, and plasma homocysteine concentrations are influenced by copper nutriture in rats. These data support the concept that copper deficiency can be a risk factor for cardiovascular disease.     

Cardiac levels of fibronectin,laminin, isomyosins,and cytochrome c oxidase of weanling rats are more vulnerable to copper deficiency than those of postweanling rats

The relative quantities of cardiac laminin, fibronectin, cytochrome c oxidase (CCO), and isomyosin types were studied by gel electrophoresis in male rats fed copper-deficient diets beginning either from the time of weaning for 5 weeks or from 5 weeks postweaning for 6 weeks with one group of copper-repleted rats. Increased levels of fibronectin and V(3) isomyosin but decreased levels of CCO subunit IV and laminin were found in weanling copper-depleted rats. In contrast, postweanling copper-depleted rats exhibited only increased levels of fibronectin and decreased levels of cardiac CCO subunit IV. Repletion of copper-deficient rats for 6 weeks was not sufficient to restore CCO subunit IV to the same level as controls. These results confirm that biochemical lesions in the basal laminae are a result of copper restriction. The decreased nuclear encoded subunits of CCO may help explain some of the mitochondrial pathology observed in dietary copper restriction. Increased V(3) isomyosin levels with low ATPase activity may help to conserve to a limited extent the ATP levels in copper-deficient cardiac tissue. These protein changes are consistent with the known morphological alterations of hearts from copper-restricted rats.     

Fructose metabolizing enzymes in the rat liver and metabolic parameters: Interactions between dietary copper,type of carbohydrates,and gender

This study was conducted to determine the effects of nutrient interactions between dietary carbohydrates and copper levels on fructose-metabolizing hepatic enzymes in male and female rats. Male and female rats were fed diets for 5 weeks that were either adequate or deficient in copper that contained either starch or fructose. Rats of both sexes fed fructose as compared with those fed starch showed higher activity of hepatic fructose metabolizing enzymes. There were also significant differences in fructose metabolism of liver between the male and female rats. Female rats had lower hepatic ketohexokinase and triose kinase but higher triosephosphate isomerase activities compared with male rats. Male rats fed copper-deficient diets had lower aldolase B activity compared with those fed copper-adequate diets. Female rats fed copper-deficient diets had higher triosephosphate isomerase activity compared with rats fed copper-adequate diets. Our data suggest that gender differences in hepatic fructose metabolism may not be the primary reason for the severity of copper deficiency syndrome in male rats fed copper-deficient diet with fructose.     

In vivo apoprotein catabolism of high density lipoproteins in copper-deficient, hypercholesterolemic rats

High density lipoprotein (HDL) apoprotein catabolism was examined in male Sprague-Dawley rats deficient in dietary copper. Twenty-four rats were randomly divided into two groups: copper-adequate (control, 5 mg of copper/kg diet) and copper-deficient (0.6 mg of copper/kg diet). After 5 weeks, animals were administered a tracer dose of iodinated HDL protein previously isolated from donor rats that were subjected to the same dietary treatments as the test animals. Copper-deficient rats exhibited a 54% increase in plasma volume and a 26% increase in HDL protein concentration above controls. Consequently, the intravascular pool of total HDL protein was increased 2-fold. The fractional catabolic rate of total HDL protein was similar between groups. However, because of the increased intravascular HDL pool in copper-deficient animals, the absolute catabolic rate was greater (640 +/- 49 micrograms/hr vs 316 +/- 12 micrograms/hr in controls). Tissue uptake of total HDL protein in copper-deficient rats tended to be greater in the kidneys, spleen, and testes compared with controls; the heart exhibited a significant 2.3-fold increase. In contrast, the catabolic rate of HDL protein in the liver and adrenal gland were not different between treatment groups. That an obligatory increase in HDL protein uptake was not observed in the liver and adrenal gland (organs which are sensitive to and can further metabolize cholesterol) suggests that these organs may be regulated, possibly contributing to the observed hypercholesterolemia in this model. These data imply that total HDL apoprotein catabolism is increased in response to the increased intravascular pool of HDL in copper-deficient rats.     

The effect of copper deficiency on rat hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase activity

The effect of copper deficiency on hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase, the key enzyme regulating cholesterol biosynthesis, was investigated in the rat. Male weanling rats were fed semipurified diets containing adequate, marginal, or deficient levels of copper for 6 weeks. Two separate studies were conducted; in the first study, animals were fasted 12 hours prior to analysis and in the second study, animals were fed diets ad libitum. Plasma lipid levels, hepatic cholesterol concentrations, and 3-hydroxy-3-methylglutaryl coenzyme A reductase specific activity, total and active, were determined. Consistent with previous findings, plasma total cholesterol and triglyceride levels were significantly elevated in copper-deficient rats. Copper deficiency resulted in a significant decrease in hepatic total cholesterol levels. Total and active levels of 3-hydroxy-3-methylglutaryl coenzyme A reductase in fed animals were elevated twofold with copper deficiency, with the active form of the enzyme constituting approximately 30% of total activity. 3-Hydroxy-3-methylglutaryl coenzyme A reductase activity in copper-deficient fasted rats was twofold higher than for the fasted adequate animal; however, fasting did result in a 10-fold reduction in hepatic reductase specific activity. These data support the hypothesis that copper deficiency results in a hypercholesterolemic state in the rat associated with increased hepatic cholesterol synthesis.     

Decreased passive stiffness of cardiac myocytes and cardiac tissue from copper-deficient rat hearts

Passive stiffness characteristics of isolated cardiac myocytes, papillary muscles, and aortic strips from male Holtzman rats fed a copper-deficient diet for approximately 5 wk were compared with those of rats fed a copper-adequate diet to determine whether alterations in these characteristics might accompany the well-documented cardiac hypertrophy and high incidence of ventricular rupture characteristic of copper deficiency. Stiffness of isolated cardiac myocytes was assessed from measurements of cellular dimensional changes to varied osmotic conditions. Stiffness of papillary muscles and aortic strips was determined from resting length-tension analyses and included steady-state characteristics, dynamic viscoelastic stiffness properties, and maximum tensile strength. The primary findings were that copper deficiency resulted in cardiac hypertrophy with increased cardiac myocyte size and fragility, decreased cardiac myocyte stiffness, and decreased papillary muscle passive stiffness, dynamic stiffness, and tensile strength and no alteration in aortic connective tissue passive stiffness or tensile strength. These findings suggest that a reduction of cardiac myocyte stiffness and increased cellular fragility could contribute to the reduced overall cardiac tissue stiffness and the high incidence of ventricular aneurysm observed in copper-deficient rats.