Effect of dietary carbohydrates and copper status on blood pressure of rats

Copper deficiency was induced in rats by feeding diets containing either 62% starch, fructose or glucose deficient in copper for 6 weeks. All copper deficient rats, regardless of the dietary carbohydrate, exhibited decreased ceruloplasmin activity and decreased serum copper concentrations. Rats fed the fructose diet exhibited a more severe copper deficiency as compared to rats fed either starch or glucose. The increased severity of the deficiency was characterized by reduced body weight, serum copper concentration and hematocrit. In all rats fed the copper adequate diets, blood pressure was unaffected by the type of dietary carbohydrate. Significantly reduced systolic blood pressure was evident only in rats fed the fructose diet deficient in copper. When comparing the three carbohydrate diets, the physiological and biochemical lesions induced by copper deprivation could be magnified by feeding fructose.     

Dietary copper, simple sugars, and metabolic changes in pigs

Inadequate dietary copper is known to result in undesirable metabolic changes in rats and humans. Abnormal cardiac function, leading to sudden death, is a common finding when copper deficient rats are fed a 62% fructose diet. To further study the apparent mineral-carbohydrate relationship to cardiac physiology, 3 male and 3 female swine were randomly assigned to four groups (6 pigs per group) which were fed low copper (1.5 ppm) or copper supplemented (40 ppm) diets with 20% of calories from either fructose or glucose for 10 weeks. In agreement with results from other animal studies, copper deficient swine exhibited decreased plasma ceruloplasmin, erythrocyte superoxide dismutase and plasma lysyl oxidase activities and lowered serum copper. The copper deficient fructose group had the lowest aortic lysyl oxidase activity and hematocrit when compared to the other groups. The relative heart weight in the copper deficient fructose group was 93% greater than the other three dietary groups. The livers of copper deficient fructose fed pigs were also significantly larger. Two enzymes related to cardiac and hepatic function, aspartate and alanine aminotransferase were also measured. Copper deficiency significantly lowered alanine aminotransferase but there was no dietary effect on aspartate amino-transferase. The results of this project indicate that the pig is a sensitive model for the study of cardiovascular abnormalities which occur when fructose is consumed with a low copper diet.     

The Cardiac Copper Chaperone Proteins Sco1 and CCS are Up-Regulated,but Cox 1 and Cox4 are Down-Regulated,by Copper Deficiency

Copper is ferried in a cell complexed to chaperone proteins, and in the heart much copper is required for cytochrome c oxidase (Cox). It is not completely understood how copper status affects the levels of these proteins. Here we determined if dietary copper deficiency could up- or down-regulate select copper chaperone proteins and Cox subunits 1 and 4 in cardiac tissue of rats. Sixteen weanling male Long–Evans rats were randomized into treatment groups, one group receiving a copper-deficient diet (<1 mg Cu/kg diet) and one group receiving a diet containing adequate copper (6 mg Cu/kg diet) for 5 weeks. Hearts were removed, weighed, and non-myofibrillar proteins separated to analyze for levels of CCS, Sco1, Ctr1, Cox17, Cox1, and Cox4 by SDS–PAGE and Western blotting. No changes were observed in the concentrations of CTR1 and Cox17 between copper-adequate and copper-deficient rats. CCS and Sco1 were up-regulated and Cox1 and Cox4 were both down-regulated as a result of copper deficiency. These data suggest that select chaperone proteins and may be up-regulated, and Cox1 and 4 down-regulated, by a dietary copper deficiency, whereas others appear not to be affected by copper status.     

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.     

Renal copper as an index of copper status in marginal deficiency

Marginal copper (Cu) deficiency is difficult to study, in part because its effects may be small, but also because feeding of a deficient diet may not cause a discernable change in Cu status. The key to resolution of effects may be in the choice of Cu status index. In this study, liver Cu concentration, a commonly used index of Cu status, was compared with activity of ceruloplasmin (CP), a circulating Cu-dependent enzyme, and kidney Cu concentration for their utility in resolving effects of marginal Cu deficiency. Seventy male, weanling rats were fed diets containing, nominally, 0, 1.5, 3, 4.5, or 6 mg Cu/kg diet for 5 wk. All three indices showed strong depression with severe deficiency (dietary Cu=0), but were relatively weak in their ability to distinguish between animals fed marginally deficient diets when compared by group statistics (ANOVA). Further, group statistics revealed no effect of marginal deficiency on six other variables known to change with severe Cu deficiency: heart weight/body weight, hematocrit, red cell distribution width, neutrophil count, glycated hemoglobin, and platelet count. To take into account interanimal variation, the three putative indices were plotted against these six variables and linear regression was performed on points representing marginally deficient rats. None of the variables showed significant regression with liver Cu or serum ceruloplasmin, but three showed significant regression with kidney Cu. These findings indicate that kidney Cu is preferable to liver Cu or ceruloplasmin as an index of Cu status in marginal deficiency and that linear regression is a possible way of testing for effects of marginal Cu deficiency, especially when effects are subtle.     

Effects of moderate copper deficiency on carbon tetrachloride-induced hepatotoxicity in rats.

Extreme copper deficiency has been shown to enhance CCl4-induced injury in rats. CCl4 hepatotoxicity was studied in rats with copper deficiency moderated by limiting deficiency periods to 5 or 6 weeks, using minimally adequate dietary zinc and including a marginal copper diet. Also, housing some rats in groups of six, rather than individually, was found to moderate the effects of low copper intake. Weanling male rats were fed copper at either 6, 2, or 0.2 mg/kg diet (adequate, marginal, deficient). Copper-zinc superoxide dismutase activity levels for singly and group-housed marginal rats were 80% and 93%, respectively, of adequate values. Values for deficient rats were 35% (singles) and 47% (group). In singly housed rats, a CCl4 dose of 400 microliters/kg intraperitoneally increased serum sorbitol dehydrogenase activities, indicators of cell membrane hepatotoxicity, in inverse proportion to dietary copper. A lower dose (100 microliters/kg) also produced smaller sorbitol dehydrogenase increases in adequate rats compared with deficients, but produced lowest increases in the marginals. The latter pattern also occurred in group-housed rats given the higher CCl4 dose, but the difference for adequate and marginal rats was not significant. The higher CCl4 dose, in singly housed rats, decreased liver glucose-6-phosphatase activities independently of copper intake. These activities are inversely proportional to microsomal lipid damage. In conclusion, moderate copper deficiency enhanced CCl4 hepatotoxicity, but the effect depended on injury criteria, CCl4 dose, and actual copper status as assessed by copper-zinc superoxide dismutase activities.     

Early and advanced glycation end-products are increased in dietary copper deficiency

The hypothesis that nonenzymatic glycosylation of proteins (glycation) contributes to damage associated with dietary copper deficiency has depended largely on indirect evidence. Thus far, the observation of an elevated percentage of glycated hemoglobin in copper-deficient rats has provided the only direct evidence of an increase in glycation. We sought further direct evidence of increased glycation in copper deficiency. Male weanling rats were fed a copper-adequate (CuA, 6.4 mg Cu/kg diet) or copper-deficient diet (CuD, 0.4 mg Cu/kg diet) for 5 weeks. Rats fed the CuD diet were copper deficient as judged by depressed organ copper concentrations and a variety of indirect indices. Measurements of hemoglobin A(1) and serum fructosamine (both early glycation end-products) as well as serum pentosidine (an advanced glycation end-product) indicated that all three compounds were elevated in CuD rats relative to CuA rats. This finding further supports the view that glycation is enhanced and thus may contribute to defects associated with dietary copper deficiency.     

Iron and zinc status in rats with diet-induced marginal deficiency of vitamin A and/or copper

The hypothesis was tested that there are interactions of marginal copper and vitamin A deficiency regarding iron and zinc status. Copper restriction (1 vs 5 mg Cu/kg diet) significantly lowered copper concentrations in plasma and tissues of rats and reduced blood hemoglobin, hematocrit, and iron concentrations in tibia and femur, but raised iron concentrations in liver. Vitamin A restriction (0 vs 4000 IU vitamin A/kg diet) reduced plasma retinol concentrations and induced a fall of blood hemoglobin and hematocrit. Neither copper nor vitamin A restriction for up to 42 d affected feed intake and body wt gain. There were no interrelated effects of vitamin A and copper deficiency on iron status. Copper deficiency slightly depressed liver, spleen, and kidney zinc concentrations. Vitamin A deficiency lowered zinc concentrations in heart, but only when the diets were deficient in copper.     

Vitamin B6 deficiency alters tissue iron concentrations in the Wistar rat

PurposeWe investigated the effect of a vitamin B6 deficiency and pair-feeding on tissue trace element status.MethodTissue zinc, copper and iron concentrations were measured in 3 groups of young, male Wistar rats receiving a diet of 3.5 mg/kg (control group), 0 mg/kg (deficient group) and a pair-fed group over 8 weeks. The pair-fed group received the same diet consumed by the control. Tissue trace element analysis was performed using atomic absorption spectrophotometry and plasma vitamin B6 status was determined using HPLC.ResultsDeficiency resulted in elevation in liver iron concentration and reduction in muscle iron concentration. Muscle copper concentrations were reduced in the pair-fed and deficient groups vs. the control group. Tissue zinc concentrations remained unaffected by the deficiency. Kidney iron and heart copper levels were elevated in the pair-fed group.ConclusionsThe liver and muscle iron changes were due to the deficiency and not to reduced calorie intake and the latter may be due to impaired heme synthesis. The differences in copper between the groups were due to reduced food intake. Zinc seems to form a fixed pool in these animals. A dietary deficiency of vitamin B6 impacts on the trace element status of certain tissues in key metabolic tissues and hence needs to be factored into the amelioration of the condition.     

High-selenium lentil diet protects against arsenic-induced atherosclerosis in a mouse model

Background: Cardiovascular disease (CVD) is a major cause of death worldwide, and arsenic (As) intake, mainly through drinking water, is a well-known risk factor for CVD as well as other health problems. Selenium (Se) is a known antagonist to As toxicity. Objective: We tested the potential of high-Se lentils from the Canadian prairies as a therapeutic food to alter the outcome of As-enhanced atherosclerosis. Materials and Methods: Male ApoE^−/− mice exposed to a moderate level of As (200 ppb) in their drinking water, and control mice on tap water received one of three lentil diets: Se-deficient (0.009 mg/kg), Se-adequate (0.16 mg/kg) or Se-high (0.3 mg/kg). After 13 weeks, lesion formation in the aortic arch and sinus were assessed. Intralesional cellular composition, serum lipid levels and hepatic oxidative stress were assessed as well. Results: Arsenic-exacerbated plaque formation was reduced in the sinus and completely abolished in the aortic arch of mice on the Se-fortified lentil diet, whereas lesions were increased in As-exposed mice on both the Se-deficient and Se-adequate diets. Notably, Se deficiency contributed to proatherogenic composition of serum lipids in As-exposed mice as indicated by high-density lipoprotein:low-density lipoprotein. At least adequate Se status was crucial for counteracting As-induced oxidative stress. Conclusion: This study is the first to show the potential of high-Se lentils to protect against As-triggered atherosclerosis, and this invites further investigations in human populations at risk from As contamination of their drinking water.     

Effect of copper deficiency on the concentrations of catecholamines and related enzyme activities in the rat brain.

Immature rats were made copper deficient by feeding them a low (< 1 p. p. m.) copper diet. During the gestation and lactation periods their dams consumed the same diet. Controls received a dietary supplement of 10 p. p. m. copper. At approx 7 weeks of age, the deficient animals exhibited signs of neurological dysfunction and gross lesions of the brain. Cytochrome oxidase activity and copper content of the liver and brain were used as criteria of copper status and confirmed the existence of severe deficiency. The whole brains minus cerebella of the deficient animals contained approx 30% less dopamine and norepinephrine than those of the controls. The tyrosine hydroxylase activity was depressed more than 25% in the copper deficient brains while the superoxide dismutase activity was lowered more than 35%. There was a high correlation between the chief criterion of copper status, liver cytochrome oxidase activity, and the brain concentrations of dopamine, norepinephrine and tyrosine hydroxylase activity. The decrease in activity of tyrosine hydroxylase was sufficient to account for the lowered concentrations of the catecholamines.     

Effects of dietary zinc and copper on free radical production in rat lung and liver

The effects of dietary copper and zinc on free radical production in lung and liver microsomes were studied in male weanling rats. The rats were fed for 6 weeks on one of seven diets, with different copper and zinc concentrations representing low, adequate, and high dietary levels of copper and low and adequate levels of zinc. Rats were put on diets arranged in a 3 X 2 factorial design with copper and zinc supplementations of 0, 15, and 500 mg/kg and 0.5 or 100 mg/kg, respectively. The low copper diet depressed copper levels in both the lungs and liver, although zinc levels were unchanged in rats on the low zinc diets. Endogenous carbon-centered lipid radical production in microsomes induced by NADPH was measured using spin-trapping techniques. The low zinc diets increased free radical production in lung microsomes but not in liver microsomes. No change in free radical production was observed in lung or liver microsomes obtained from rats on low copper diets. The data indicate that endogenous free radical production is increased in lung microsomes as a function of dietary zinc deficiency but is not influenced by copper status.     

Iron overload can induce mild copper deficiency

Dietary copper in the U.S. often is lower than that proved insufficient for men and women under controlled conditions. Iron overload can have adverse effects on copper nutriture and can produce cardiac disease in people. The hypothesis that iron can interfere with copper utilization to produce adverse effects related to cardiovascular function was tested.

Rats were fed a diet high in iron and marginal, but not deficient in copper for comparison with similar diets containing iron at the recommended amount. Copper and iron were measured by atomic absorption spectroscopy; cholesterol was measured by fluorescence, ceruloplasmin was measured by oxidase activity and hematology was done by an automated cell counter. When dietary copper was 2.0 mg/kg of diet, high iron decreased (p<0.008) cardiac and hepatic copper, plasma copper and ceruloplasmin, and increased (p<0.02) cardiac weight, hepatic iron and plasma cholesterol. When dietary copper was increased to 2.5 mg/kg, copper in heart and plasma decreased (p<0.04) and hepatic iron increased (p=0.001) with high iron but other effects disappeared. No harmful changes in hematology, such as hematocrit, mean corpuscular volume, etc. were found. High iron increased the dietary copper requirement of the animals. People with iron overload may benefit from copper supplementation, particularly if they habitually consume a diet low in copper.     

Serum superoxide dismutase 3 (extracellular superoxide dismutase) activity is a sensitive indicator of Cu status in rats

Sensitivity of the assay for Cu,Zn superoxide dismutase 3 (SOD3), the predominant form of SOD in serum, can be increased, and interferences caused by low-molecular-weight substances in the serum can be reduced by conducting the assay at pH 10 with xanthine/xanthine oxidase and acetylated cytochrome c (cyt c) as superoxide generator and detector, respectively. Serum SOD3 activity was assayed under these conditions in an experiment where weanling, male rats were fed diets for 6 weeks containing 3, 5 and 15 mg Zn/kg with dietary Cu set at 0.3, 1.5 and 5 mg Cu/kg at each level of dietary Zn. Serum SOD3 responded to changes in dietary Cu but not to changes in dietary Zn. A second experiment compared serum SOD3 activity to traditional indices of Cu status in weanling, male and female rats after they were fed diets containing, nominally, 0, 1, 1.5, 2, 2.5, 3 and 6 mg Cu/kg for 6 weeks. Serum SOD3 activity was significantly lower (P < .05) in male rats fed diets containing 0 and 1 mg Cu/kg and female rats fed diet containing 0 mg Cu/kg compared with rats fed diet containing 6 mg Cu/kg. These changes were similar to changes in liver Cu concentrations, liver cyt c oxidase (CCO) activity and plasma ceruloplasmin in males and females. Serum SOD3 activity was also strongly, positively correlated with liver Cu concentrations over the entire range of dietary Cu concentrations (R(2) = .942 in males, R(2) = .884 in females, P < .0001). Plots of serum SOD3 activity, liver Cu concentration, liver CCO activity and ceruloplasmin as functions of kidney Cu concentration all had two linear segments that intersected at similar kidney Cu concentrations (18-22 microg/g dry kidney in males, 15-17 microg/g dry kidney in females). These findings indicate that serum SOD3 activity is a sensitive index of Cu status.     

Effect of folic acid deficiency upon lymphocyte subsets from lymphoid organs in mice.

1. Three groups of weanling C57BL/6 female mice were fed one of two folate-deficient diets (0 and 0.1 mg folic acid/kg diet) or a normal folate-containing diet (2 mg folic acid/kg diet) for 8 weeks. A control pair-fed group was introduced with the most severe folate-deficient diet. Seven mice were fed the 0 mg folic acid/kg diet for 8 weeks, then rehabilitated (R) on the 2 mg folic acid/kg diet for 10 days. 2. Mice fed 0 mg folic acid/kg diet were severely folate-deficient (SFD), whereas mice fed 0.1 mg folic acid/kg diet were moderately folate-deficient (MFD), as shown by their folate status parameters. 3. Thymus weight, thymocyte content and positive immature CD4+8+ cells were decreased in SFD mice compared to controls. These values were normalized after 10 days of rehabilitation. 4. Mesenteric lymph node cells were apparently not affected by folate deficiency. 5. The proportion of Thy-1+ splenocytes was mildly lower in SFD mice than in controls. In R mice, mean spleen weight and spleen cellularity were increased compared to the other groups, but the proportions of Thy-1+, CD4+8- and CD4-8+ cells were markedly lower than control values.     

Copper deficiency depresses rat aortae superoxide dismutase activity and prostacyclin synthesis

Prostaglandin synthesis shows dependence on lipid hydroperoxides and resultant oxygen derived radical formation. In view of the importance of dietary copper in cytosolic copper dependent superoxide dismutase (Cu/Zn SOD) activity and the role of SOD in oxygen radical formation, the influence of dietary copper on prostacylin (PGI2) synthesis and SOD activity in rat aorta was examined. Copper deficient (0.5 micrograms Cu/g diet) rats showed a significant 47% reduction in PGI2 synthesis rates by aortic ring incubations in comparison to copper adequate (6.0 micrograms Cu/g diet) animals. Aortic SOD activity was reduced by 46% in copper deficiency in comparison to copper adequate animals. Marginal dietary copper (1.6 micrograms Cu/g diet) significantly reduced aortic SOD activity by 32% but was without effect on aortic ring incubation PGI2 synthesis. These results indicate that dietary copper deficiency, and the resultant decrease in SOD activity, depresses aortic PGI2 synthesis.     

High Lever Dietary Copper Promote Ghrelin Gene Expression in the Fundic Gland of Growing Pigs

This experiment was conducted to examine the effect of dietary copper supplementation on ghrelin mRNA expression level in the fundic gland of growing pigs. A total of 45 crossbred pigs were randomly assigned to three groups of 15 pigs, five replicates of three animals comprised each group. Pigs were allocated to diets that contained 5?mg/kg copper (as the control group), 125?mg/kg copper sulfate, or 125?mg/kg copper methionine. At the end of the experiment, five pigs were selected at random from each group, slaughtered, and collected the fundic gland for determination of ghrelin mRNA expression level. The results showed that average daily gain, average daily feed intake, absolute weight, serum growth hormone (GH) concentration, and ghrelin mRNA level were higher in pigs fed the diets with 125?mg/kg copper methionine and 125?mg/kg copper sulfate (P?<?0.05), than in pigs fed a diet with 5?mg/kg copper. These data suggest that high dietary copper (125?mg/kg) appears to increase feed intake and promote weight gain by enhancing the secretion of GH and ghrelin mRNA level in growing pigs.     

Effects of dietary zinc on free radical generation, lipid peroxidation, and superoxide dismutase in trained mice.

The purpose of this study was to investigate the effects of dietary zinc on free radical generation, lipid peroxidation, and superoxide dismutase (SOD) in exercised mice. In the first part of the study, 48 male weanling mice were randomly divided into three groups. They were fed a zinc-deficient diet containing 1.6 mg/kg zinc or were pair-fed or fed ad libitum a zinc-adequate diet supplemented with 50 mg/kg zinc. Half of each group received an exercise training program that consisted of swimming for 60 min per day in deionized water. The diets and exercise program persisted for 6 weeks. In the second part of the study, 64 mice were fed zinc-deficient diets for 6 weeks, and then one group was fed the zinc-deficient diet for an additional 3 weeks, and the other three groups were fed diets supplemented with 5, 50, and 500 mg/kg zinc, respectively. Half of each group also received the exercise program. Both blood and liver samples were examined. Free radicals in liver were directly detected by electron spin resonance techniques and the extent of lipid peroxidation was indicated by malonic dialdehyde (MDA). Both CuZn-SOD and Mn-SOD were measured. The results showed that exercise training increased the metabolism of zinc, and zinc deficiency induced an increased free radical generation and lipid peroxidation and a decreased hepatic CuZn-SOD activity in exercised mice. Furthermore, although exercise training had no effect on the level of free radicals in zinc-adequate mice, it could increase the hepatic mitochondrial MDA formation further in zinc-deficient animals and zinc deficiency would eliminate the exercise-induced increase in SOD activities which existed in zinc-adequate mice. A total of 50 mg/kg zinc supplemented in the diet was adequate to correct the zinc-deficient status in exercised mice while 5 mg/kg zinc had a satisfactory effect on the recovery of only sedentary zinc-deficient mice. However, 500 mg/kg zinc had a harmful effect on both sedentary and exercised zinc-deficient animals.     

Utilization by sheep of dried pig faeces containing a high concentration of copper

Seven groups of three sheep were given pelleted diets as follows: A, 97% hay + 3% molasses; B, C, D, 82% hay + 3% molasses + 15% dried pig faeces; E, F, G, 67% hay + 3% molasses + 30% dried pig faeces. In an attempt to counteract potential toxic effects of copper in the pig faeces (613 mg/kg dry matter), molybdenum was added to diets C and F at the rate of 90 mg/kg diet, and to diets D and G at the rate of 175 mg/kg diet. Sulphate was included in all diets at the rate of 1.08% of diet. Measurements were made of digestibility, copper retention, and plasma glutamic oxaloacetic transaminase (GOT) values during a 70-day feeding period, after which the animals were slaughtered.Dry matter digestibility coefficients were : diet A, 49.2; diets B, C, D, 44.4; diets E, F, G, 42.5, from which the coefficient for pig faeces alone is calculated to be < 30. Mean copper retention over the 70 days ranged from 210 mg for diet A to 1225 mg for diet G (excluding diet E which showed an aberrant retention of 53 ± 185 mg). Plasma GOT values fluctuated between diets and between sheep with a maximum value of 182 units/ml. Mean liver copper concentrations ranged from 718 mg/kg dry matter for diet A to 1740 mg/kg for diet E. Necrotic lesions occurred in some livers. Kidneys were apparently normal. There were no clear differences in copper status of animals receiving 15% versus 30% pig faeces except for a tendency for liver damage to be greater in the latter. There were no apparent effects of additions of molybdenum.The pig faeces were poorly utilized and, because of the high copper content, potentially hazardous to the health of the sheep.