Effect of Copper on Growth of Yeast

The effect of copper was tested on the growth of many strains of yeast. Plate culture on density gradient agar of copper was used for estimating the growth response to copper. Growth in many strains was more strongly inhibited by the copper-aquo complex than by the copper-amino acid complex. Debaryomyces hansenii IFO 023 was found a suitable strain for the present study, because it was not resistant, not producing H₂S, and copper absorption by this strain was similar to that of the resistant strain. Growth of yeast cells in medium containing copper was affected by pH and concentration of amino acid in medium. Absorption of copper into intact cells was almost saturated for the initial few minutes. It was also affected by the addition of amino acid to copper solution. Our results indicated that the growth response of yeast to copper was closely related to copper absorption into cells. About 60 percent of copper absorbed into cells was distributed in the soluble fraction of the cell homogenate which was obtained by centrifugation at 105,000 g for 60 min.     

Effects of promoter mutations on the in vivo regulation of the cop operon of Enterococcus hirae by copper(I) and copper(II).

The cop operon of Enterococcus hirae encodes a repressor, CopY, a copper chaperone, CopZ, and two copper ATPases, CopA and CopB. Regulation of the cop operon is bi-phasic, with copper addition as well as copper chelation leading to induction. Using a plasmid-borne system with a reporter gene, induction of wild-type and mutant cop promoters by high and low copper conditions was investigated. Only mutations that impaired the interaction of CopY with both DNA binding sites had a marked effect on regulation, leading to hyperinduction by copper(I) or copper(II). Chelation of copper(II), but not copper(I), also induced the operon, but induction by copper chelation was not significantly affected by the mutations. E. hirae mutants with reduced extracellular copper reductase activity exhibited the same induction kinetics as wild-type cells. These results show that copper addition and copper chelation induce the cop operon by different routes.     

Copper export from cultured astrocytes

Copper is an essential trace metal that is required as a catalytic co-factor or a structural component of several important enzymes. However, since excess of copper can also harm cells due to its potential to catalyse the generation of toxic reactive oxygen species, transport of copper and the cellular copper content are tightly regulated. Astrocytes are known to efficiently take up copper ions, but it was not known whether these cells are also able to export copper. Treatment of astrocyte-rich primary cultures for 24 h with copper chloride caused a concentration-dependent increase in the specific cellular copper content. During further 24 h incubation in the absence of copper chloride, the copper-loaded astrocytes remained viable and released up to 45% of the accumulated copper. The rate of copper export was proportional to the amount of cellular copper, was almost completely prevented by lowering the incubation temperature to 4 °C and was partly prevented by the endocytosis inhibitor amiloride. Copper export is most likely mediated by the copper ATPase ATP7A, since this transporter is expressed in astrocyte cultures and its cellular location is strongly affected by the absence or the presence of extracellular copper. The potential of cultured astrocytes to export copper suggests that astrocytes provide neighbouring cells in brain with this essential trace element.     

Copper reduction by yeast cell wall materials and its role on copper uptake in Debaryomyces hansenii

Copper binding reducing activities of cell wall materials (CWM) prepared from cells of the yeast Debaryomyces hamsenii were examined. When CWM was treated with copper sulfate (0.1 mM CuSO₄), the copper was partially reduced from Cu (II) to Cu (I) and bound to CWM (below 10 nmol per mg dry wt.). The bound copper was mostly in the fraction of mannan-protein. Both copper-binding ability and protein content decreased with protease treatments. Mannan-protein prepared from CWM bound more copper than mannan did. This suggests that Cu (II) bound to the protein portion in CWM and was reduced to Cu (I). The optimum pH of copper reduction by CWM was about 5.0. The amount of copper bound to CWM increased with reducing agents and decreased with oxidizing agents. On the other hand, the copper uptake by yeast whole cells and spheroplasts was also stimulated by reducing agents, but inhibited by oxidizing agents. Furthermore, copper uptake by spheroplasts was stimulated in the presence of CWM. The optimum pH of copper uptake coincided with that of copper reducing activity. These results suggest that yeast cell wall not only supplies copper binding but also reduces copper, and the reduced copper is transported into yeast cells. The yeast cells may have copper-reducing proteins in the cell wall.     

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.     

Copper biosorption by Pseudomonas cepacia and other strains

Biosorption of copper by Pseudomonas cepacia was found to be dependent on added copper concentration. Copper uptake by the cells was rapid over the range of copper concentrations tested and complete within the first 10 min of incubation time. The effect of pH on copper uptake by P. cepacia was determined using overlapping buffers over the pH range 3–8, and copper biosorption from a 10 mM copper solution was greatest at pH 7. Copper uptake (measured by analysis of cell digests) was unaffected by cyanide and azide (up to 30 mM) and by incubation of cells with a 10 mM copper solution at 4 °C. Evidence from these results suggested that copper uptake by P. cepacia cells involves surface binding and not intracellular accumulation by active transport. Biosorption of copper by various Pseudomonas isolates from metal-contaminated environments agreed well with copper biosorption by Pseudomonas strains from the National Collection of Type Cultures (NCTC).     

The use of waste biomass of Sargassum sp. for the biosorption of copper from simulated semiconductor effluents

Seaweed Sargassum sp. biomass proved to be useful for the recovery of ionic copper from highly concentrated solutions simulating effluents from semiconductor production. In the case of solutions containing copper in the form of chloride, sulphate and nitrate salts, the best pH for the recovery of copper was 4.5. It was observed that copper biosorption from copper nitrate solutions was higher than the recovery of copper from copper chloride or sulphate solutions. The continuous system used was constituted of four column reactors filled with the biomass of Sargassum sp. and showed high operational stability. Biomass of Sargassum sp. in the reactors was gradually saturated from the bottom to the top of each column reactor. The biomass of Sargassum sp. in the first column was saturated first, followed by a gradual saturation of the remaining columns due to the pre-concentration caused by the biomass in the first column. The biomass of Sargassum in the bioreactors completely biosorbed the ionic copper contained in 63 L of copper sulphate solution, 72 L of copper chloride solution and 72 L of copper nitrate solution, all the solutions containing copper at 500 mg/L. Effluents produced after biosorption presented copper concentrations less than 0.5 mg/L.     

A quick microwave histochemical stain for copper

A rapid microwave method is described for staining copper in liver. This procedure was compared with a conventional method for copper. To this end, liver sections obtained from patients affected by several liver diseases associated with copper overload, were stained both with the standard rubeanic acid method for copper and with our modification of the same method, incorporating microwave treatment. Liver sections from a normal human newborn were used as a positive control. In Wilson's disease in the cirrhotic stage, copper was detected by the conventional method solely in periportal cells; following the microwave treatment, we were able to demonstrate copper in the whole lobule. In alcoholic cirrhosis, rubeanic acid stained copper only in a few periportal cells, while, by our modified method, copper was detected in almost all periportal hepatocytes. In chronic biliary tract disease, and in the newborn liver, copper was demonstrated in a few periportal cells by both the two histochemical procedures. In conclusion, although copper was detected by both procedures, a different degree of positivity was sometimes observed by using microwaves. Moreover, the microwave-treated sections showed more contrast and less artifacts. From a practical point of view, for the simplicity of employment and, above all, for its quickness (10 min), we suggest the use of our method in all conditions where copper overload is suspected.     

Amine Oxidases of Microorganisms

There was an increase in copper content proportional to the increase in specific activity of the enzyme during the purification of amine oxidase of Aspergillus niger. The recrystallized enzyme preparation contained 1 g atom of copper per 83,000 g of protein. This indicated that the enzyme contained 3 g atoms of copper per mole of enzyme. The copper in the enzyme was removed by dialysis against sodium diethyldithiocarbamate with concomitant loss of activity. The dialyzed enzyme was reactivated by the addition of cupric copper.

The copper in the enzyme was present in cupric state. No valency change of the copper was observed in the catalytic activity.

The enzyme was inhibited by various chelating agents, and potently inhibited by various carbonyl reagents.     

黏土矿物中重金属离子的吸附规律及竞争吸附

采用等温吸附法,研究了重金属铜、铅、镉、镍在膨润土中的吸附特征,发现膨润土对铜、铅的吸附明显强于镉、镍,吸附强度大小顺序为Pb2 >Cu2 >Ni2 >Cd2 。Langmuir和Freundlich方程对这4种金属离子等温吸附的拟合均呈极显著关系。Pb2 、Cd2 、Ni2 分别与Cu2 的双组分竞争吸附表明,黏土矿物对4种离子具有"选择性吸附"。在Pb2 、Ni2 、Cd2 的存在条件下,黏土矿物对Cu2 的吸附产生不同程度的下降;100mg/LCu2 对Pb2 的影响不大,但可完全抑制Ni2 、Cd2 的吸附。建立了IAS和LCA模型来预测Pb2 与Cu2 的双组分竞争吸附,并对LCA模型进行修正,提出了更符合实际情况的竞争吸附模型。文章最后用LCA修正模型对Pb2 与Cu2 的双组分竞争吸附进行了模拟。     

Albumin has no role in the uptake of copper by human fibroblasts

The mechanism of copper uptake by cells has been the subject of controversy for some time. This paper examines the possibility of a role for albumin in the uptake of copper by fibroblasts. Although the cells could accumulate copper from a copper-albumin complex, there was no evidence for either copper-albumin or albumin receptors on the cell surface. The possibility of a surface exchange mechanism for copper was examined. While copper uptake showed saturation with increasing concentrations of labelled copper-albumin, adding unlabelled copper to the incubation medium did not inhibit uptake. Adding albumin or histidine to the copper-albumin complex resulted in an inhibition of copper uptake. The results can only be explained by the cell taking up free copper from the incubation medium, with the albumin then releasing its copper to maintain the equilibrium between free and bound metal. Since, in vivo there is essentially no free copper in serum, it is concluded that albumin is most unlikely to play a role in the uptake of copper by fibroblasts.     

Protective<Emphasis Type="Italic">in vivo</Emphasis> effect of curcumin on copper genotoxicity evaluated by comet and micronucleus assays

Curcumin is a phytochemical with antiinflammatory, antioxidant and anticarcinogenic activities. Apparently, curcumin is not genotoxic in vivo, but in vitro copper and curcumin interactions induce genetic damage. The aim of this study was to test if in vivo copper excess induces DNA damage measured by comet and micronucleus assays in the presence of curcumin. We tested 0.2% curcumin in Balb-C mice at normal (13 ppm) and high (65, 130 and 390 ppm) copper ion concentrations. The comet and micronucleus assays were performed 48 hr after chemical application. Comet tail length in animals treated with 0.2% curcumin was not significantly different from the control. Animals exposed to copper cations (up to 390 ppm) exhibited higher oxidative DNA damage. Curcumin reduced the DNA damage induced by 390 ppm copper. We observed statistically significant increase in damage in individuals exposed to 390 ppm copper versus the control or curcumin groups, which was lowered by the presence of curcumin. Qualitative data on comets evidenced that cells from individuals exposed to 390 ppm copper had longer tails (categories 3 and 4) than in 390 ppm copper + curcumin. A statistically significant increase in frequency of micronucleated erythrocytes (MNE/10000TE) was observed only in 390 ppm copper versus the control and curcumin alone. Also cytotoxicity measured as the frequency of polychromatic erythrocytes (PE/1000TE) was attributable to 390 ppm copper. The lowest cytotoxic effect observed was attributed to curcumin. In vivo exposure to 0.2% curcumin for 48 hr did not cause genomic damage, while 390 ppm copper was genotoxic, but DNA damage induced by 390 ppm copper was diminished by curcumin. Curcumin seems to exert a genoprotective effect against DNA damage induced by high concentrations of copper cations. The comet and micronucleus assays prove to be suitable tools to detect DNA damage by copper in the presence of curcumin.     

Relationships of vegetation to copper and cobalt in the copper clearings of Haut Shaba, Zaire

The vegetation of two copper clearings at Tenke Fungurumi in Zaire is described. The copper content ol the soil varied between 1000 to 130,000 ppm. Areas of highest soil copper (above 6–7000 ppni) were colonized primarily by grasses particularly Eragrostis boehmii, Sporobolus rangei and Loudetia simplex but also by other specialized cupriferous species including Becium aureoviride, Dasystachys pulchella, Anisopappus hoffmannianus and Pandiaka metallorum. Soils with 1000 to 7000 ppm copper were colonized by a community dominated by Loudetia simplex and a morphologically distinct form of Cryptosepalum maravieme. The percentage cover of Cryptosepalum was negatively correlated with soil copper. Uapaca robynsii , the most copper-tolerant woody plant, grew below 1500 ppm copper and was normally replaced by other species below approximately 1000 ppm.
The gross morphology oi Xerophyta equisetoides on three sites at Dikuluwe was investigated in relation to the soil characteristics. The growth form on Dikuluwe Hill (11,000 to 111,000 ppm copper) and a nearby non-cupriferous hill (100–200 ppm copper) were basically similar, although the morphology of the Dikuluwe Hill population was probably affected by soil copper and water stress. A distinct morphological form grew on a cupriferous (4000–5000 ppm copper) dembo site.     

Copper inhibits the water and glycerol permeability of aquaporin-3

Aquaporin-3 (AQP3) is an aquaglyceroporin expressed in erythrocytes and several other tissues. Erythrocytes are, together with kidney and liver, the main targets for copper toxicity. Here we report that both water and glycerol permeability of human AQP3 is inhibited by copper. Inhibition is fast, dose-dependent, and reversible. If copper is dissolved in carbonic acid-bicarbonate buffer, the natural buffer system in our body, doses in the range of those observed in Wilson disease and in copper poisoning caused significant inhibition. AQP7, another aquaglyceroporin, was insensitive to copper. Three extracellular amino acid residues, Trp128, Ser152, and His241, were identified as responsible for the effect of copper on AQP3. We have previously shown that Ser152 is involved in regulation of AQP3 by pH. The fact that Ser152 mediates regulation of AQP3 by copper may explain the phenomenon of exquisite sensitivity of human erythrocytes to copper at acidic pH. When AQP3 was co-expressed with another AQP, only glycerol but not water permeability was inhibited by copper. Our results provide a better understanding of processes that occur in severe copper metabolism defects such as Wilson disease and in copper poisoning.     

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.     

High Copper Levels Promotes Broiler Hepatocyte Mitochondrial Permeability Transition In Vivo and In Vitro

This study was to examine the effects of copper on the mitochondrial non-specific pore. Three hundred sixty, one-day-old, healthy Arbor Acres (AA) broilers were fed with different concentrations (11, 110, 220, and 330?mg/kg) of copper originated from copper sulfate, tribasic copper chloride (TBCC), or copper methionine. At the indicated time point, the mitochondrial permeability transition (MPT) and copper concentration were analyzed. Results showed that under the same copper concentration, the MPT of broilers fed copper methionine was the greatest, followed by TBCC, then copper sulfate. The effects of copper on MPT were time- and dose-dependent. Furthermore, in vitro in the presence of K(+), 5?μM Cu(2+) could cause permeability transition as compared to 10?μM Cu(2+) in buffer without K(+). Taking these results together, we have shown that hepatocellular MPT may be influenced not only by source and concentration of copper or the raising period of broilers, but also by the existence of K(+).     

Ascorbic acid feeding of rats reduces copper absorption,causing impaired copper status and depressed biliary copper excretion

The feeding of diets enriched with ascorbic acid (10 g/kg) to rats has previously been shown to lower plasma and liver copper concentrations. The present studies corroborate this. We hypothesized that ascorbic acid initially reduces copper absorption, this effect being masked later by the stimulatory effect on copper absorption of the impaired copper status. We also hypothesized that the impaired copper status as induced by ascorbic acid feeding is followed by a diminished biliary excretion of copper in an attempt to preserve copper homeostasis. Our hypotheses are supported by the present studies. Ascorbic acid feeding initially reduced apparent copper absorption, and in the course of the experiment this effect tended to turn over into a stimulatory effect. Copper deficiency, as induced by feeding a diet containing 1 mg Cu/kg instead of 5 mg Cu/kg, systematically increased copper absorption. Biliary excretion of copper in rats given ascorbic acid was unaffected initialy but became depressed after prolonged ascorbic acid feeding. A similar time course was seen for fecal endogenous copper excretion that was calculated as the difference between true and apparent copper absorption. Copper deficiency systematically reduced biliary copper excretion and fecal endogenous copper loss.     

Copper induction of lactate oxidase of Lactococcus lactis: a novel metal stress response

Lactococcus lactis IL1403, a lactic acid bacterium widely used for food fermentation, is often exposed to stress conditions. One such condition is exposure to copper, such as in cheese making in copper vats. Copper is an essential micronutrient in prokaryotes and eukaryotes but can be toxic if in excess. Thus, copper homeostatic mechanisms, consisting chiefly of copper transporters and their regulators, have evolved in all organisms to control cytoplasmic copper levels. Using proteomics to identify novel proteins involved in the response of L. lactis IL1403 to copper, cells were exposed to 200 muM copper sulfate for 45 min, followed by resolution of the cytoplasmic fraction by two-dimensional gel electrophoresis. One protein strongly induced by copper was LctO, which was shown to be a NAD-independent lactate oxidase. It catalyzed the conversion of lactate to pyruvate in vivo and in vitro. Copper, cadmium, and silver induced LctO, as shown by real-time quantitative PCR. A copper-regulatory element was identified in the 5' region of the lctO gene and shown to interact with the CopR regulator, encoded by the unlinked copRZA operon. Induction of LctO by copper represents a novel copper stress response, and we suggest that it serves in the scavenging of molecular oxygen.