Age-Related Features of Ceruloplasmin Biosynthesis and Distribution in Rats

In vivo biosynthesis of ceruloplasmin (Cp), a copper-containing glycoprotein, which plays an important role in copper transfer between organs and bidirectional iron transport in vertebrates, was studied in 7-day old rats, which are characterized by the embryonic type of copper metabolism. In addition to the liver, Cp is synthesized in the lungs, brain, and kidneys. In pulse-chase experiments it was demonstrated that [¹⁴C]-Cp appearance in the blood coincides with the secretion ofde novo synthesized Cp from the liver. [¹⁴C]-Cp is taken up from the blood stream by cells of the heart, lung, and kidneys and binds to red blood cells, while Cp polypeptide chain is not taken up by the brain cells. Immunoreactive polypeptides of the Cp receptor were found using immunoblotting in plasma membranes of the heart, liver, kidneys, and red blood cells, rather than in the brain. Using the RT-PCR method with selective primers, it was shown that these cells contain molecular forms of Cp-mRNAs programming the synthesis of both secretory Cp and Cp bound to the plasma membrane via a glycosyl phosphatidylinositol anchor. After switching to the adult type of copper metabolism, the blood serum contents of copper and Cp sharply increase, while the Cp content in the cerebrospinal fluid, as measured according to the oxidase and antigen activities, and copper concentration, as determined by atomic absorption spectroscopy, remain low. Ontogenetic features of the system ensuring the copper homeostasis in mammals are discussed.     

Iron and copper metabolism in analbuminaemic rats fed a high-iron diet

The metabolism of iron and copper in male Nagase analbuminaemic (NA) and Sprague Dawley (SD) rats was compared. Relative liver weight was higher and spleen weight significantly lower in NA than SD rats. In NA rats, red blood cell count, haemoglobin and haematocrit were lower, whereas plasma transferrin, total iron-binding capacity and mean corpuscular haemoglobin were higher when compared with SD rats. Iron concentrations in plasma, liver, kidneys and heart were higher, and those in the spleen and tibia were lower, in NA rats. The iron concentrations in liver and spleen were positively correlated with the amount of brown pigment as observed histopathologically. Bile flow as well as biliary iron and copper excretion were higher in NA than SD rats. Copper concentrations in liver, kidneys and plasma were higher in NA rats. Plasma levels of ceruloplasmin were about two-fold higher in NA rats. The feeding of a high-iron diet reduced kidney copper concentrations in both strains of rats, which was associated with a decrease in the absorption and biliary excretion of copper.     

Plasma ceruloplasmin Evidence for its presence in and uptake by heart and other organs of the rat

Evidence for the presence of the plasma protein, ceruloplasmin, in heart and other tissues of the rat was sought using various techniques. With p-phenylenediamine, ceruloplasmin-like oxidase activity was detected in heart postmitochondrial and 100 000 × g supernatants in amounts far exceeding those that could be accounted for by residual blood. Much lower levels were detected in kidney, brain and liver. Oxidase activity of heart purified on DEAE-cellulose in the same way as rat plasma ceruloplasmin and behaved identically also in disc gel electrophoresis. The presence of ceruloplasmin in heart extracts was confirmed immunologically by Ouchterlony diffusion, using rabbit antibody raised against pure rat ceruloplasmin. When pure [³H]leucin-labeled ceruloplasmin was infused intravenously into a copper-deficient rat, radioactivity was concentrated in the heart and brain within 2 h; radioactive counts per g attained 11 and 3 times those of plasma in the two organs, respectively. A lesser concentration occurred in the liver. The results suggest that circulating ceruloplasmin (made by the liver) finds its way into the cells of some organs, especially the heart, a phenomenon which may be related to the function of ceruloplasmin to provide copper to the cytochrome oxidase of various tissues.     

Developmental changes of selected minerals in Zucker rats

Effects of obesity and age on copper, iron, zinc, sodium, potassium, and protein were compared in liver, kidney, brain, and muscle of obese (fa/fa) and nonobese (non-fa/fa) male Zucker rats. Blood plasma cerulopasmin, copper, zinc, sodium, and potassium were also determined. Mean brain weight of fa/fa rats was less than that of non-fa/fa rats at 12 weeks of age; mean brain protein concentration was greater in fa/fa than in non-fa/fa at 5 and 12 weeks of age. At 18-19 days of age, mean sodium concentration (mg/g protein) in liver of fa/fa was less than that of non-fa/fa. At 5 weeks of age, mean copper concentration (microgram/g protein) in kidney was greater in fa/fa. Mean total copper, iron, zinc, sodium, and potassium in liver and kidney were greater in fa/fa than in non-fa/fa at 5 weeks because of the larger livers and kidneys of fa/fa. Mean concentrations of copper, zinc, sodium, and potassium per gram of brain protein were slightly (6-10%) less in fa/fa than in non-fa/fa at 5 weeks. By 12 weeks, mean concentrations of copper in liver, kidney, (tibialis) muscle, and blood plasma, ceruloplasmin in blood plasma, zinc in liver and muscle, iron in muscle, and sodium in liver were greater in fa/fa than in non-fa/fa. However, total amount of each mineral in muscle at 12 weeks was less in fa/fa than in non-fa/fa because of the smaller mean muscle weight of fa/fa. Mean concentrations of copper and zinc in brain and of iron in liver and brain were less in fa/fa than in non-fa/fa at 12 weeks. The major age-related changes in fa/fa that were not observed in non-fa/fa were large increases in liver and kidney copper between 5 and 12 weeks of age. It seems that the abnormal mineral metabolism is a consequence of the obesity, but the mechanisms are not identified.     

Evidence for ceruloplasmin as a copper transport protein.

Rats fed a copper-deficient diet for eight weeks showed a large decrease in cytochrome $\text{c}$ oxidase in heart, spleen, liver, lung, and pancreas but no significant change in kidney and brain. Three injections of human or rat ceruloplasmin over a five day period greatly increased cytochrome $\text{c}$ oxidase activity in spleen, liver, heart and lung. Rats receiving CuCl₂, Cu-histidine, and Cu-albumin produced a smaller and slower increase in cytochrome $\text{c}$ oxidase compared to ceruloplasmin treated animals. In Cu-histidine treated rats, the increase in enzyme activity did not occur until after the plasma ceruloplasmin level reached a maximal value. It is concluded that ceruloplasmin functions as a primary copper transport protein from which copper atoms are transferred to cytochrome $\text{c}$ oxidase and probably other copper containing proteins.     

Copper transport and metabolism are normal in aceruloplasminemic mice.

Ceruloplasmin is an abundant serum glycoprotein containing greater than 95% of the copper found in the plasma of vertebrate species. Although this protein is known to function as an essential ferroxidase, the role of ceruloplasmin in copper transport and metabolism remains unclear. To elucidate the role of ceruloplasmin in copper metabolism, the kinetics of copper absorption, transport, distribution, and excretion were examined utilizing (64)Cu in wild-type and aceruloplasminemic mice. No differences in gastrointestinal absorption, hepatic uptake, or biliary excretion were observed in these animals. Furthermore, steady state measurements of tissue copper content utilizing (64)Cu and atomic absorption spectroscopy revealed no differences in the copper content of the brain, heart, spleen, and kidney. Consistent with these findings, the activity of copper-zinc superoxide dismutase in these tissues was equivalent in wild-type and ceruloplasmin-deficient mice. Hepatic iron was elevated 3.5-fold in aceruloplasminemic mice because of the loss of ferroxidase function. Hepatic copper content was markedly increased in aceruloplasminemic mice. As no differences were observed in copper absorption or biliary copper excretion, these data suggest that in these animals, hepatocyte copper intended for ceruloplasmin incorporation is trafficked into a compartment that is less available for biliary copper excretion. Taken together, these data reveal no essential role for ceruloplasmin in copper metabolism and suggest a previously unappreciated complexity to the subcellular distribution of this metal within the hepatocyte secretory pathway.     

Electrolyte composition of cow and calf tissues in health and in acute digestive disturbances]

Sodium, potassium, calcium, magnesium, manganese, zinc and chloride contents in the blood plasma of calves at parturition have been established to correspond to their levels in blood of cows during their calving period. Iron and inorganic phosphorus contents in calves blood plasma appeared to increase and copper content to be lower in this period as compared to postnatal period. By the third day of postnatal ontogenesis sodium concentration in calves blood decreased, copper level increased and the rest indices of water-salts metabolism in calves and adult animals were alike. Digestion disturbances in the calves were accompanied by changes in levels and magnitude of Na+/K+ ratio, magnesium, iron, copper, manganese and zinc contents in blood, liver and kidneys as well as Ca++/Pi ratio in mitochondria and cytosol of liver and jejunum mucose layer cells in comparison with clinically healthy animals.     

Metabolism of zinc and copper in the neonate: Zinc thionein in developing rat brain,heart, lung,spleen, and thymus

In a continuing study of the importance of metallothionein (MT) in the growth and development of neonates, zinc and copper metabolism in rat brain, heart, lung, spleen, and thymus has been analyzed in 5, 10, 15, 20 and 25 day old rats. Total, cytosol, and MT zinc and copper concentrations and organ contents were determined. Zinc, but very little, if any copper was associated with MT in these organs. Concentrations ranged from 0.03 to 3.3 μg Zn in MT/g; organ contents ranged from 0.003 to 2.2 μg Zn in MT/organ. Brain exhibited the highest concentrations and contents of zinc in MT, approaching the levels found in kidneys. Rank order of organ contents of zinc in MT was brain > lung > heart, spleen, thymus, during this neonatal growth period. When organ growth was rapid, a large percentage (20–95%) of the cytosolic zinc present in these organs was associated with MT, as has been previously observed with liver, kidneys, and testes. None of these organs undergoes the dramatic changes in zinc and copper metabolism previously observed in neonatal rat liver and gastrointestinal tract, and in maturing testes. They are more comparable to kidneys in their concentrations of zinc in MT. Like testes, little copper is found in these organs.     

Milk ceruloplasmin and its expression by mammary gland and liver in pigs

Concentrations of ceruloplasmin and copper in milk and blood plasma, the nature of milk ceruloplasmin, and the effects of lactation and gestation on these parameters, as well as the expression of ceruloplasmin mRNA by the mammary gland, were examined in pigs. As seen previously in humans, ceruloplasmin and copper concentrations in sow milk were much higher a few days after birth than 1 month later, averaging 26.5 and 6.6 mg ceruloplasmin/L (by immunoassay) and 1.67 and 0.34 mg total Cu/L, on days 3 and 33 postpartum, respectively. Values for ceruloplasmin oxidase activity (measured with p-phenylene diamine) were 7.8 and 1.3 nmol/min/L, respectively. Daily milk ceruloplasmin production went from 61 to 22 mg/day and daily copper output from 38 to 12 mg/day. In contrast, there was little or no variation in serum ceruloplasmin concentration during lactation or gestation, although total plasma copper was high at the end of gestation. Milk ceruloplasmin was of the same apparent size as serum ceruloplasmin, as determined by SDS-PAGE and immunoblotting, and ceruloplasmin mRNAs of liver and mammary gland were indistinguishable by Northern analysis and RT-PCR of the various exons. Expression of total RNA and ceruloplasmin mRNA, as detected in biopsies of mammary gland, increased markedly upon onset of lactation and then declined during the next month in conjunction with a drop in milk ceruloplasmin production. The results indicate that milk ceruloplasmin, while being the same protein as in plasma, is not derived from the plasma but is produced by the mammary gland.     

Ceruloplasmin in human plasma and its relationships with the copper-albumin complex.

The electron paramagnetic spectrum of human plasma is dominated, in the g = 2 region, by resonances from copper atoms bound to ceruloplasmin, and does not reveal the fraction of copper normally associated with albumin, except in a few cases, where a copper-albumin signal increases with time after blood withdrawal. This copper-albumin complex is responsible for a resonance at a g value below g = 2 in the spectrum of human serum, which has been recently attributed to a modified form of type 2 copper bound to ceruloplasmin [Rylkov, V.V., Tarasiev, M.Y. & Moshkov, K.A. (1991) Eur. J. Biochem. 197, 185-189]. In the plasma, copper associated to albumin comes from ceruloplasmin. Purified ceruloplasmin is unable to exchange copper with albumin, either purified or in plasma. It can not be ruled out that some serum components trigger the metal exchange, in a defence mechanism operating when ceruloplasmin leaks, by unknown processes, its copper content before discharging the metal into the various organs.     

Phosphofructokinase isozymes from human organs and blood cells.

Phosphofructokinase (PFK) isozymes of blood cells and some human tissues were studied by starch gel electrophoresis and immunoprecipitation by anti-muscle and anti-erythrocyte PFK sera. PFK from muscle, heart, brain and placenta were totally precipitated by both antisera. PFK from blood cells (erythrocytes, lymphocytes, granulocytes, platelets) were precipitated more strongly by anti-erythrocyte PFK serum than by anti-muscle PFK serum. Liver, kidney and monoblast PFK were slightly precipitated by both antisera. From the electrophoretic patterns and the immunoprecipitation curves we may conclude that muscle contains the homotetrameric M4 forms; platelet, liver and kidney the homotetrameric E4 form, and blood cells the M-E hybrids. Monoblasts probably contain a E4 type PFK precursor, and heart, placenta and brain, a modified M4 type PFK. Other isozymes, unrelated with muscle and erythrocyte, were revealed in liver and kidney.     

Milk ceruloplasmin is a valuable source of nutrient copper ions for mammalian newborns

This research focuses on the role of milk ceruloplasmin (Cp), the main extracellular copper-containing protein of vertebrates, as a source of copper for newborns. In the first part of the study, Cp concentration and Cp-associated copper were measured in human skimmed milk at the 1st and the 5th days postpartum. It was shown that most of the copper was associated with Cp and that the decrease in copper concentration during lactation was related to the drop of Cp levels. The following in vivo experiments demonstrated that milk [(125)I]Cp per os administered to 6-day-old rats (embryonic-type copper metabolism) was transported into their bloodstream. The electrophoretic mobility and relative molecular weight of [(125)I]Cp transferred through the cellular barrier remained unaltered. However, 22-day-old rats (adult-type copper metabolism) digested the administered milk [(125)I]Cp completely. In the final part of the study, newborn rats were fed with baby formula for 8d. It was found that these rats switched their copper metabolism from embryonic type to adult type earlier than their littermates fed by dams. Activation of Cp gene expression in the liver, increased Cp and copper concentrations in the blood, and reduced copper content of the liver were observed in the rats fed with baby formula. In the brain, no copper concentration change was observed, but Cp and copper concentrations were dramatically increased in the cerebrospinal fluid. The role of milk Cp as a source of copper adapted to embryonic-type copper metabolism is discussed.     

Effect of Silver Ions on Copper Metabolism during Mammalian Ontogenesis

Copper metabolism was studied in laboratory rats that received silver ions with food (Ag diet) from birth for 5, 20, 40, and 180 days. Parameters of the copper status in the blood serum were determined, and data on the distribution of silver ions in the body were obtained. A comparative histological analysis of brain, liver, kidney, and spleen sections of adult rats kept on the Ag diet for 30 or 180 days was performed. Copper and silver content, expression levels of the genes of copper transport proteins, and the activity of copper enzymes were determined in the cells of the liver, the central organ responsible for copper metabolism in mammals. In adult rats kept on the Ag diet for 30 days, copper status parameters dropped to near-zero values. In contrast, these parameters were decreased only twofold in rats that had been kept on the Ag diet for 6 months from birth. At the same time, the expression of genes involved in copper homeostatis was downregulated. The expression of genes that encode copper enzymes was unchanged. The activity of ceruloplasmin, the main copper-containing protein of the blood, was decreased, while the activity of SOD1, a cellular copper enzyme, was unchanged. The pathways by which silver can interfere with copper metabolism and the mechanisms that compensate these effects are discussed. The data obtained may help assess the potential consequences of growing environmental exposure to silver due to increasing use of silver nanoparticles in different areas of human activity.     

Perspectives on copper biochemistry

The biochemistry of the essential trace element copper has been outlined. Following absorption, Cu(II) is transported by serum albumin and transcuprein to the liver where it is incorporated into the plasma Cu-protein, ceruloplasmin, or, possibly, stored as Cu-metallothionein or as superoxide dismutase. Ceruloplasmin is the long-term copper transporter and carries Cu(II) to the tissues for the biosynthesis of key Cu(II) enzymes, especially cytochrome c oxidase, lysyl oxidase and others. The production of copper enzymes raises many new questions about the metabolism of copper. Since ceruloplasmin is the centerpiece of copper metabolism and function, we conclude with more details on its chemistry and multifunctions. This Cu-protein of 132,000 daltons has now been totally sequenced and the copper-containing active sites located. Finally, we have proposed seven possible functions for ceruloplasmin, and there is now good evidence for the existence of ceruloplasmin receptors to expedite some of these functions.     

Stable isotope pilot study of exchangeable copper kinetics in human blood plasma

To develop further our understanding of initial dietary copper metabolism, a method has been developed to separate plasma copper that is bound to albumin, from that bound to ceruloplasmin. This method has been tested using plasma samples from a pilot study involving six human volunteers who consumed 3mg oral doses of the stable isotope (65)Cu and gave blood samples at timed intervals up to 7 days. The results suggest that this method can be used to monitor dynamic fluctuations in newly absorbed copper over a short time frame.     

Membrane proteins involved in the adherence of Plasmodium falciparum-infected erythrocytes to the endothelium.

Plasmodium falciparum (human malaria) infections are characterized by the attachment of erythrocytes infected with mature stage parasites to endothelial cells lining the post-capillary venules, a phenomenon known as sequestration. In the human body, the microvessels of the heart, lungs, kidneys, small intestine, and liver are the principal sites of sequestration. Sequestered cells that clog the brain capillaries may reduce blood flow sufficiently so that there is confusion, lethargy, and unarousable coma--cerebral malaria. This review considers what is known about the molecular characteristics of the surface proteins, that is, the red cell receptors and the endothelial cell ligands, involved in sequestration. Recent work from our laboratory on the characterization of the adhesive proteins on the surface of the P falciparum-infected red cell, and the ligands to which they bind on human brain endothelial cells is also discussed. Finally, consideration is given to the multifactor processes involved in sequestration and cerebral malaria, as well as the possible role of 'anti-adhesion therapy' in the management of severe malaria.     

Effects of sub-chronic low-level lead exposure on the homeostasis of copper and zinc in rat tissues

Information about the health risks or the subtle adverse health effects that might be associated with low-level lead exposure on micronutrient metabolism are scarce in the literature. The present work investigated the subtle adverse health effects of exposure to progressively low levels of lead on the metabolism of two micronutrients, copper and zinc in different tissues of the rat. Rats were exposed to 200, 300 and 400 ppm lead in their drinking water for 12 weeks. Lead, copper and zinc concentrations were determined in blood, liver, kidney, heart, spleen and brain of the animals. While the imbalance in zinc metabolism was characterized by a deposition of zinc in the kidney and to a lesser extent in the heart of the animals, imbalance in copper metabolism was characterized by a depletion of blood and splenic copper concentrations as well as renal and cardiac accumulation of copper. Hepatic and brain copper and zinc contents, together with blood zinc were not affected by the 12-week lead exposure. A linear relationship was observed between lead dose and lead accumulation in the spleen, whereas a non-linear relationship was observed between lead dose and lead accumulation in blood, liver, kidney and heart. Our findings indicate that exposure to progressively low-level lead concentrations results in imbalance in copper and zinc in the organism and this might be a factor in propensity toward behavioral disorders observed in lead exposure.     

A comparative study of the transport dynamics of the peptide moiety of the milk ceruloplasmin molecule in the body of rats with embryonic and adult types of copper metabolism

In chase experiments, we followed the distribution of [125I]-ceruloplasmin prepared from human breast milk orally administered to young rats. Experiments were conducted using six-day-old rat pups (the embryonic type of copper metabolism) or 35-day-old ones (the adult type of copper metabolism). Using the technique of rocket immunoelectrophoresis, we have demonstrated that in six-day-old rats [125I]-ceruloplasmin was transferred from the gastrointestinal tract to the bloodstream and could be detected there over a period of 4 h. In 35-day-old rats, milk ceruloplasmin was digested in the upper part of the intestinal tract. The dynamic aspects of the distribution of labeled milk ceruloplasmin in the body of six-day old rats over a period of 4 h point out that, under the conditions of embryonic copper metabolism, it can serve as a transporter of copper ions to extrahepatic organs. We discuss the role of milk ceruloplasmin in copper metabolism in mammals during the neonatal period.     

Effect of alcohol intoxication on ascorbic and dehydroascorbic acid levels in rat tissue. and human blood

It is found that acute ethanol intoxication is accompanied by a decrease in the ascorbic acid content in the brain, liver and kidneys. The content of dehydroascorbic acid in kidneys in this case increases and in the brain tends to decrease. The chronic alcohol intoxication of rats has an opposite (as compared to the acute intoxication) effect on changes in the content of ascorbic and dehydroascorbic acids in the studied organs. People with chronic alcohol intoxication have the lower content of ascorbic acid in blood plasma and the higher content in erythrocytes, the content of dehydroascorbic acid being increased.