Ivo F. Scheiber

Metabolism and functions of copper in brain

Copper is an important trace element that is required for essential enzymes. However, due to its redox activity, copper can also lead to the generation of toxic reactive oxygen species. Therefore, cellular uptake, storage as well as export of copper have to be tightly regulated in order to guarantee sufficient copper supply for the synthesis of copper-containing enzymes but also to prevent copper-induced oxidative stress. In brain, copper is of importance for normal development. In addition, both copper deficiency as well as excess of copper can seriously affect brain functions. Therefore, this organ possesses ample mechanisms to regulate its copper metabolism. In brain, astrocytes are considered as important regulators of copper homeostasis. Impairments of homeostatic mechanisms in brain copper metabolism have been associated with neurodegeneration in human disorders such as Menkes disease, Wilsons disease and Alzheimers disease. This review article will summarize the biological functions of copper in the brain and will describe the current knowledge on the mechanisms involved in copper transport, storage and export of brain cells. The role of copper in diseases that have been connected with disturbances in brain copper homeostasis will also be discussed.

Astrocyte functions in the copper homeostasis of the brain.

Copper is an essential element that is required for a variety of important cellular functions. Since not only copper deficiency but also excess of copper can seriously affect cellular functions, the cellular copper metabolism is tightly regulated. In brain, astrocytes appear to play a pivotal role in the copper metabolism. With their strategically important localization between capillary endothelial cells and neuronal structures they are ideally positioned to transport copper from the blood-brain barrier to parenchymal brain cells. Accordingly, astrocytes have the capacity to efficiently take up, store and to export copper. Cultured astrocytes appear to be remarkably resistant against copper-induced toxicity. However, copper exposure can lead to profound alterations in the metabolism of these cells. This article will summarize the current knowledge on the copper metabolism of astrocytes, will describe copper-induced alterations in the glucose and glutathione metabolism of astrocytes and will address the potential role of astrocytes in the copper metabolism of the brain in diseases that have been connected with disturbances in brain copper homeostasis.

Zinc prevents the copper-induced damage of cultured astrocytes

Copper is essential for several cellular processes, but an excess of cellular copper is known to be cell toxic. To study the consequences of a copper treatment of astrocytes, we have used astrocyte-rich primary cultures as model system to investigate cellular functions and cellular integrity of these cells after application of micromolar concentrations of copper chloride. After exposure of the cells to copper, the cell-associated copper content increased strongly in a time and concentration dependent manner. While incubation of cultured astrocytes with 3 microM copper hardly affected the cells during incubation for up to 4h, presence of 10 microM or 30 microM copper severly compromised cellular functions as demonstrated by a loss in total and soluble protein contents, a lowered MTT reduction capacity, lowered activities of the enzymes lactate dehydrogenase, glucose-6-phosphate dehydrogenase and glutathione reductase, a lowered cellular glutathione content, an increased lipid peroxidation, and an elevated membrane permeability for propidium iodide. Presence of an excess of zinc inhibited cellular copper accumulation and prevented most of the detrimental consequences of a copper exposure, suggesting that the beneficial effect of zinc against the copper-induced impairment of cultured astrocytes is mediated by inhibition of the cellular copper accumulation.

Copper: Effects of Deficiency and Overload

Copper is an essential trace metal that is required for the catalysis of several important cellular enzymes. However, since an excess of copper can also harm cells due to its potential to catalyze the generation of toxic reactive oxygen species, transport of copper and the cellular copper content are tightly regulated. This chapter summarizes the current knowledge on the importance of copper for cellular processes and on the mechanisms involved in cellular copper uptake, storage and export. In addition, we will give an overview on disturbances of copper homeostasis that are characterized by copper overload or copper deficiency or have been connected with neurodegenerative disorders.

Copper accumulation by cultured astrocytes

To study copper transport in brain astrocytes, we have used astrocyte-rich primary cultures as model system. Cells in these cultures contained a basal copper content of 1.1+/-0.4 nmol per mg protein. The cellular copper content increased strongly after application of copper chloride in a time and concentration-dependent manner. Analysis of the linear copper accumulation during the first 5 min of copper exposure revealed that cultured astrocytes accumulated copper with saturable kinetics with apparent K(M)- and V(max)-values of 9.4+/-1.8 microM and 0.76+/-0.13 nmol/(min x mg protein), respectively. In contrast, incubation of astrocytes with copper in the presence of ascorbate caused a linear increase of the copper accumulation rates for copper concentrations of up to 30 microM. In addition, copper accumulation was strongly inhibited by the presence of an excess of zinc or of various other divalent metal ions. The presence of mRNA and of immunoreactivity of the copper transport protein Ctr1 in astrocyte cultures suggests that Ctr1 contributes to the observed copper accumulation. However, since some characteristics of the observed copper accumulation are not consistent with Ctr1-mediated copper transport, additional Ctr1-independent mechanism(s) are likely to be involved in astrocytic copper accumulation.

Copper-treatment increases the cellular GSH content and accelerates GSH export from cultured rat astrocytes

To test whether copper exposure affects astroglial glutathione (GSH) metabolism, we have exposed astrocyte-rich primary cultures with copper chloride in concentrations of up to 30 μM and investigated cellular and extracellular GSH contents. Cultured astrocytes accumulated copper in a concentration-dependent manner thereby increasing the specific cellular copper content within 24h up to sevenfold. The increase in the cellular copper content was accompanied by a proportional increase in the specific cellular GSH content that reached up to 165% of the values of cells that had been incubated without copper, while the low cellular content of GSH disulfide (GSSG) remained unaltered in copper-treated cells. Also the rate of GSH export was significantly increased after copper exposure reaching up to 177% of control values. The export of GSH from control and copper-treated astrocytes was lowered by more than 70%, if cells were incubated in presence of the multidrug-resistance protein (Mrp) 1 inhibitor MK571 or at a low incubation temperature of 4°C. These data demonstrate that copper accumulation stimulates GSH synthesis and accelerates Mrp1-mediated GSH export from cultured astrocytes. These processes are likely to contribute to the resistance of astrocytes against copper toxicity and could improve the supply of GSH precursors from astrocytes to neurons.

Copper metabolism of astrocytes

Copper is an essential trace element which is involved in many important cellular functions [1]. However, excess of copper can impair cellular functions by copper-induced oxidative stress. In brain, astrocytes are considered to play a prominent role in antioxidative defence as well as in the copper homeostasis [1, 2]. To investigate uptake, toxicity, storage and export of copper in astrocytes, we used primary rat astrocyte cultures as model system. Cultured astrocytes efficiently take up copper ions predominantly by the copper transporter Ctr1 and the divalent metal transporter DMT1. In addition, copper oxide nanoparticles are rapidly accumulated by astrocytes, most likely by endocytotic processes. Astrocytes tolerate moderate increases in intracellular copper contents very well. However, if the specific cellular copper content exceeds after exposure to copper or copper oxide nanoparticles a threshold level of around 10 nmol copper/mg protein, accelerated production of reactive oxygen species and compromised cell viability were observed. Upon exposure to sub-toxic concentrations of copper ions or copper oxide nanoparticles, astrocytes increase their copper storage capacity by upregulating the cellular contents of glutathione and metallothioneins. In addition, cultured astrocytes have the capacity to export copper ions which is likely to involve the copper-transporting ATPase 7A. The ability of astrocytes to efficiently accumulate, store and export copper ions suggests that astrocytes play a key role in brain copper homeostasis and that an impairment of astrocytic functions may be involved in diseases which are connected with disturbances in brain copper metabolism.

Synergistic accumulation of iron and zinc by cultured astrocytes

Iron and zinc are essential for normal brain function, yet the mechanisms used by astrocytes to scavenge non-transferrin-bound iron (NTBI) and zinc are not well understood. Ischaemic stroke, traumatic brain injury and Alzheimer’s disease are associated with perturbations in the metabolism of NTBI and zinc, suggesting that these two metals may collectively contribute to pathology. The present study has investigated the accumulation of NTBI and zinc by rat primary astrocyte cultures. It was found that astrocytes express mRNA for both divalent metal transporter 1 (DMT1) and Zip14, indicating the potential for these transporters to contribute to the accumulation of NTBI and zinc by these cells. Astrocytes were found to accumulate iron from ferric chloride in a time- and dose-dependent manner, and the rate of accumulation was strongly stimulated by co-incubation with zinc acetate. In addition, cultured astrocytes rapidly accumulated zinc from zinc acetate, and this accumulation was stimulated by co-incubation with ferric chloride. Because a synergistic stimulation of iron and zinc accumulation is inconsistent with the known properties of DMT1 and Zip14, the present results suggest that additional mechanisms assist astrocytes to scavenge iron and zinc when they are present together in the extracellular compartment. These mechanisms may be involved in disorders that involve elevations in the extracellular concentrations of these metal ions.

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.

Ostreococcus tauri is a new model green alga for studying iron metabolism in eukaryotic phytoplankton

BackgroundLow iron bioavailability is a common feature of ocean surface water and therefore micro-algae developed original strategies to optimize iron uptake and metabolism. The marine picoeukaryotic green alga Ostreococcus tauri is a very good model for studying physiological and genetic aspects of the adaptation of the green algal lineage to the marine environment: it has a very compact genome, is easy to culture in laboratory conditions, and can be genetically manipulated by efficient homologous recombination. In this study, we aimed at characterizing the mechanisms of iron assimilation in O. tauri by combining genetics and physiological tools. Specifically, we wanted to identify and functionally characterize groups of genes displaying tightly orchestrated temporal expression patterns following the exposure of cells to iron deprivation and day/night cycles, and to highlight unique features of iron metabolism in O. tauri, as compared to the freshwater model alga Chalamydomonas reinhardtii.ResultsWe used RNA sequencing to investigated the transcriptional responses to iron limitation in O. tauri and found that most of the genes involved in iron uptake and metabolism in O. tauri are regulated by day/night cycles, regardless of iron status. O. tauri lacks the classical components of a reductive iron uptake system, and has no obvious iron regulon. Iron uptake appears to be copper-independent, but is regulated by zinc. Conversely, iron deprivation resulted in the transcriptional activation of numerous genes encoding zinc-containing regulation factors. Iron uptake is likely mediated by a ZIP-family protein (Ot-Irt1) and by a new Fea1-related protein (Ot-Fea1) containing duplicated Fea1 domains. The adaptation of cells to iron limitation involved an iron-sparing response tightly coordinated with diurnal cycles to optimize cell functions and synchronize these functions with the day/night redistribution of iron orchestrated by ferritin, and a stress response based on the induction of thioredoxin-like proteins, of peroxiredoxin and of tesmin-like methallothionein rather than ascorbate. We briefly surveyed the metabolic remodeling resulting from iron deprivation.ConclusionsThe mechanisms of iron uptake and utilization by O. tauri differ fundamentally from those described in C. reinhardtii. We propose this species as a new model for investigation of iron metabolism in marine microalgae.