Yeast copper–zinc superoxide dismutase can be activated in the absence of its copper chaperone

Copper–zinc superoxide dismutase (Sod1) is an abundant intracellular enzyme that catalyzes the disproportionation of superoxide to give hydrogen peroxide and dioxygen. In most organisms, Sod1 acquires copper by a combination of two pathways, one dependent on the copper chaperone for Sod1 (CCS), and the other independent of CCS. Examples have been reported of two exceptions: Saccharomyces cerevisiae, in which Sod1 appeared to be fully dependent on CCS, and Caenorhabditis elegans, in which Sod1 was completely independent of CCS. Here, however, using overexpressed Sod1, we show there is also a significant amount of CCS-independent activation of S. cerevisiae Sod1, even in low-copper medium. In addition, we show CCS-independent oxidation of the disulfide bond in S. cerevisiae Sod1. There appears to be a continuum between CCS-dependent and CCS-independent activation of Sod1, with yeast falling near but not at the CCS-dependent end.     

Enzyme-bound copper of dopamine β-monooxygenase.: Activation of the holoenzyme by added copper and uncoupling of electron transfer from hydroxylation by copper salicylate

Preparations of dopamine β-monooxygenase containing a full complement of copper (4.2 copper atoms per tetramer) show increased ascorbate-supported catalytic activities after addition of an excess of copper ions. The significance ot this observation on the question of the number of copper atoms per active site is discussed.Low molecular weight copper complexes such as copper salicylate cause uncoupling of electron transport from hydroxylation. This uncoupling is probably the reason for the well-known inhibition of this enzyme observed at high copper concentration.The onset of inhibition by the copper chelator bathocuproine disulfonate occurs on a faster time scale than the removal of enzyme-bound copper. Nevertheless, the copper removal is sufficiently rapid to require that it be considered in interpretation of inhibition experiments with chelators.     

Novel speciation analysis of copper in river water: observation of soluble anionic copper–ligand complexes

In natural water, copper is believed to be complexed with organic materials such as humic and fulvic acids, as well as anthropogenic substances such as ethylenediaminetetraacetic acid (EDTA). The nature of the complexes is known to be a main factor in determining copper toxicity to aquatic biota, as well as its geochemical transport. In this study, organically chelated copper species in river water were revealed to be classified into hydrophobic and anionic components using column cartridge separation techniques based on C18 and anion exchange. The amounts of anionic ligated copper species in the tested water samples ranged from 0 to 46 nM, and the average contribution of the anionic ligated copper to the total dissolved copper concentration was around 30 %. Several water samples contained discharged sewage effluents with high contents of EDTA, which may be the main chelating agent responsible for copper retention on the anionic ion exchange cartridge column. However, most of the river water samples were not contaminated with EDTA, and therefore, fulvic substances are expected to be responsible for retention. As this is the first observation of anionic copper species in the natural aquatic environment, further geochemical and biological studies of these substances should be undertaken.     

Absorption of copper and copper–histidine complexes across the apical surface of freshwater rainbow trout intestine

Bioavailability is integral in mediating the delicate balance between nutritive and potentially toxic levels of copper in fish diets. Brush-border membrane vesicles isolated from freshwater rainbow trout intestine were used to characterise apical copper absorption, and to examine the influence of the amino acid histidine on this process. In the absence of histidine, a low affinity, high capacity copper uptake mechanism was described. However, when expressed as a function of ionic copper (Cu²⁺), absorption was linear, rather than saturable, suggesting that the saturable curve was an artifact of copper speciation. Conversely, in the presence of l-histidine (780 μM) saturable uptake was characterised. The uptake capacity discerned (J _max of 354 ± 81 nmol mg protein⁻¹ min⁻¹) in the presence of histidine indicated a significantly reduced capacity for copper transport than that in the absence of histidine. To determine if copper uptake was achievable through putative histidine uptake pathways, copper and histidine were incubated in the presence of tenfold greater concentrations of amino acids proposed to block histidine transporters. Accounting for changes in copper speciation, significant inhibition of uptake by glycine and lysine were noted at copper levels of 699 and 1,028 μM. These results suggest that copper–histidine complexes may be transportable via specific amino acid-transporters in the brush-border membrane.     

Is the Western diet adequate in copper?

Copper has been known to be essential for health for more than three quarters of a century. Myriad experiments with animals reveal that the cardiovascular, musculoskeletal and nervous systems are most sensitive to deficiency. Copper in the Western diet has been decreasing at least since the 1930s; half of the adult population consumes less than the amount recommended in the European Communities and the United Kingdom. At least one fourth of adults consume less than the estimated average requirement published for the United States and Canada. Hundreds of people have been reported in journals about medicine and neurology rather than nutrition to have impaired copper nutriture based on the criteria of low copper concentrations and low activities of enzymes dependent on copper in various fluids and tissues. In contrast, only 46 people have participated in depletion/repletion experiments needed to define requirements. Almost 1000 people have benefited from supplements containing copper in controlled trials. People deficient in copper are being identified increasingly; it is unknown if unusually high requirements or unusually low diets are causal. Alzheimer's disease, ischemic heart disease and osteoporosis are the most likely human illnesses from low copper intakes.     

The reaction of zinc sulphide with ionic copper—the biological implications. Part 1. Surface area studies of zinc sulphide and its reaction with copper complexes and copper containing proteins

The role of metal sulphides vis-à-vis the availability of dietary copper in ruminant animals has been investigated using zinc sulphide as a model metal sulphide and a selection of copper complexes and copper containing proteins as models for sources of dietary copper. The extent of reactivity of zinc sulphide towards the copper complexes is dependent upon the type of donor atom co-ordinated to copper:

The order to reactivity is found to be CuO > CuN > CuS complexes and is in keeping with the reported values for the instability constant pK_n of the complexes. In contrast, no reaction is observed between zinc sulphide and the copper containing proteins studied (azurin, superoxide dismutase and cerulophasmin) and is attributed to the protection of the copper centres by the protein backbone. The results facilitate an understanding of copper metabolism in ruminants and a mechanism is proposed for the removal of dietary copper sources in such species.Reactions between copper(II) sulphate solutions and samples of zinc sulphide having a range of specific surface areas (prepared by sintering at differing temperatures) have been studied. The fact that the reactivity is found to be highly dependent upon the specific surface area of the metal sulphide may well be of significance when considering the fate of copper in sulphur-rich biological systems.     

Infrared spectroscopic characterization of copper–polyhistidine from 1,800 to 50 cm−1: model systems for copper coordination

Poly(l-histidine) and imidazole in the presence of copper cations have been investigated by means of Fourier transform infrared (IR) spectroscopy in the mid- and far-IR spectral range to establish specific marker bands of the copper-coordination site in metalloproteins as a function of pH as well as the effect of the coordination on the amino acid contributions. Whereas the well-known mid-IR region was specific for the secondary structure of the protein mimics, the far-IR region included contributions from the metal–ligand vibrations. The addition of copper led to secondary structure changes of poly(l-histidine) at neutral and basic pD and to specific shifts of ring vibrations. At pD 9.5 the addition of copper deprotonated the nitrogen atoms of the imidazole ring and the backbone. At neutral pD the copper cations were coordinated by the N3 atom of the imidazole ring. Copper–imidazole vibrations at neutral pD were observed at 154 and 128 cm⁻¹. Signals observed at 313 and 162 cm⁻¹ were assigned to metal–ligand vibrations arising from copper–poly(l-histidine) complexes with a negatively charged imidazole ring.     

The chemistry of copper binding to PrP: is there sufficient evidence to elucidate a role for copper in protein function?

There has been an enormous body of literature published in the last 10 years concerning copper and PrP (prion protein). Despite this, there is still no generally accepted role for copper in the function of PrP or any real consensus as to how and to what affinity copper associates with the protein. The present review attempts to look at all the evidence for the chemistry, co-ordination and affinity of copper binding to PrP, and then looks at what effect this has on the protein. We then connect this evidence with possible roles for PrP when bound to copper. No clear conclusions can be made from the available data, but it is clear from the present review what aspects of copper association with PrP need to be re-investigated.     

Compact conformations of α-synuclein induced by alcohols and copper

The intrinsically disordered protein α-synuclein aggregates into amyloid fibrils, a process known to be implicated in several neurodegenerative states. Partially folded forms of the protein are thought to trigger the aggregation process. Here, α-synuclein conformers are characterized by analysis of the charge-state distributions observed in electrospray-ionization mass spectrometry under negative-ion mode. It is found that, even at neutral pH, a small fraction of the molecular population is in a compact conformation. Several distinct partially folded forms are then identified under conditions that promote α-synuclein aggregation, such as solutions of simple and fluorinated alcohols. Specific intermediates accumulate at increasing concentrations of ethanol, hexafluoro-2-propanol, and trifluoroethanol. Finally, extensive folding induced by Cu(2+) binding is revealed by titrations in the presence of Cu(2+)-glycine. The data confirm the existence of a single, high-affinity binding site for Cu(2+). Because accumulation of this partially folded form correlates with enhancement of fibrillation kinetics, it is likely to represent an amyloidogenic intermediate in α-synuclein conformational transitions.     

Is there a role for copper in neurodegenerative diseases?

Copper is an essential metal in living organisms; thus, the maintenance of adequate copper levels is of vital importance and is highly regulated. Dysfunction of copper metabolism leading to its excess or deficiency results in severe ailments. Two examples of illnesses related to alterations in copper metabolism are Menkes and Wilson diseases. Several proteins are involved in the maintenance of copper homeostasis, including copper transporters and metal chaperones. In the last several years, the beta-amyloid-precursor protein (beta-APP) and the prion protein (PrP(C)), which are related to the neurodegenerative disorders Alzheimer and prion diseases respectively, have been associated with copper metabolism. Both proteins bind copper through copper-binding domains that also have been shown to reduce copper in vitro. Moreover, this ability to reduce copper is associated with a neuroprotective effect exerted by the copper-binding domain of both proteins against copper in vivo. In addition to a functional link between copper and beta-APP or PrP(C), evidence suggests that copper has a role in Alzheimer and prion diseases. Here, we review the evidence that supports both, the role of beta-APP and PrP(C), in copper metabolism and the putative role of copper in neurodegenerative diseases.     

Simon Labbé's work on iron and copper homeostasis

Iron and copper have a wealth of functions in biological systems, which makes them essential micronutrients for all living organisms. Defects in iron and copper homeostasis are directly responsible for diseases, and have been linked to impaired development, metabolic syndromes and fungal virulence. Consequently, it is crucial to gain a comprehensive understanding of the molecular bases of iron- and copper-dependent proteins in living systems. Simon Labbé maintains parallel programs on iron and copper homeostasis using the fission yeast Schizosaccharomyces pombe (Schiz. pombe) as a model system. The study of fission yeast transition-metal metabolism has been successful, not only in discerning the genes and pathways functioning in Schiz. pombe, but also the genes and pathways that are active in mammalian systems and for other fungi.     

Effects of methamidophos and glyphosate on copper sorption-desorption behavior in soils

A batch-equilibration technique was employed to study the impact of two organo-phosphorus pesticides methamidophos (MDP) and glyphosate (GPS) on copper (Cu2+) sorption-desorption for phaeozem and burozem collected from Northeastern China. The addition of the two pesticides decreased Cu2+ sorption, increased Cu2+ desorption and prolonged the equilibrium time of Cu2+ sorption-desorption. But GPS appeared to exert a stronger influence on Cu2+ sorption-desorption due to its stronger complexion with Cu2+. When MDP was added, Cu2+ sorption-desorption was linearly correlated with MDP treatment concentrations. But in the presence of GPS, Cu2+ sorption first underwent a rapid decrease period, and then slowly tended towards a steady period. The reverse pattern could be found for Cu2+ desorption in the presence of GPS. Without pesticides and with the existence of MDP, Cu2+ sorption-desorption kinetics was well conformed to two-constant equation and Elovich equation. But that was not the case for Cu2+ desorption kin     

Promotion of atherogenesis by copper or iron--which is more likely?

Iron levels increase in atherosclerotic lesions in cholesterol fed-rabbits and play a role in atherosclerosis. We investigated whether copper also rises. Male New Zealand White rabbits were fed high-cholesterol diets for 8 weeks. After sacrifice, lesion sizes were determined, and elemental analyses of the lesion and unaffected artery wall performed using nuclear microscopy. Unlike iron, lesion copper is decreased by about half compared with the unaffected artery wall, and much less copper than iron is present. Our data suggest that iron may be more likely to play a role in the promotion of atherosclerosis than copper.     

Excess copper induces accumulation of hydrogen peroxide and increases lipid peroxidation and total activity of copper–zinc superoxide dismutase in roots of Elsholtzia haichowensis

The effects of excess copper (Cu) on the accumulation of hydrogen peroxide (H₂O₂) and antioxidant enzyme activities in roots of the Cu accumulator Elsholtzia haichowensis Sun were investigated. Copper at 100 and 300 μM significantly increased the concentrations of malondialdehyde and H₂O₂, and the activities of catalase (E.C. 1.11.1.6), ascorbate peroxidase (E.C. 1.11.1.11), guaiacol peroxidase (GPOD, E.C. 1.11.1.7) and superoxide dismutase (SOD, E.C. 1.15.1.1). Isoenzyme pattern and inhibitor studies showed that, among SOD isoforms, only copper–zinc superoxide dismutase (CuZn–SOD) increased. Excess Cu greatly increased the accumulation of superoxide anion (O₂ ^·−) and H₂O₂ in E. haichowensis roots. This study also provides the first cytochemical evidence of an accumulation of H₂O₂ in the root cell walls as a consequence of Cu treatments. Experiments with diphenyleneiodonium as an inhibitor of NADPH oxidase, 1,2-dihydroxybenzene-3,5-disulphonic acid as an O₂ ^·− scavenger, and N-N-diethyldithiocarbamate as an inhibitor of SOD showed that the source of H₂O₂ in the cell walls could partially be NADPH oxidase. The enzyme can use cytosolic NADPH to produce O₂ ^·−, which rapidly dismutates to H₂O₂ by SOD. Apoplastic GPOD and CuZn–SOD activities were induced in roots of E. haichowensis with 100 μM Cu suggesting that these two antioxidant enzymes may be responsible for H₂O₂ accumulation in the root apoplast.     

The co-effect of copper and lipid vesicles on Aβ aggregation

Both metal ions and lipid membranes have a wide distribution in amyloid plaques and play significant roles in AD pathogenesis. Although influences of different metal ions or lipid vesicles on the aggregation of Aβ peptides have been extensively studied, their combined effects are less understood. In this study, we reported a unique effect of copper ion on Aβ aggregation in the presence of lipid vesicles, different from other divalent metal ions. Cu²⁺ in a super stoichiometric amount leads to the rapid formation of β-sheet rich structure, containing abundant low molecular weight (LMW) oligomers. We demonstrated that oligomerization of Aβ40 induced by Cu²⁺ binding was an essential prerequisite for the rapid conformation transition. Overall, the finding provided a new view on the complex triple system of Aβ, copper ion and lipid vesicles, which might help understanding of Aβ pathologies.     

Stimulation and oxidative catalytic inactivation of thermolysin by copper•Cys-Gly-His-Lys

[Cu²⁺•Cys-Gly-His-Lys] stimulates thermolysin (TLN) activity at low concentration (below 10 μM) and inhibits the enzyme at higher concentration, with binding affinities of 2.0 and 4.9 μM, respectively. The metal-free Cys-Gly-His-Lys peptide also stimulates TLN activity, with an apparent binding affinity of 2.2 μM. Coordination of copper through deprotonated imine nitrogens, the histidyl nitrogen, and the free N-terminal amino group is consistent with the characteristic absorption spectrum of a Cu²⁺–amino-terminal copper and nickel binding motif (λ _max ∼ 525 nm). The lack of thiol coordination is suggested by both the absence of a thiol to Cu²⁺ charge transfer band and electrochemical studies, since the electrode potential (vs. Ag/AgCl) 0.84 V (ΔE = 92 mV) for the Cu^3+/2+ redox couple obtained for [Cu²⁺•Cys-Gly-His-Lys] was found to be in close agreement with that of a related complex [Cu²⁺•Lys-Gly-His-Lys]⁺ (0.84 V, ΔE = 114 mV). The N-terminal cysteine appears to be available as a zinc-anchoring residue and plays a critical functional role since the [Cu²⁺•Lys-Gly-His-Lys]⁺ homologue exhibits neither stimulation nor inhibition of TLN. Under oxidizing conditions (ascorbate/O₂) the catalyst is shown to mediate the complete irreversible inactivation of TLN at concentrations where enzyme activity would otherwise be stimulated. The observed rate constant for inactivation of TLN activity was determined as k _obs = 7.7 × 10⁻² min⁻¹, yielding a second-order rate constant of (7.7 ± 0.9) × 10⁴ M⁻¹ min⁻¹. Copper peptide mediated generation of reactive oxygen species that subsequently modify active-site residues is the most likely pathway for inactivation of TLN rather than cleavage of the peptide backbone.     

The many “faces” of copper in medicine and treatment

Copper (Cu) is an essential microelement found in all living organisms with the unique ability to adopt two different redox states—in the oxidized (Cu²⁺) and reduced (Cu⁺). It is required for survival and serves as an important catalytic cofactor in redox chemistry for proteins that carry out fundamental biological functions, important in growth and development. The deficit of copper can result in impaired energy production, abnormal glucose and cholesterol metabolism, increased oxidative damage, increased tissue iron (Fe) accrual, altered structure and function of circulating blood and immune cells, abnormal neuropeptides synthesis and processing, aberrant cardiac electrophysiology, impaired myocardial contractility, and persistent effects on the neurobehavioral and the immune system. Increased copper level has been found in several disorders like e.g.: Wilson’s disease or Menke’s disease. New findings with the great potential for impact in medicine include the use of copper-lowering therapy for antiangiogenesis, antifibrotic and anti-inflammatory purposes. The role of copper in formation of amyloid plaques in Alzheimer’s disease, and successful treatment of this disorder in rodent model by copper chelating are also of interest. In this work we will try to describe essential aspects of copper in chosen diseases. We will represent the evidence available on adverse effect derived from copper deficiency and copper excess. We will try to review also the copper biomarkers (chosen enzymes) that help reflect the level of copper in the body.     

Functional proton transfer pathways in the heme–copper oxidase superfamily

Heme–copper oxidases (HCuOs) terminate the respiratory chain in mitochondria and most bacteria. They are transmembrane proteins that catalyse the reduction of oxygen and use the liberated free energy to maintain a proton-motive force across the membrane. The HCuO superfamily has been divided into the oxygen-reducing A-, B- and C-type oxidases as well as the bacterial NO reductases (NOR), catalysing the reduction of NO in the denitrification process. Proton transfer to the catalytic site in the mitochondrial-like A family occurs through two well-defined pathways termed the D- and K-pathways. The B, C, and NOR families differ in the pathways as well as the mechanisms for proton transfer to the active site and across the membrane. Recent structural and functional investigations, focussing on proton transfer in the B, C and NOR families will be discussed in this review. This article is part of a Special Issue entitled: Respiratory Oxidases.