Release of copper from yeast copper-thionein after S-alkylation of copper-thiolate clusters.

Our knowledge on the release of copper from Cu-thionein in biological systems is limited. Other than oxidative cleavage or direct transfer, the possibility of an alkylation mechanism seemed attractive. Iodoacetamide and methyl methanesulphonate were successfully employed to alkylate the Cu-thiolate sulphur atom of homogeneous Cu(I)-thionein from yeast. The alkylation caused a weakening of the Cu-S bonding, which led to the release of copper. After equilibrium dialysis a proportion of the released copper was found in the dialysis buffer. When iodoacetamide was used carboxymethylcysteine was detected in the protein hydrolysate. A 10-fold molar excess over cysteine was sufficient for complete alkylation, which could be conveniently monitored by c.d. at 328 and 359 nm. The reaction proceeded under both aerobic and anaerobic conditions. E.p.r. measurements of Cu2+ revealed unequivocally the complete cleavage of the Cu-thiolate bonding in less than 5 h. It is possible that this mode of copper release might be of relevance to the molecular transport of this biochemically important transition metal.     

Laboratory evolution of copper tolerant yeast strains

Background  

Yeast strains endowed with robustness towards copper and/or enriched in intracellular Cu might find application in biotechnology processes, among others in the production of functional foods. Moreover, they can contribute to the study of human diseases related to impairments of copper metabolism. In this study, we investigated the molecular and physiological factors that confer copper tolerance to strains of baker's yeasts.     

Bakers' yeast uridine nucleosidase is a regulatory copper containing protein.

The enzymatic properties of homogeneous bakers' yeast uridine nucleosidase, prepared as previously described (G. Magni et al., J. Biol. Chem. 1975 $\text{250}$, 9–13) have been further investigated, and in addition to glucose-6-phosphate and ribose the enzyme activity was inhibited by ribose-5-phosphate and ribulose-5-phosphate. The curves describing this inhibitions were sigmoidal and when the data were plotted according to Hill, n′ values different from 1 were observed suggesting the existence of interactions among the inhibitory molecules binding sites. Furthermore the percentage of inhibition exerted by glucose-6-phosphate, ribose and ribose-5-phosphate on the enzyme activity varied at different pH values. The addition of various chelating agents to the activity assay mixture caused a strong inhibition of the enzyme activity and metal analysis by atomic absorption spectrophotometry, colorimetric methods and electronic paramagnetic resonance, indicated the presence of 1 copper atom per enzyme molecule. Finally the inhibition exerted by metal ions on the enzyme activity was described.     

X-ray absorption studies of yeast copper metallothionein

The local structures of the metal sites in copper metallothionein from Saccharomyces cerevisiae have been investigated by x-ray absorption spectroscopy at the copper and sulfur K edges. Analysis of the EXAFS (extended x-ray absorption fine structure) data indicates that each copper is trigonally coordinated to sulfur at a distance of 2.23 A. Cu-Cu interactions at 2.7 and 3.9 A have also been tentatively identified. Sulfur K edge data are compatible with cysteinyl thiolates bridging each of the eight Cu(I) ions. The data support a model for the copper cluster in yeast metallothionein consisting of a Cu8S12 core. EXAFS data on two specifically engineered carboxyl-terminal truncated mutants reveal that the copper coordination in the mutants is similar to that observed in the wild-type protein.     

An EXAFS study of the copper accumulated by yeast cells

Summary X-ray absorption spectroscopy has been applied to the in vivo examination of copper-resistant yeast cells. The in vivo structure of the metal-binding site of the accumulated copper has been compared to that of the purified yeast thionein. Analysis of the EXAFS spectra performed on intact yeast cells indicates that the accumulated copper is univalent and is exclusively coordinated to sulfur atoms at a distance of 219 pin with an average coordination number of 2. In contrast, the purified protein indicates a univalent copper trigonally coordinated to sulfur at a distance of 221 pm. These discrepancies are discussed in terms of copper location in the resistant yeast cells.     

Charting the travels of copper in eukaryotes from yeast to mammals

Throughout evolution, all organisms have harnessed the redox properties of copper (Cu) and iron (Fe) as a cofactor or structural determinant of proteins that perform critical functions in biology. At its most sobering stance to Earth's biome, Cu biochemistry allows photosynthetic organisms to harness solar energy and convert it into the organic energy that sustains the existence of all nonphotosynthetic life forms. The conversion of organic energy, in the form of nutrients that include carbohydrates, amino acids and fatty acids, is subsequently released during cellular respiration, itself a Cu-dependent process, and stored as ATP that is used to drive a myriad of critical biological processes such as enzyme-catalyzed biosynthetic processes, transport of cargo around cells and across membranes, and protein degradation. The life-supporting properties of Cu incur a significant challenge to cells that must not only exquisitely balance intracellular Cu concentrations, but also chaperone this redox-active metal from its point of cellular entry to its ultimate destination so as to avert the potential for inappropriate biochemical interactions or generation of damaging reactive oxidative species (ROS). In this review we chart the travels of Cu from the extracellular milieu of fungal and mammalian cells, its path within the cytosol as inferred by the proteins and ligands that escort and deliver Cu to intracellular organelles and protein targets, and its journey throughout the body of mammals. This article is part of a Special Issue entitled: Cell Biology of Metals.     

Candida argentea sp. nov., a copper and silver resistant yeast species

A new yeast species was isolated from the sediment under metal-contaminated effluent from a disused metal mine in mid-Wales, UK. BLAST searching with DNA sequence amplified from the ribosomal 26S D1/D2 and ITS regions did not reveal a close match with any previously described species (≥6?% and 3?% divergence, respectively). Phylogenetic analysis indicated that the species was a member of the Saccharomycetales, but did not group closely with other established species, the nearest relative being Wickerhamia fluorescens although bootstrap support was not strong. In addition to its unusual phylogeny, the species also exhibited notable physiological and morphological traits. Isolates exhibited unusually high resistance to both copper and silver in laboratory assays. These phenotypes appeared to be inherent to the species rather than a transient adaptation to the metal-enriched site in Wales, as the same phenotypes were observed in an identical (according to 26S rDNA sequence) isolate from Sao Domingos, Portugal in the Iberian Pyrite Belt. The species exhibited a multipolar budding-type cell division but, unusually, accumulated as rod-shaped cells following division on solid medium, contrasting with the larger ellipsoidal cells observed in broth. This dimorphism could be discerned readily with flow cytometry. The yeast was tolerant of hyper osmotic stress and grew in acidic media (pH 3). This new species is designated Candida argentea and five independent strains are deposited at the National Collection of Yeast Cultures, UK (NCYC 3753(T), 3754, 3755, 3756, 3757). Because of its unusual morphological variation and metal resistance properties, C. argentea may provide opportunities to gain new insights into the physiological and genetic bases of these phenotypes. Results illustrate novel fungal biodiversity that can occur at polluted sites.     

Versatile cassettes designed for the copper inducible expression of proteins in yeast

A series of yeast expression vectors and cassettes utilizing the CUP1 gene of Saccharomyces cerevisiae have been constructed. The cassettes contain multiple cloning sites for gene fusions and were created by inserting a 27-bp polylinker at the +14 position of the CUP1 gene. The cassettes are portable as restriction fragments and enable copper-regulated expression of foreign proteins in S. cerevisiae. In copper sensitive yeast, multiple copies of the CUP1 cassettes confer copper resistance due to the production of the copper metallothionein. Genes cloned into the CUP1 cassettes, however, usually prevent translation of the metallothionein leading to a loss of resistance. This could be useful for one-step cloning into yeast.     

Proteomic study of the yeast Rhodotorula mucilaginosa RCL-11 under copper stress

In order to understand the mechanism involved in Rhodotorula mucilaginosa RCL-11 resistance to copper a proteomic study was conducted. Atomic absorption spectroscopy showed that the copper concentration in the medium decreased from 0.5 to 0.19 mM 48 h after inoculation of the yeast. Analysis of one-dimensional gel electrophoresis of crude cell extracts revealed expression of differential bands between cells with and without copper. In order to study this difference, two-dimensional electrophoresis of R. mucilaginosa RCL-11 exposed to Cu for 16, 24, and 48 h was carried out. Identification of differentially expressed proteins was performed by MALDI-TOF/TOF. Ten of the 16 spots identified belonged to heat shock proteins. Superoxide dismutase, methionine synthase and beta-glucosidase were also found over-expressed at high copper concentrations. The results obtained in the present work show that when R. mucilaginosa RCL-11 is exposed to 0.5 mM copper, differential proteins, involved in cell resistance mechanisms, are expressed.     

The role of PDR13 in tolerance to high copper stress in budding yeast.

PDR13 in Saccharomyces cerevisiae contributes to drug resistance via sequential activation of PDR1 and PDR5. In this study, we found that a PDR13 deletion mutant was hypersensitive to Cu(2+) compared to the wild-type counterpart. The Cu(2+) tolerance mechanism mediated by Pdr13 does not seem to involve Pdr1 or Pdr5, since mutants harboring a deletion of either the PDR1 or PDR5 gene did not show elevated Cu(2+) sensitivity. Instead, we found that the PDR13 null mutant could not express CUP1 or CRS5 metallothionein at wild-type levels when subjected to high Cu(2+) stress. These results suggest that Pdr13 contributes to high Cu(2+) tolerance of S. cerevisiae, at least in part, via a mechanism involving metallothionein expression.     

Removal of copper ions from dilute solutions byStreptomyces noursei mycelium. Comparison with yeast biomass

Sorption properties of Streptomyces noursei mycelium for copper ions were compared with the accumulation competence of dried and native yeast (Candida utilis) biomass. The copper sorption capacity of S. noursei after optimization was found to be higher than that of the two other adsorbents (dried yeast biomass 82 %, native Candida cells 48 % of the sorption capacity of the S. noursei mycelium).     

Factors controlling the uptake of yeast copper/zinc superoxide dismutase into mitochondria

We have previously shown that a fraction of yeast copper/zinc-superoxide dismutase (SOD1) and its copper chaperone CCS localize to the intermembrane space of mitochondria. In the present study, we have focused on the mechanism by which SOD1 is partitioned between cytosolic and mitochondrial pools. Using in vitro mitochondrial import assays, we show that only a very immature form of the SOD1 polypeptide that is apo for both copper and zinc can efficiently enter the mitochondria. Moreover, a conserved disulfide in SOD1 that is essential for activity must be reduced to facilitate mitochondrial uptake of SOD1. Once inside the mitochondria, SOD1 is converted to an active holo enzyme through the same post-translational modifications seen with cytosolic SOD1. The presence of high levels of CCS in the mitochondrial intermembrane space results in enhanced mitochondrial accumulation of SOD1, and this apparently involves CCS-mediated retention of SOD1 within mitochondria. This retention of SOD1 is not dependent on copper loading of the enzyme but does require protein-protein interactions at the heterodimerization interface of SOD1 and CCS as well as conserved cysteine residues in both molecules. A model for how CCS-mediated post-translational modification of SOD1 controls its partitioning between the mitochondria and cytosol will be presented.     

AtCOX17, an Arabidopsis homolog of the yeast copper chaperone COX17

We have identified a new plant gene, AtCOX17, encoding a protein that shares sequence similarity to COX17, a Cu-binding protein from yeast (Saccharomyces cerevisiae) and vertebrates that mediates the delivery of Cu to the mitochondria for the assembly of a functional cytochrome oxidase complex. The newly characterized Arabidopsis protein has six Cys residues at positions corresponding to those known to coordinate Cu binding in the yeast homolog. Moreover, we show that the Arabidopsis COX17 cDNA complements a COX17 mutant of yeast restoring the respiratory deficiency associated with that mutation. These two lines of evidence indicate that the plant protein identified here is a functional equivalent of yeast COX17 and might serve as a Cu delivery protein for the plant mitochondria. COX17 was identified by investigating the hypersensitive response-like necrotic response provoked in tobacco (Nicotiana tabacum) leaves after harpin inoculation. AtCOX17 expression was activated by high concentrations of Cu, bacterial inoculation, salicylic acid treatment, and treatments that generated NO and hydrogen peroxide. All of the conditions inducing COX17 are known to inhibit mitochondrial respiration and to produce an increase of reactive oxygen species, suggesting that gene induction occurs in response to stress situations that interfere with mitochondrial function.     

Pipes and wiring: the regulation of copper uptake and distribution in yeast

Copper is required for processes as conserved as respiration and as specialized as protein modification. Recent exciting findings from studies in yeast cells have revealed the presence of specific pathways for copper transport, trafficking and signal transduction that maintain the delicate balance of this essential yet toxic metal ion.