Wolfgang Maret

Cytosolic zinc buffering and muffling: Their role in intracellular zinc homeostasis

Our knowledge of the molecular mechanisms of intracellular homeostatic control of zinc ions is now firmly grounded on experimental findings gleaned from the study of zinc proteomes and metallomes, zinc transporters, and insights from the use of computational approaches. A cells repertoire of zinc homeostatic molecules includes cytosolic zinc-binding proteins, transporters localized to cytoplasmic and organellar membranes, and sensors of cytoplasmic free zinc ions. Under steady state conditions, a primary function of cytosolic zinc-binding proteins is to buffer the relatively large zinc content found in most cells to a cytosolic zinc(ii) ion concentration in the picomolar range. Under non-steady state conditions, zinc-binding proteins and transporters act in concert to modulate transient changes in cytosolic zinc ion concentration in a process that is called zinc muffling. For example, if a cell is challenged by an influx of zinc ions, muffling reactions will dampen the resulting rise in cytosolic zinc ion concentration and eventually restore the cytosolic zinc ion concentration to its original value by shuttling zinc ions into subcellular stores or by removing zinc ions from the cell. In addition, muffling reactions provide a potential means to control changes in cytosolic zinc ion concentrations for purposes of cell signalling in what would otherwise be considered a buffered environment not conducive for signalling. Such intracellular zinc ion signals are known to derive from redox modifications of zinc-thiolate coordination environments, release from subcellular zinc stores, and zinc ion influx via channels. Recently, it has been discovered that metallothionein binds its seven zinc ions with different affinities. This property makes metallothionein particularly well positioned to participate in zinc buffering and muffling reactions. In addition, it is well established that metallothionein is a source of zinc ions under conditions of redox signalling. We suggest that the biological functions of transient changes in cytosolic zinc ion concentrations (presumptive zinc signals) complement those of calcium ions in both spatial and temporal dimensions.

Zinc metallothionein imported into liver mitochondria modulates respiration

Metallothionein (MT) localizes in the intermembrane space of liver mitochondria as well as in the cytosol and nucleus. Incubation of intact liver mitochondria with physiological, micromolar concentrations of MT leads to the import of MT into the mitochondria where it inhibits respiration. This activity is caused by the N-terminal β-domain of MT; in this system, the isolated C-terminal α-domain is inactive. Free zinc inhibits respiration at concentrations commensurate with the zinc content of either MT or the isolated β-domain, indicating that MT inhibition involves zinc delivery to mitochondria. Respiratory inhibition of uncoupled mitochondria identifies the electron transfer chain as the primary site of inhibition. The apoform of MT, thionein, is an endogenous chelating agent and activates zinc-inhibited respiration with a 1:1 stoichiometry ([zinc binding sites]/[zinc]). Carbamoylation of the lysines of MT significantly attenuates the inhibitory effect, suggesting that these residues are critical for the passage of MT through the outer mitochondrial membrane. Such an import pathway has been proposed for other proteins that also lack a mitochondrial targeting sequence, e.g., apocytochrome c, and possibly Cox17, a mitochondrial copper chaperone that is the only protein known so far to exhibit significant primary sequence homology to MT. The presence and respiratory inhibition of MT in liver, but not heart, mitochondria suggest a hitherto unknown biological modulating activity of MT in cellular respiration and energy metabolism in a tissue-specific manner.

Cellular Zinc and Redox States Converge in the Metallothionein/Thionein Pair

The paramount importance of zinc for a wide range of biological functions is based on its occurrence in thousands of known zinc proteins. To regulate the availability of zinc dynamically, eukaryotes have compartmentalized zinc and the metallothionein/thionein pair, which controls the pico- to nanomolar concentrations of metabolically active cellular zinc. Interactions of zinc with sulfur ligands of cysteines turn out to be critical both for tight binding and creation of a redox-active coordination environment from which the redox-inert zinc can be distributed. Biological oxidants such as disulfides and S-nitrosothiols oxidize the zinc/thiolate clusters in metallothionein with concomitant zinc release. In addition, selenium compounds that have the capacity to form selenol(ate)s catalytically couple with the glutathione/glutathione disulfide and metallothionein/thionein redox pairs to either release or bind zinc. In this pathway, selenium expresses its antioxidant effects through redox catalysis in zinc metabolism. Selenium affects the redox state of thionein, an endogenous chelating agent. With its 20 cysteines, thionein contributes significantly to the zinc- and thiol-redox-buffering capacity of the cell. Thus, hitherto unknown interactions between the essential micronutrients zinc and selenium on the one hand and zinc and redox metabolism on the other are key features of the cellular homeostatic zinc system.

Metallothionein/disulfide interactions, oxidative stress, and the mobilization of cellular zinc ☆

Glutathione disulfide, the major cellular disulfide, releases zinc from metallothionein (MT) [W. Maret (1994) Oxidative metal release from metallothionein via zinc-thiol/disulfide interchange, Proc. natn. Acad. Sci. U.S.A. 91, 237-241]. Here, the interaction of rabbit liver MT-II with other selected biological disulfides (coenzyme A/glutathione mixed disulfide, coenzyme A disulfide, and cystamine) was investigated by measuring concomitant release of radioactive 65-zinc from MT. These disulfides react more rapidly than glutathione disulfide, thus underscoring the reactivity of zinc sulfur bonds in the clusters of MT and the importance of the MT/disulfide interaction as a chemical mechanism for mobilizing zinc from a thermodynamically stable zinc complex. Two implications of these in vitro findings are discussed. (i) Apparently, in the case of zinc which is redox inert, Nature has availed itself of the redox activity of the cysteine ligand to mobilize the metal, and, presumably to permit redox-control of cellular zinc distribution. The mobilization of zinc from MT suggests a possible function of MT as a physiological zinc donor. (ii) A shift of the glutathione redox balance under conditions of oxidative stress will accelerate metal release from MT. Such a disturbance of metal metabolism has important consequences for the progression of diseases such as Alzheimers and Parkinsons disease where oxidative stress occurs in affected brain tissue.

Protein tyrosine phosphatases as targets of the combined insulinomimetic effects of zinc and oxidants.

Zinc ions have an insulin-like (insulinomimetic) effect. A particularly sensitive target of zinc ions is protein tyrosine phosphatase 1B (PTP 1B), a key regulator of the phosphorylation state of the insulin receptor. Modulation of insulin signaling by zinc chelating agents and the recognition of temporal and spatial fluctuations of zinc suggest a physiological role of zinc in insulin signal transduction. Tyrosine phosphatases seem to be regulated jointly by insulin-induced redox (hydrogen peroxide) signaling, which results in their oxidative inactivation, and by their zinc inhibition after oxidative zinc release from other proteins. In␣diabetes, the significant oxidative stress and associated changes in zinc metabolism modify the cell’s response and sensitivity to insulin. Zinc deficiency activates stress pathways and may result in a loss of tyrosine phosphatase control, thereby causing insulin resistance.

Metals on the move: zinc ions in cellular regulation and in the coordination dynamics of zinc proteins

Homeostatic control maintains essential transition metal ions at characteristic cellular concentrations to support their physiological functions and to avoid adverse effects. Zinc is especially widely used as a catalytic or structural cofactor in about 3000 human zinc proteins. In addition, the homeostatic control of zinc in eukaryotic cells permits functions of zinc(II) ions in regulation and in paracrine and intracrine signaling. Zinc ions are released from proteins through ligand-centered reactions in zinc/thiolate coordination environments, and from stores in cellular organelles, where zinc transporters participate in zinc loading and release. Muffling reactions allow zinc ions to serve as signaling ions (second messengers) in the cytosol that is buffered to picomolar zinc ion concentrations at steady-state. Muffling includes zinc ion binding to metallothioneins, cellular translocations of metallothioneins, delivery of zinc ions to transporter proteins, and zinc ion fluxes through cellular membranes with the result of removing the additional zinc ions from the cytosol and restoring the steady-state. Targets of regulatory zinc ions are proteins with sites for transient zinc binding, such as membrane receptors, enzymes, protein–protein interactions, and sensor proteins that control gene expression. The generation, transmission, targets, and termination of zinc ion signals involve proteins that use coordination dynamics in the inner and outer ligand spheres to control metal ion association and dissociation. These new findings establish critically important functions of zinc ions and zinc metalloproteins in cellular control.

Free zinc ions outside a narrow concentration range are toxic to a variety of cells in vitro.

The zinc(II) ion has recently been implicated in a number of novel functions and pathologies in loci as diverse as the brain, retina, small intestine, prostate, heart, pancreas, and immune system. Zinc ions are a required nutrient but elevated concentrations are known to kill cells in vitro. Paradoxical observations regarding zincs effects have appeared frequently in the literature, and often their physiological relevance is unclear. We found that for PC-12, HeLa and HT-29 cell lines as well as primary cultures of cardiac myocytes and neurons in vitro in differing media, approximately 5 nmol/L free zinc (pZn = 8.3, where pZn is defined as – log10 [free Zn2+]) produced apparently healthy cells, but 20-fold higher or (in one case) lower concentrations were usually harmful as judged by multiple criteria. These results indicate that (1) the free zinc ion levels of media should be controlled with a metal ion buffer; (2) adding zinc or strong zinc ligands to an insufficiently buffered medium may lead to unpredictably low or high free zinc levels that are often harmful to cells; and (3) it is generally desirable to measure free zinc ion levels due to the presence of contaminating zinc in many biochemicals and unknown buffering capacity of many media.

Metallothionein redox biology in the cytoprotective and cytotoxic functions of zinc.

A critical aspect of cellular zinc metabolism is the tight control of the picomolar concentrations of free zinc ions and their fluctuations to balance folding and misfolding of proteins, supply of thousands of zinc-requiring proteins with zinc, and dual functions of zinc as either a pro-oxidant or a pro-antioxidant. Zinc/sulfur (cysteine) bonds in proteins have a key role in this control because they generate redox-active coordination environments. Metallothionein (MT) is such a redox-active zinc protein, which couples biochemically to the cellular redox state. The coordination dynamics and redox state of its zinc/thiolate clusters determine cellular zinc availability. A fraction of MT in tissues and cells contains free thiols and disulfides. Thus, MT with seven zinc ions and twenty reduced thiols as characterized by high-resolution 3D structures does not represent its biologically active form. Redox stress affects the zinc and redox buffering capacity of MT and elicits fluctuations of zinc ions that are potent effectors of multiple metabolic and signaling pathways. We are beginning to appreciate the sensitivity of cellular zinc homeostasis to perturbations, the clinical importance of linked zinc and redox imbalances for aging and the development of chronic diseases, and the tangible benefits of preventive and therapeutic nutritional interventions.

New perspectives of zinc coordination environments in proteins.

Zinc is more widely used as a cofactor in proteins than any other transition metal ion. In addition to catalytic and structural functions, zinc(II) ions have a role in information transfer and cellular control. They bind transiently when proteins regulate zinc concentrations and re-distribute zinc and when proteins are regulated by zinc. Transient zinc-binding sites employ the same donors of amino acid side chains as catalytic and structural sites but differ in their coordination chemistry that can modulate zinc affinities over at least ten orders of magnitude. Redox activity of the cysteine ligands, multiple binding modes of the oxygen, sulfur and nitrogen donors, and protein conformational changes induce coordination dynamics in zinc sites and zinc ion mobility. Functional annotations of the remarkable variation of coordination environments in zinc proteomes need to consider how the primary coordination spheres interact with protein structure and dynamics, and the adaptation of coordination properties to the biological context in extracellular, cellular, or subcellular locations.

Differential fluorescence labeling of cysteinyl clusters uncovers high tissue levels of thionein.

The isolation of thionein (T) from tissues has not been reported heretofore. T contains 20 cysteinyl residues that react with 7-fluorobenz-2-oxa-1,3-diazole-4-sulfonamide to form fluorescent adducts. In metallothionein (MT) the cysteinyl residues, which are bound to zinc, do not react. However, they do react in the presence of a chelating agent such as EDTA. The resultant difference in chemical reactivity provides a means to measure T in the absence of EDTA, (MT + T) in its presence, and, of course, MT by difference. The 7-fluorobenz-2-oxa-1,3-diazole-4-sulfonamide derivative of T can be isolated from tissue homogenates by HPLC and quantified fluorimetrically with a detection limit in the femtomolar range and a linear response over 3 orders of magnitude. Analysis of liver, kidney, and brain of rats reveals almost as much T as MT. Moreover, in contrast to earlier views, MT in tissue extracts appears to be less stable than T. The existence of T in tissues under normal physiological conditions has important implications for its function both in zinc metabolism and the redox balance of the cell.