Jenifer S. Calvo scite author profile

Metallothioneins (MTs) are a class of low molecular weight and cysteine-rich metal binding proteins present in all the branches of the tree of life. MTs efficiently bind with high affinity several essential and toxic divalent and monovalent transition metals by forming characteristic polynuclear metalthiolate clusters within their structure. MTs fulfil multiple biological functions related to their metal binding properties, with essential roles in both Zn(II) and Cu(I) homeostasis as well as metal detoxification. Depending on the organism considered, the primary sequence, and the specific physiological and The presence of nonsulfur coordination residues (e.g., histidine) in some members of the superfamily, such as bacterial and plant MTs, has broken the dogma of the exclusive metal coordination by cysteine thiolate residues in MTs. According to Binz and K€ agi (2), MTs are classified into 15 families based on taxonomic parameters and the patterns of distribution of Cys residues in their sequence. The recognized fundamental functions of MTs arise from their capabilities to bind transition metals with high affinity, and their primary biological roles include homeostasis of essential trace metals zinc and copper, and sequestration and protection from environmental toxic metals such as cadmium, mercury, and lead (1). In addition, in light of the reactivity of the metal-coordinating thiolate ligands, MTs play fundamental roles in protection against oxidative stress including reactive oxygen and nitrogen species and other free radicals (1,3-5). However, additional specific MT functions arise from specific biological needs and complexity of the organisms in which they are expressed. Since 60 years from their discovery, it emerged that metallothoineins indeed possess complex pleiotropic functions. This is exemplified by the better-studied mammalian MTs for which additional specialized roles in adaptation to stress, protection against brain injury, regulation of neuronal outgrowth, antiapoptotic effects, and reactivity and inactivation of metal-based chemotherapeutics leading to resistance have been demonstrated (4).As a result of the high number of thiolate coordinating residues in MTs and the lack of defined three-dimensional (3D) structures in the metal depleted apo forms, MTs can bind a number of different monovalent and divalent metals both in vitro and in vivo. The affinity of the metal ions for the binding

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Ratiometric two-photon microscopy reveals attomolar copper buffering in normal and Menkes mutant cells

Morgan

Bourassa

Harankhedkar

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Copper is controlled by a sophisticated network of transport and storage proteins within mammalian cells, yet its uptake and efflux occur with rapid kinetics. Present as Cu(I) within the reducing intracellular environment, the nature of this labile copper pool remains elusive. While glutathione is involved in copper homeostasis and has been assumed to buffer intracellular copper, we demonstrate with a ratiometric fluorescent indicator, crisp-17, that cytosolic Cu(I) levels are buffered to the vicinity of 1 aM, where negligible complexation by glutathione is expected. Enabled by our phosphine sulfide-stabilized phosphine (PSP) ligand design strategy, crisp-17 offers a Cu(I) dissociation constant of 8 aM, thus exceeding the binding affinities of previous synthetic Cu(I) probes by four to six orders of magnitude. Two-photon excitation microscopy with crisp-17 revealed rapid, reversible increases in intracellular Cu(I) availability upon addition of the ionophoric complex CuGTSM or the thiol-selective oxidant 2,2′-dithiodipyridine (DTDP). While the latter effect was dramatically enhanced in 3T3 cells grown in the presence of supplemental copper and in cultured Menkes mutant fibroblasts exhibiting impaired copper efflux, basal Cu(I) availability in these cells showed little difference from controls, despite large increases in total copper content. Intracellular copper is thus tightly buffered by endogenous thiol ligands with significantly higher affinity than glutathione. The dual utility of crisp-17 to detect normal intracellular buffered Cu(I) levels as well as to probe the depth of the labile copper pool in conjunction with DTDP provides a promising strategy to characterize perturbations of cellular copper homeostasis.

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Non-coordinative metal selectivity bias in human metallothioneins metal–thiolate clusters

2018

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Mammalian metallothioneins (MT-1 through MT-4) are a class of metal binding proteins containing two metal-thiolate clusters formed through the preferential coordination of d10 metals, Cu(I) and Zn(II), by 20 conserved cysteine residues located in two protein domains. MT metalation (homometallic or heterometallic Zn(II)/Cu(I) species) appears to be isoform specific and controlling zinc and copper concentrations to perform specific and distinct biological functions. Structural and functional relationships, and in vivo metalation studies, identified evolutionary features defining the metal-selectivity nature for MTs. Metallothionein-3 (MT-3) has been shown to possess the most pronounced Cu-thionein character forming Cu(I)-containing species more favorably than metallothionein-2 (MT-2), which possesses the strongest Zn-thionein character. In this work, we identify isoform-specific determinants which control metal binding selectivity bias in different MTs isoforms. By studying the reactivity of Zn7MT-2, Zn7MT-3 and Zn7MT-3 mutants towards Cu(II) to form Cu(I)4Zn4MTs, we have identified isoform-specific key non-coordinating residues governing folding/outer sphere control of metal selectivity bias in MTs metal clusters. By mutating selected residues and motifs in MT-3 to the corresponding MT-2 amino acids, we dissected key roles in modulating cluster dynamic and metal exchange rates, in increasing the Cu(I)-affinity in MT-3 N-terminal β-domain and/or modulating the higher stability of the Zn(II)-thiolate cluster in MT-2 β-domain. We thus engineered MT-3 variants in which the copper-thionein character is converted into a zinc-thionein. These results provide new insights into the molecular determinants governing metal selectivity in metal-thiolate clusters.

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Jenifer S. Calvo

Copper metallothioneins

Ratiometric two-photon microscopy reveals attomolar copper buffering in normal and Menkes mutant cells

Non-coordinative metal selectivity bias in human metallothioneins metal–thiolate clusters

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