The Glutathione/Metallothionein System Challenges the Design of Efficient O2 -Activating Copper Complexes.

Copper complexes are of medicinal and biological interest, including as anticancer drugs designed to cleave intracellular biomolecules by O2 activation. To exhibit such activity, the copper complex must be redox active and resistant to dissociation. Metallothioneins (MTs) and glutathione (GSH) are abundant in the cytosol and nucleus. Because they are thiol-rich reducing molecules with high CuI affinity, they are potential competitors for a copper ion bound in a copper drug. Herein, we report the investigation of a panel of CuI /CuII complexes often used as drugs, with diverse coordination chemistries and redox potentials. We evaluated their catalytic activity in ascorbate oxidation based on redox cycling between CuI and CuII , as well as their resistance to dissociation or inactivation under cytosolically relevant concentrations of GSH and MT. O2 -activating CuI /CuII complexes for cytosolic/nuclear targets are generally not stable against the GSH/MT system, which creates a challenge for their future design.

Reactivity of Cu(ii)-, Zn(ii)- and Fe(ii)-thiosemicarbazone complexes with glutathione and metallothionein: from stability to dissociation to transmetallation.

Thiosemicarbazones (TSCs) are a class of strong metal ion ligands, which are currently being investigated for several applications, such as anticancer treatment. In addition to these ligands only, which exert their activity upon interaction with metal ions in cells, preformed metal-TSC complexes are also widely studied, predominantly with the essential metal ions iron, copper and zinc. Currently, it is unclear what the active species are, which complexes are present and what are their biological targets. Herein, we study the complexes of copper(ii), zinc(ii) and iron(ii) with three TSCs, PT, 3-AP (triapine) and Dp44mT, (latter two are currently in clinical trials), concerning their reactivity with glutathione (GSH) and Zn7-metallothionein (Zn7MT-1, 2 and 3). These two cysteine-containing molecules can have a major impact on metal-TSC complexes because they are abundant in the cytosol and nucleus, they are strong metal ligands and have the potential to reduce Cu(ii) and Fe(iii). Our results indicate that Fe(ii)-TSC is stable in the presence of typical cytosolic concentrations of GSH and Zn7MT. In contrast, all three Cu(ii)-TSCs react rapidly due to the reduction of Cu(ii) to Cu(i), which is then transferred to MT. This suggests that Cu(ii)-TSCs are rapidly dissociated in a cytosolic-type environment and the catalytic generation of reactive oxygen species by Cu(ii)-TSCs is stopped. Moreover, in the case Cu(ii)-Dp44mT, transmetallation with Zn(ii) from MT occurs. The reaction of Zn(ii)-TSCs is ligand dependent, from predominant dissociation for PT and 3-AP, to very little dissociation of Zn(ii)-Dp44mT2. These results indicate that GSH and Zn7MT may be important factors in the fate of Cu(ii)- and Zn(ii)-TSCs. In particular, for Cu, its chemistry is complex, and these reactions may also occur for other families of Cu-complexes used in cancer treatment or for other applications.

Low catalytic activity of the Cu(ii)-binding motif (Xxx-Zzz-His; ATCUN) in reactive oxygen species production and inhibition by the Cu(i)-chelator BCS.

The catalytic redox activity of Cu(ii) bound to the motif NH2-Xxx-Zzz-His (ATCUN) with ascorbate and H2O2/O2 is very low and can be stopped via Cu(i)-chelation. This impacts its application as an artificial Cu-enzyme to degrade biomolecules via production of reactive oxygen species in a Cu(i)-chelator rich environment like the cytosol.

Cu transfer from amyloid-ß4-16 to metallothionein-3: the role of the neurotransmitter glutamate and metallothionein-3 Zn(ii)-load states.

Copper transfer from Cu(ii)amyloid-ß4-16 to human Zn7-metallothionein-3 can be accelerated by glutamate and by lowering the Zn-load of metallothionein-3 with EDTA. Glutamate facilitates the Cu(ii) release, and Zn4-6-metallothionein-3 react more rapidly. These mechanisms are additive, proving the intricate and interconnected network of zinc and copper trafficking between biomolecules.

Cu and Zn coordination to amyloid peptides: From fascinating chemistry to debated pathological relevance.

Several diseases share misfolding of different peptides and proteins as a key feature for their development. This is the case of important neurodegenerative diseases such as Alzheimer's and Parkinson's diseases and type II diabetes mellitus. Even more, metal ions such as copper and zinc might play an important role upon interaction with amyloidogenic peptides and proteins, which could impact their aggregation and toxicity abilities. In this review, the different coordination modes proposed for copper and zinc with amyloid-ß, α-synuclein and IAPP will be reviewed as well as their impact on the aggregation, and ROS production in the case of copper. In addition, a special focus will be given to the mutations that affect metal binding and lead to familial cases of the diseases. Different modifications of the peptides that have been observed in vivo and could be relevant for the coordination of metal ions are also described.

Chemistry of mammalian metallothioneins and their interaction with amyloidogenic peptides and proteins.

Cu and Zn ions are essential in most living beings. Their metabolism is critical for health and mis-metabolism can be lethal. In the last two decades, a large body of evidence has reported the role of copper, zinc and iron, and oxidative stress in several neurodegenerative diseases like Alzheimer's, Parkinson's, prion diseases, etc. To what extent this mis-metabolism is causative or a consequence of these diseases is still a matter of research. In this context metallothioneins (MTs) appear to play a central gate-keeper role in controlling aberrant metal-protein interactions. MTs are small proteins that can bind high amounts of Zn(ii) and Cu(i) ions in metal-cluster arrangements via their cysteine thiolates. Moreover, MTs are well known antioxidants. The present tutorial outlines the chemistry underlying the interconnection between copper(i/ii) and zinc(ii) coordination to amyloidogenic proteins and MTs, and their redox properties in generation and/or silencing reactive oxygen species (overproduced in oxidative stress) and other reactants. These studies have revealed the coordination chemistry involved in neurodegenerative diseases and the interactions between MTs and amyloidogenic protein metal-complexes (like amyloid-ß, α-synuclein and prion-protein). Overall, the protective role of MTs in neurodegenerative processes is emerging, serving as a foundation for exploring MT chemistry as inspiration for therapeutic approaches.

Cysteine and glutathione trigger the Cu-Zn swap between Cu(ii)-amyloid-ß4-16 peptide and Zn7-metallothionein-3.

Cysteine and glutathione are able to reduce Cu(ii) coordinated to the peptide amyloidß4-16, and shuttle the resulting Cu(i) to partially replace Zn(ii) in the protein Zn7-metallothionein-3. The released Zn(ii) in turn binds to amyloid-ß4-16. Thus cysteine and glutathione are modulators of Cu/Zn-distribution between metallothionein-3 and amyloid-ß4-16.