From heavy metal‐binders to biosensors: Ciliate metallothioneins discussed

Metallothioneins (MTs) are ubiquitous proteins with the capacity to bind heavy metal ions (mainly Cd, Zn or Cu), and they have been found in animals, plants, eukaryotic and prokaryotic micro‐organisms. We have carried out a comparative analysis of ciliate MTs (Tetrahymena species) to well‐known MTs from other organisms, discussing their exclusive features, such as the presence of aromatic amino acid residues and almost exclusive cysteine clusters (CCC) present in cadmium‐binding metallothioneins (CdMTs), higher heavy metal‐MT stoichiometry values, and a strictly conserved modular–submodular structure. Based on this last feature and an extensive gene duplication, we propose a possible model for the evolutionary history of T. thermophila MTs. We also suggest possible functions for these MTs from consideration of their differential gene expressions and discuss the potential use of these proteins and/or their gene promoters for designing molecular or whole‐cell biosensors for a fast detection of heavy metals in diverse polluted ecosystems.     

Advances in metallothionein structure and functions.

Metallothioneins (MTs) are a class of ubiquitously occurring low molecular weight cysteine- and metal-rich proteins containing sulfur-based metal clusters. The conservation of these clusters in an increasing number of three-dimensional structures of invertebrate, vertebrate and bacterial MTs signifies the importance of this structural motif. In the postgenomic era, it is becoming increasingly clear that MTs fulfil different functions. Increasing body of evidence show that diverse functions of the mammalian MT-1/MT-2 isoforms including involvement in zinc homeostasis, protection against heavy metal toxicity and oxidative damage are related to their clusters. In contrast, the biological properties of the brain-specific MT-3 isoform imply that the clusters in this protein play a structural role. The recent highlights of MT research are the subject of this review.     

Plant metallothioneins – metal chelators with ROS scavenging activity?

Metallothioneins (MTs) are ubiquitous cysteine-rich proteins present in plants, animals, fungi and cyanobacteria. In plants, MTs are suggested to be involved in metal tolerance or homeostasis, as they are able to bind metal ions through the thiol groups of their cysteine residues. Recent reports show that MTs are also involved in the scavenging of reactive oxygen species (ROS). The interplay between these roles is not entirely clear. Plants have many MT isoforms with overlapping expression patterns, and no specific role for any of them has been assigned. This review is focused on recent findings on plant MTs.     

Chemistry and biology of mammalian metallothioneins

Metallothioneins (MTs) are a class of ubiquitously occurring low molecular mass, cysteine- and metal-rich proteins containing sulfur-based metal clusters formed with Zn(II), Cd(II), and Cu(I) ions. In mammals, four distinct MT isoforms designated MT-1 through MT-4 exist. The first discovered MT-1/MT-2 are widely expressed isoforms, whose biosynthesis is inducible by a wide range of stimuli, including metals, drugs, and inflammatory mediators. In contrast, MT-3 and MT-4 are noninducible proteins, with their expression primarily confined to the central nervous system and certain squamous epithelia, respectively. MT-1 through MT-3 have been reported to be secreted, suggesting that they may play different biological roles in the intracellular and extracellular space. Recent reports established that these isoforms play an important protective role in brain injury and metal-linked neurodegenerative diseases. In the postgenomic era, it is becoming increasingly clear that MTs fulfill multiple functions, including the involvement in zinc and copper homeostasis, protection against heavy metal toxicity, and oxidative damage. All mammalian MTs are monomeric proteins, containing two metal–thiolate clusters. In this review, after a brief summary of the historical milestones of the MT-1/MT-2 research, the recent advances in the structure, chemistry, and biological function of MT-3 and MT-4 are discussed.     

Histidine ligands in bacterial metallothionein enhance cluster stability

The cyanobacterial metallothionein (MT) SmtA is the prototype for bacterial MTs and protects against elevated levels of zinc. In contrast to mammalian MTs, bacterial MTs coordinate to metal ions not only via cysteine sulfurs, but unusually for MTs, also via histidine nitrogens. To investigate whether histidine coordination in these metal-sulfur clusters provides advantages over S-coordination only, we mutated the two metal-binding histidine residues in the cyanobacterial MT SmtA from Synechococcus PCC7942 to cysteines. We show that the mutant proteins are still capable of binding up to four zinc ions as is the wild-type protein. However, the mutations perturb protein folding and metal-binding dynamics. Interestingly, several homologues of SmtA also show variations in these two residues. We conclude that histidine residues in Synechococcus PCC7942 SmtA have a stabilising effect due to electrostatic interactions that impact on protein folding and metal cluster charge, and are involved in fine-tuning the reactivity of the bound metal ions.     

Metallothionein functions and structural characteristics

Metallothioneins (MTs) are low molecular weight proteins characterized by a high cysteine content and give rise to metal-thiolate clusters. Most MTs have two metal clusters containing three and four bivalent metal ions, respectively. The MT gene family in mammals consists of four subfamilies designated MT-1 through MT-4. MT-3 is expressed predominantly in brain and MT-4 in differentiating stratified squamous epithelial cells. Many reports have addressed MT structure and function, but despite the increasing experimental data several topics remain to be clarified, and the true function of this elusive protein has yet to be disclosed. Owing to their induction by a variety of stimuli, MTs are considered valid biomarkers in medicine and environmental studies. Here, we will discuss only a few topics taken from the latest literature. Special emphasis will be placed on MT antioxidant functions, the related oxidation of cysteines, which can give rise to intra/intermolecular bridges, and the relations between MTs and diseases which could be originated by metal dysregulation.     

Toxicity and interaction of titanium dioxide nanoparticles with microtubule protein

Titanium dioxide (TiO2) nanoparticles (NPs) are widely used in several manufactured products. The small size of NPs facilitates their uptake into cells as well as transcytosis across epithelial cells into blood and lymph circulation to reach different sites, such as the central nervous system. Different studies have shown the risks that TiO2 NPs in the neuronal system and other organs present. As membrane-bound layer aggregates or single particles, TiO2 NPs can enter not only cells, but also mitochondria and nuclei. Therefore these particles can interact with cytoplasmic proteins such as microtubules (MTs). MTs are cytoskeletal proteins that are essential in eukaryotic cells for a variety of functions, such as cellular transport, cell motility and mitosis. MTs in neurons are used to transport substances such as neurotransmitters. Single TiO2 NPs in cytoplasm can interact with these proteins and affect their crucial functions in different tissues. In this study, we showed the effects of TiO2 NPs on MT polymerization and structure using ultraviolet spectrophotometer and fluorometry. The fluorescent spectroscopy showed a significant tubulin conformational change in the presence of TiO2 NPs and the ultraviolet spectroscopy results showed that TiO2 NPs affect tubulin polymerization and decrease it. The aim of this study was to find the potential risks that TiO2 NPs pose to human organs and cells.     

Metal release in metallothioneins induced by nitric oxide: X-ray absorption spectroscopy study

Metallothioneins (MTs) are low molecular weight proteins that include metal ions in thiolate clusters. The capability of metallothioneins to bind different metals has suggested their use as biosensors for different elements. We study here the interaction of nitric oxide with rat liver MTs by using in situ X-ray absorption spectroscopy techniques. We univocally show that the presence of NO induces the release of Zn atoms from the MT structure to the solution. Zn ions transform in the presence of NO from a tetrahedral four-fold coordinated environment in the MT into a regular octahedral six-fold coordinated state, with interatomic distances compatible with those of Zn solvated in water.     

Centrosome fragments and microtubules are transported asymmetrically away from division plane in anaphase

Spinning disc confocal microscopy of LLCPK1 cells expressing GFP-tubulin was used to demonstrate that microtubules (MTs) rapidly elongate to the cell cortex after anaphase onset. Concurrently, individual MTs are released from the centrosome and the centrosome fragments into clusters of MTs. Using cells expressing photoactivatable GFP-tubulin to mark centrosomal MT minus ends, a sevenfold increase in MT release in anaphase is documented as compared with metaphase. Transport of both individually released MTs and clusters of MTs is directionally biased: motion is directed away from the equatorial region. Clusters of MTs retain centrosomal components at their focus and the capacity to nucleate MTs. Injection of mRNA encoding nondegradable cyclin B blocked centrosome fragmentation and the stimulation of MT release in anaphase despite allowing anaphase-like chromosome segregation. Biased MT release may provide a mechanism for MT-dependent positioning of components necessary for specifying the site of contractile ring formation.     

Metallothionein and stress combine to affect multiple organ systems

Metallothioneins (MTs) are a family of low molecular weight, cysteine-rich, metal-binding proteins that have a wide range of functions in cellular homeostasis and immunity. MTs can be induced by a variety of conditions including metals, glucocorticoids, endotoxin, acute phase cytokines, stress, and irradiation. In addition to their important immunomodulatory functions, MTs can protect essential cellular compartments from toxicants, serve as a reservoir of essential heavy metals, and regulate cellular redox potential. Many of the roles of MTs in the neuroinflammation, intestinal inflammation, and stress response have been investigated and were the subject of a session at the 6th International Congress on Stress Proteins in Biology and Medicine in Sheffield, UK. Like the rest of the cell stress response, there are therapeutic opportunities that arise from an understanding of MTs, and these proteins also provide potential insights into the world of the heat shock protein.     

Arrestin mobilizes signaling proteins to the cytoskeleton and redirects their activity

Arrestins regulate the activity and subcellular localization of G protein-coupled receptors and other signaling molecules. Here, we demonstrate that arrestins bind microtubules (MTs) in vitro and in vivo. The MT-binding site on arrestins overlaps significantly with the receptor-binding site, but the conformations of MT-bound and receptor-bound arrestin are different. Arrestins recruit ERK1/2 and the E3 ubiquitin ligase Mdm2 to MTs in cells, similar to the arrestin-dependent mobilization of these proteins to the receptor. Arrestin-mediated sequestration of ERK to MTs reduces the level of ERK activation. In contrast, recruitment of Mdm2 to MTs by arrestin channels Mdm2 activity toward cytoskeleton-associated proteins, increasing their ubiquitination dramatically. The mobilization of signaling molecules to MTs is a novel biological function of arrestin proteins.     

Assembly of cortical microtubules during cold treatment of the coenocytic green alga,Chaetomorpha moniligera

The effects of cold treatment on the cortical microtubules (MTs) of Chaetomorpha moniligera Kjellman were investigated by immunofluorescence microscopy. Cortical MTs in Chaetomorpha thallus are arranged longitudinally. In this study, 70–75% of MTs disassembled within 4 h on ice while the others remained stable under these conditions. Reticulate background immunofluorescence, assumed to indicate the presence of a tubulin monomer, was distributed about the stable MTs. Immunofluorescence was prominent in only 50% of the cells. Tubulin polymerization was noted where the background and MT immunofluorescence was strong. New MTs grew transversely as single strings or clusters from the sides of MTs after cold treatment for 4 h and elongated with time to take on a reticulate form at 24 h. The significance of this tubulin polymerization under cold treatment is discussed.Abbreviations MT microtubule - MTOC microtubule-organizing center     

FRET and FRAP imaging: Approaches to characterise tau and stathmin interactions with microtubules in cells

Microtubules (MTs) are involved in many crucial processes such as cell morphogenesis, mitosis and motility. These dynamic structures resulting from the complex assembly of tubulin are tightly regulated by stabilising MT‐associated proteins (MAPs) such as tau and destabilising proteins, notably stathmin. Because of their key role, these MAPs and their interactions have been extensively studied using biochemical and biophysical approaches, particularly in vitro. Nevertheless, numerous questions remain unanswered and the mechanisms of interaction between MT and these proteins are still unclear in cells. Techniques coupling cell imaging and fluorescence methods, such as Förster resonance energy transfer and fluorescence recovery after photobleaching, are excellent tools to study these interactions in situ. After describing these methods, we will present emblematic data from the literature and unpublished experimental results from our laboratory concerning the interactions between MTs, tau and stathmin in cells.     

Peculiarities of the Molecular Structure and Functions of Metallothioneins in the Central Nervous System

This review presents modern concepts on the structure and principles of classification of low-molecular-weight proteins capable of binding with metal ions, metallothioneins (MTs). The mechanism underlying the binding of metals with these biopolymers is characterized; the main functions of MTs in the CNS, their role in defense reactions of neurons and other cells, as well as of those of the organism in general are reviewed.     

Mammalian metallothionein

Chemical, spectroscopic, and structural studies have established the metallothioneins (MTs) to be a widely occurring family of polypeptidic bioinorganic structures. They are distinguished by an extremely high metal (Zn, Cd, Cu) and Cys content and by the arrangement of these components in metal-thiolate clusters. By structural criteria the MTs have recently been subdivided into three classes (Fowler et al.,Experientia Suppl. 52, 19–22, 1987). Class I MTs include mammalian MTs and related forms. Class II MTs display no such relationships, and Class III MTs are atypical polypeptides made up of repetitive γ-glutamylcysteinyl units. Amino acid sequences of over 50 MTs are now known. In mammals, over 55% of the residues, including the 20 Cys, are conserved. Mammalian MTs are genetically polymorphous. Thus, in human tissues and cell lines closely related structures of ten functional isoMTs have been determined either by amino acid or nucleotide sequencing. A comparable degree of polymorphism also exists in the rabbit. Mammalian MTs have been inferred to bind a total of seven bivalent metal ions (Me) through thiolate coordination in two separate clusters, i.e., Me(II)₃(Cys)₉ and Me(II)₄(Cys)₁₁. This two-cluster model has now fully been confirmed by the spatial structures of rat MT-2 and rabbit MT-2a determined by 2D NMR spectroscopy in aqueous solution.     

Stu2p and XMAP215: turncoat microtubule-associated proteins?

The dynamics of microtubule-based (MT) cytoskeletons are controlled by a variety of accessory proteins: microtubule-associated proteins (MAPs), which usually stabilize MTs, and microtubule-destabilizers. Two related MAPs, XMAP215 and Stu2p, are known to stabilize MTs. However, recent studies report that these proteins have a MT-destabilizing function as well. Here we discuss the implications of these reports.     

Identification of microtubule binding sites in the Ncd tail domain

Nonclaret disjunctional (Ncd) is a minus end-directed, C-terminal motor protein that is required for spindle assembly and maintenance during meiosis and early mitosis in Drosophila oocytes and early embryos. Ncd has an ATP-independent MT binding site in the N-terminal tail domain, and an ATP-dependent MT binding site in the C-terminal motor domain. The ability of Ncd to cross-link MTs through the action of these binding sites may be important for Ncd function in vivo. To identify the region(s) responsible for ATP-independent MT interactions of Ncd, 12 cDNAs coding various regions of Ncd tail domain were expressed in E. coli as C-terminal fusions to thioredoxin (Trx). Ncd tail fusion proteins (TrxNT) were purified by ion exchange (S-Sepharose) and/or Talon metal affinity chromatography. Purified TrxNT and NT proteins were analyzed in microtubule (MT) cosedimentation and bundling assays to identify which tail proteins were able to bind and bundle MTs. Based on the results of these experiments, all TrxNT and NT proteins that showed MT binding activity also bundled MTs, and there are two ATP-independent MT interaction sites in the tail region: one within amino acids 83-100 that exhibits conformation-independent, high-affinity MT binding activity; and another within amino acids 115-187 that exhibits conformation-dependent, lower affinity MT binding activity. It is possible that both of these MT interacting sites combine in the native protein to form a single MT binding site that allows the Ncd tail to bind cargo MTs in vivo.     

Two new members of the Tetrahymena multi-stress-inducible metallothionein family: Characterization and expression analysis of T. rostrata Cd/Cu metallothionein genes.

We report the cloning and characterization of two new metallothionein (MT) genes (TrosMTT1 and TrosMTT2), isolated as cDNAs, from the ciliated protozoa Tetrahymena rostrata. The TrosMTT1 inferred protein has been identified as a CdMT and included into the 7a subfamily of Tetrahymena MTs, while TrosMTT2 has been identified as a CuMT (including it into 7b subfamily), due to its similarity to TpigMT-2 and its significant induction by copper. TrosMTT1 protein sequence reveals a remarkably regular and hierarchical modular organization, as it is known for other Tetrahymena CdMTs, showing a bi-modular structure. TrosMTT2 presents a structural organization based on CKCX(2-5)CKC repeats, like it occurs in other Tetrahymena CuMTs, indicating that an evolutionary history based on intra-gene duplications might be also possible. Both are also multi-stress-inducible genes because they are induced by other heavy metals and stressors, as it has been shown by quantitative real-time RT-PCR. It is the first time that the gene expression of a putative Tetrahymena CuMT is analyzed by quantitative PCR, confirming it as a CuMT. These two new Tetrahymena MTs complete, at present, the actual view of this protein superfamily, and corroborate the unique features of ciliate MTs. Furthermore, both, a comparative analysis of relative gene expression values obtained by quantitative RT-PCR on other Tetrahymena MT genes and an analysis of the different Tetrahymena MTs based on the different Cys clusters of these proteins are carried out, which show an update view of Tetrahymena MT gene family.     

Electrospray ionization mass spectrometry of zinc, cadmium, and copper metallothioneins: evidence for metal-binding cooperativity

Electrospray ionization (ESI) mass spectra of both well-characterized and novel metallothioneins (MTs) from various species were recorded to explore their metal-ion-binding modes and stoichiometries. The ESI mass spectra of the zinc- and cadmium-binding MTs showed a single main peak corresponding to metal-to-protein ratios of 4, 6, or 7. These findings combined with data obtained by other methods suggest that these MTs bind zinc or cadmium in a single predominant form and are consistent with the presence of three- and four-metal clusters. An unstable copper-specific MT isoform from Roman snails (Helix pomatia) could be isolated intact and was shown to preferentially bind 12 copper ions. To obtain additional information on the formation and relative stability of metal-thiolate clusters in MTs, a mass spectrometric titration study was conducted. One to seven molar equivalents of zinc or of cadmium were added to metal-free human MT-2 at neutral pH, and the resulting complexes were measured by ESI mass spectrometry. These experiments revealed that the formation of the four-metal cluster and of the thermodynamically less stable three-metal cluster is sequential and largely cooperative for both zinc and cadmium. Minor intermediate forms between metal-free MT, Me4MT, and fully reconstituted Me7MT were also observed. The addition of increasing amounts of cadmium to metal-free blue crab MT-I resulted in prominent peaks whose masses were consistent with apoMT, Cd3MT, and Cd6MT, reflecting the known structure of this MT with two Me3Cys9 centers. In a similar reconstitution experiment performed with Caenorhabditis elegans MT-II, a series of signals corresponding to apoMT and Cd3MT to Cd6MT species were observed.