Molecular characterization and function analysis of MT-10 and MT-20 metallothionein isoforms from Mytilus galloprovincialis

Structure and function of molluscan metallothioneins (MTs) are still poorly understood. The sea mussel Mytilus galloprovincialis displays two MT isoforms which differ in both primary sequences and physiological functions. MT-10 is the constitutive isoform, whereas MT-20 is mainly induced by cadmium (Cd). Both MTs were produced as recombinant proteins and showed identical Cd content and similar Cd-binding properties. Conversely, circular dichroism disclosed marked differences in the secondary conformations of the two Cd(7)-MTs. The possible relapses of these structural differences on protein stability and function were assessed. MT-10 presented a higher thermal stability and a more compact structure than MT-20, as it was inferred by absorption and emission spectroscopy studies. Moreover, the kinetics of Cd-release clearly indicated that MT-10 is much more sensitive to oxidation than is MT-20. The observed differences between MT-10 and MT-20 are discussed in terms of the different physiological roles exerted by the two isoforms in mussel.     

Induction,Regulation, Degradation,and Biological Significance of Mammalian Metallothioneins

MTs are small cysteine-rich metal-binding proteins found in many species and, although there are differences between them, it is of note that they have a great deal of sequence and structural homology. Mammalian MTs are 61 or 62 amino acid polypep-tides containing 20 conserved cysteine residues that underpin the binding of metals. The existence of MT across species is indicative of its biological demand, while the conservation of cysteines indicates that these are undoubtedly central to the function of this protein. Four MT isoforms have been found so far, MT-1, MT-2, MT-3, and MT-4, but these also have subtypes with 17 MT genes identified in man, of which 10 are known to be functional. Different cells express different MT isoforms with varying levels of expression perhaps as a result of the different function of each isoform. Even different metals induce and bind to MTs to different extents. Over 40 years of research into MT have yielded much information on this protein, but have failed to assign to it a definitive biological role. The fact that multiple MT isoforms exist, and the great variety of substances and agents that act as inducers, further complicates the search for the biological role of MTs. This article reviews the current knowledge on the biochemistry, induction, regulation, and degradation of this protein in mammals, with a particular emphasis on human MTs. It also considers the possible biological roles of this protein, which include participation in cell proliferation and apoptosis, homeostasis of essential metals, cellular free radical scavenging, and metal detoxification.     

Induction, regulation, degradation, and biological significance of mammalian metallothioneins

MTs are small cysteine-rich metal-binding proteins found in many species and, although there are differences between them, it is of note that they have a great deal of sequence and structural homology. Mammalian MTs are 61 or 62 amino acid polypeptides containing 20 conserved cysteine residues that underpin the binding of metals. The existence of MT across species is indicative of its biological demand, while the conservation of cysteines indicates that these are undoubtedly central to the function of this protein. Four MT isoforms have been found so far, MT-1, MT-2, MT-3, and MT-4, but these also have subtypes with 17 MT genes identified in man, of which 10 are known to be functional. Different cells express different MT isoforms with varying levels of expression perhaps as a result of the different function of each isoform. Even different metals induce and bind to MTs to different extents. Over 40 years of research into MT have yielded much information on this protein, but have failed to assign to it a definitive biological role. The fact that multiple MT isoforms exist, and the great variety of substances and agents that act as inducers, further complicates the search for the biological role of MTs. This article reviews the current knowledge on the biochemistry, induction, regulation, and degradation of this protein in mammals, with a particular emphasis on human MTs. It also considers the possible biological roles of this protein, which include participation in cell proliferation and apoptosis, homeostasis of essential metals, cellular free radical scavenging, and metal detoxification.     

Metallothionein: a multifunctional protein from toxicity to cancer

The metallothionein (MT) family is a class of low molecular weight, intracellular and cysteine-rich proteins presenting high affinity for metal ions. Although the members of this family were discovered nearly 40 years ago, their functional significance remains obscure. Four major MT isoforms, MT-1, MT-2, MT-3 and MT-4, have been identified in mammals. MTs are involved in many pathophysiological processes such as metal ion homeostasis and detoxification, protection against oxidative damage, cell proliferation and apoptosis, chemoresistance and radiotherapy resistance. MT isoforms have been shown to be involved in several aspects of the carcinogenic process, cancer development and progression. MT expression has been implicated as a transient response to any form of stress or injury providing cytoprotective action. Although MT participates in the carcinogenic process, its use as a potential marker of tumor differentiation or cell proliferation, or as a predictor of poor prognosis remains unclear. In the present review the involvement of MT in defense mechanisms to toxicity and in carcinogenicity is discussed.     

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.     

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.     

Fish and molluscan metallothioneins

Metallothioneins (MTs) are noncatalytic peptides involved in storage of essential ions, detoxification of nonessential metals, and scavenging of oxyradicals. They exhibit an unusual primary sequence and unique 3D arrangement. Whereas vertebrate MTs are characterized by the well-known dumbbell shape, with a beta domain that binds three bivalent metal ions and an alpha domain that binds four ions, molluscan MT structure is still poorly understood. For this reason we compared two MTs from aquatic organisms that differ markedly in primary structure: MT 10 from the invertebrate Mytilus galloprovincialis and MT A from Oncorhyncus mykiss. Both proteins were overexpressed in Escherichia coli as glutathione S-transferase fusion proteins, and the MT moiety was recovered after protease cleavage. The MTs were analyzed by gel electrophoresis and tested for their differential reactivity with alkylating and reducing agents. Although they show an identical cadmium content and a similar metal-binding ability, spectropolarimetric analysis disclosed significant differences in the Cd7-MT secondary conformation. These structural differences reflect the thermal stability and metal transport of the two proteins. When metal transfer from Cd7-MT to 4-(2-pyridylazo)resorcinol was measured, the mussel MT was more reactive than the fish protein. This confirms that the differences in the primary sequence of MT 10 give rise to peculiar secondary conformation, which in turn reflects its reactivity and stability. The functional differences between the two MTs are due to specific structural properties and may be related to the different lifestyles of the two organisms.     

The metallothionein genes of Mytilus galloprovincialis: genomic organization, tissue expression and evolution

Recently, increasing interest has been directed to the study of metallothioneins (MTs), which are small proteins that are able to bind metal ions. The induction of MT synthesis after exposure to metal or other environmental contaminants in a large number of aquatic invertebrates makes these proteins good biomarkers in water monitoring programs. Within bivalves, the species Mytilus galloprovincialis and Mytilus edulis represent model organisms for these types of studies, as well as for molecular studies regarding the expression and characterization of MT encoding genes. In the present paper, we focused on the genomic characterization, evolutionary, and tissue-expression analyses of the MT-10, MT-10 Intronless, and MT-20 genes in M. galloprovincialis. The comparison of the genomic sequences showed the presence of long nucleotide stretches within the introns of the MT genes that are conserved between M. galloprovincialis and M. edulis. These non-coding conserved sequences may contain regulatory motifs. Real-Time RT-PCR experiments revealed that, at the basal conditions, the MT-10 and MT-10 Intronless genes are expressed at levels considerably higher than the MT-20 gene, mainly in the digestive gland and gill tissue. The strong induction of the MT-20 gene expression detected in a field-collected sample is associated with the up-regulation of both the MT-10 and MT-10 Intronless genes. Evolutionary analysis revealed signals of localized positive selection that, together with the tissue-expression data, support a possible functional diversification between the MTs encoded by the MT-10 and MT-10 Intronless genes.     

Metallothioneins in terrestrial invertebrates: structural aspects, biological significance and implications for their use as biomarkers.

During the last few years the subject of metallothioneins (MTs) in terrestrial invertebrates has gained increasing attention. One reason for this may be that terrestrial invertebrates provide new insights into the biological diversity of MTs, with the potential of discovering alternative models of structural and functional relationships. Four groups of terrestrial invertebrates have been studied in detail, namely nematodes, insects, snails and earthworms, with the present article focusing on MTs from the latter two groups. Snails are interesting because they possess distinct MT isoforms involved in different metal-specific tasks. In the Roman snail (Helix pomatia), for example, one isoform is predominantly expressed in the midgut gland, accounting for the accumulation, binding and detoxification of cadmium. The second isoform, which is present in the snail's mantle, is substantially different regarding its primary structure. Furthermore, it binds nearly exclusively copper, and thus is probably involved in the homeostatic regulation of essential trace elements. Earthworm MTs merit our attention because of another peculiarity: they seem to be much more unstable than snail MTs, particularly under conventional conditions of preparation. The cDNA of the brandling worm (Eisenia foetida), for instance, codes for a putative MT, which is about twice the size of the actual protein. The isolated MT peptide binds four Cd2+ ions and represents a one-domain MT entity that is stable and functional in vitro. This strongly suggests that earthworm MTs are either posttranslationally modified, or subjected to enzymatic cleavage during preparation. Both snail and earthworm MTs are inducible by metal exposure, especially by cadmium, thus supporting the idea of using them as potential biomarkers for environmental metal pollution. Whilst snail MTs have already been tested in this respect with some success, the use of earthworm MTs as biomarkers still remains to be evaluated, especially in the light of the unknown significance of their posttranslational instability.     

瞬时转染金属硫蛋白-3基因后人神经母细胞瘤细胞系SH—SY5Y细胞的蛋白质差异表达

金属硫蛋白 3(MT 3) ,又称神经生长抑制因子 ,主要表达于中枢神经系统。它属于金属硫蛋白家族 ,但具有几项其他家族蛋白质如MT 1/ 2等所不具有的独特性质 ,是一种多功能蛋白质 ,可在中枢神经系统中发挥重要的神经调节和神经保护作用 ,但是具体发挥机制还很不清楚。实验以人神经母细胞瘤细胞系SH SY5Y为模型 ,运用最近发展起来的比较蛋白质组学研究方法对MT 3基因瞬时转染引起的SH SY5Y细胞蛋白质的整体变化进行了系统的研究。经考马斯亮蓝染色 ,结果表明 ,MT 3转基因后平均每块胶上可检测到约 75 0个蛋白质点。利用ImageMaster 2DElite软件对胶上的蛋白质点进行半定量分析 ,发现共有 17个蛋白质点呈显著的变化 :和对照组比较 ,在这 17个点中 ,有 12个表达明显上调 ,有 5个表达水平明显下降 ,实验结果具有可重复性。结合pI值和分子量 ,应用基质辅助激光解吸 /电离飞行时间质谱对这 17个点进行分析 ,鉴定了其中 10个点 ,包括类锌指蛋白 ,谷氨酸转运蛋白和增强蛋白等。这些蛋白质都可在神经系统功能的调节中发挥作用。实验结果表明MT 3可能是通过调节和 /或协同这些蛋白质来发挥它的多种功能的。     

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.     

Isolation and characterization of Mytilus edulis metallothionein genes

Metallothioneins (MTs) are crucial proteins in all organisms for the regulation of essential metals and the detoxification of heavy metals. Many studies have estimated MT levels in mussel tissues to detect marine metal pollution. In this study, we investigated the MT gene structures of the forms present in Mytilus edulis (blue mussel). One MT-10 (2413 bp) gene and one MT-20 (1906 bp) gene were obtained. These MT genes contain three exons and two long introns. The splicing signals for MT-10 and MT-20 were GTA(T/A)GT-(C/T)AG. The structural organization (length of intron, splicing signals, AT content) of MT-10 and MT-20 is compared with other MT genes.     

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.     

The Properties of the Metal–Thiolate Clusters in Recombinant Mouse Metallothionein-4

Metallothioneins (MTs) are metal-binding proteins with low molecular weight and conservative cysteine residues. Metallothionein-4 (MT-4), one of MT isoforms, is first reported to be distributed in a tissue-specific manner, mainly in stratified squamous epithelia. Here, we compare the properties of metal–thiolate clusters in MT-4 to those in MT-1 and MT-3, including the stabilities toward both pH change and EDTA, as well as the exposure of thiolates to solvent. The metal–thiolate clusters in MT-3 show different property and activity to the reactions compared with MT-4 and MT-1. The structure of metal–thiolate clusters in MT-4 is similar to that of MT-1 from the UV and CD spectra. During pH titration and DTNB reaction, MT-4 and MT-1 exhibit comparable behavior. But while reacting with EDTA, the metal–thiolate clusters in MT-4 are more stable than those of MT-1. We suppose the negative charge of the β-domain of MT-4 prevents the EDTA attack to MT-4.     

Immunological and biochemical properties of metallothioneins of golden hamster,mouse and rat

Summary Golden hamster, mouse and rat hepatic cadmium metallothioneins (MT) were purified by Sephadex G-75 gel filtration, DEAE-Sephadex A-25 chromatography and activated Thiol-Sepharose 4B affinity chromatography. Metallothioneins were separated by DEAE-Sephadex A-25 chromatography into two forms: MT-1 and MT-2. In mouse and golden hamster liver, MT-1 was the major form. The purified proteins were homogeneous as judged by polyacrylamide gel electrophoresis in the presence and absence of sodium dodecyl sulfate. In non-denaturing polyacrylamide gel electrophoresis, migration of mouse, rat and golden hamster hepatic metallothioneins were found to be different. Antibodies to mouse hepatic MT-1 was raised in rabbits. The antiserum cross reacted with mouse and hamster MT-1 and MT-2 giving a single precipitin band. Mouse, rat and hamster hepatic MTs are immunologically identical but electrophoretically different. The kidney and pancreatic MTs of rat and golden hamster were purified by Sephadex G-75 gel filtration. They were immunologically distinct. Pancreas MT formed a line of partial identity with hepatic MTs. Kidney MTs form two precipitin band one identical with the pancreatic form and another of complete identity with the hepatic MTs. This indicates the presence of tissue specific MTs.     

Three-dimensional structure and dynamics of a brain specific growth inhibitory factor: metallothionein-3

The brain specific member of the metallothionein (MT) family of proteins, metallothionein-3, inhibits the growth and survival of neurons, in contrast to the ubiquitous mammalian MT isoforms, MT-1 and MT-2, that are found in most tissues and are thought to function in metal ion homeostasis and detoxification. Solution NMR was utilized to determine the structural and dynamic differences of MT-3 from MT-1 and 2. The high-resolution solution structure of the C-terminal alpha-domain of recombinant mouse MT-3 revealed a tertiary fold very similar to MT-1 and 2, except for a loop that accommodates an acidic insertion relative to these isoforms. This loop was distinguished from the rest of the domain by dynamics of the backbone on the nano- to picosecond time-scale shown by (15)N relaxation studies and was identified as a possible interaction site with other proteins. The N-terminal beta-domain contains the region responsible for the growth inhibitory activity, a CPCP tetrapeptide close to the N-terminus. Because of exchange broadening of a large number of the NMR signals from this domain, homology modeling was utilized to calculate models for the beta-domain and suggested that while the backbone fold of the MT-3 beta-domain is identical to MT-1 and 2, the second proline responsible for the activity, Pro9, may show structural heterogeneity. (15)N relaxation analyses implied fast internal motions for the beta-domain. On the basis of these observations, we conclude that the growth inhibitory activity exhibited by MT-3 is a result of a combination of local structural differences and global dynamics in the beta-domain.