中华鳖肝金属硫蛋白的分离、纯化及鉴定

金属硫蛋白metallothionein,MT)是一类低分子量、富含半胱氨酸的金属结合蛋白。MT几乎广泛分布于所有生物,包括哺乳动物、两栖动物、鱼、植物、真菌和蓝细菌,不同生物金属硫蛋白理化特性和其氨基酸序列及中心片段的比较研究,对研究MT的结构和生物功能及生物的分子进化提供重要依据。哺乳动物MT研究较多,爬行动物鳖MT的研究尚属空白,本文报道鳖肝的金属硫蛋白,中华鳖（Pelodiscus sinensis)分别经皮下注射ZnSO4,CuSO4和CdCl2溶液诱导后,取乙醇沉淀的肝脏无细胞提取液再经SephadexG-50、DEAE-SepharoseCL-6B及SephadexG-25凝胶过滤和离子交换柱层析分离,自鳖肝脏中分别获得Zn-MT、Cu-MT和Cd-MT,未经诱导的鳖肝脏中无MT,质谱和HPLC分析其分子量约为6300dalton。根据氨基酸组成分析。鳖肝脏MT含61个氨基酸残基,其中MT的典型氨基酸Cys含量占17%。Lys,Glu和Asp含量较高,而芳香族氨基酸和组氨酸含量极低,从紫外光谱特性分析,Zn-MT、Cu-MT、Cd-MT紫外吸收肩分别在220nm、270nm和250nm。表明确为鳖肝脏MT。从氨基酸残基数和分子量看,鳖肝脏MT与哺乳动物MT类似;而从氨基酸组成和结合金属离子的量看,又与低等生物蚯蚓酵母菌的MT类似。鳖MT的特性介于哺乳动物MT与低等生物MT之间,体现了鳖这种生物进化的特点。     

中华鳖肝金属硫蛋白的分离、纯化及鉴定（英文）

金属硫蛋白(metallothionein,MT)是一类低分子量、富含半胱氨酸的金属结合蛋白.MT几乎广泛分布于所有生物,包括哺乳动物、两栖动物、鱼、植物、真菌和蓝细菌.不同生物金属硫蛋白理化特性和其氨基酸序列及中心片段的比较研究,对研究MT的结构和生物功能及生物的分子进化提供重要依据.哺乳动物MT研究较多,爬行动物鳖MT的研究尚属空白,本文报道鳖肝的金属硫蛋白.中华鳖 (Pelodiscus sinensis) 分别经皮下注射ZnSO4、CuSO4和CdCl2 溶液诱导后,取乙醇沉淀的肝脏无细胞提取液再经Sephadex G-50、DEAE-SepharoseCL-6B 及SephadexG-25凝胶过滤和离子交换柱层析分离,自鳖肝脏中分别获得Zn-MT、Cu-MT和Cd-MT,未经诱导的鳖肝脏中无MT.质谱和HPLC分析其分子量约为6 300 dalton.根据氨基酸组成分析,鳖肝脏MT含61个氨基酸残基,其中MT的典型氨基酸Cys含量占17%.Lys、Glu和Asp含量较高,而芳香族氨基酸和组氨酸含量极低.从紫外光谱特性分析,Zn-MT、Cu-MT、Cd-MT紫外吸收肩分别在220 nm、270 nm和250 nm.表明确为鳖肝脏MT.从氨基酸残基数和分子量看,鳖肝脏MT与哺乳动物MT类似;而从氨基酸组成和结合金属离子的量看,又与低等生物蚯蚓及酵母菌的MT类似.鳖MT的特性介于哺乳动物MT与低等生物MT之间,体现了鳖这种生物进化的特点.     

金属硫蛋白及其生物学功能

金属硫蛋白(metallothionein, MT) 是一类富含半胱氨酸的低分子质量蛋白质,已鉴定4种亚型：MT-1、MT-2、MT-3和MT-4,基于各亚型功能的相对异质性而使MT呈现其生物学作用的多样性。金属硫蛋白通过与金属离子结合而参与基因表达调控和机体的重金属解毒过程;金属硫蛋白通过抑制多种氧化应激途径而保护细胞免受损伤;金属硫蛋白通过参与细胞的增殖、分化和凋亡的调节而影响肿瘤及其他重大疾病的发生发展。本文在金属硫蛋白的结构和分类的基础上综述其生物学作用及其相关机制。     

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.     

High-yield expression in Escherichia coli of soluble human MT2A with native functions

Metallothioneins (MTs) are a family of low molecular weight, cysteine rich heavy metal binding proteins with multifunction, such as metal detoxification and antioxidation, and are involved in a number of cellular processes including gene expression, apoptosis, proliferation and differentiation. However, high yield expression of human MT in Escherichia coli has not been established effectively. To produce large amounts of human MT protein at low cost, recombinant human metallothionein 2A (MT2A) protein with an N-terminal GST tag was successfully expressed at high levels in soluble form in E. coli and high purification of it was established by affinity chromatography under native conditions. The final yield was about 5mg of the recombinant MT2A per liter of bacterial culture with the purity of 97.9%. Chemical and functional characteristics analysis of the recombinant human MT2A exhibited intact metal binding ability, hydroxyl radical scavenging ability and significant protective role against DNA damage caused by UVC radiation. Establishment of highly purified recombinant human MT2A protein with native characteristics at low cost would improve its function study and wide applications in protecting against oxidative damage and UV radiation.     

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.     

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.     

Spectroscopic characterization of a fruit-specific metallothionein: M. acuminata MT3

Metallothioneins (MTs) are ubiquitous low molecular mass, cysteine-rich proteins with the ability to bind d¹⁰ metal ions in the form of metal-thiolate clusters. In contrast to the vertebrate forms, knowledge about the properties of members of the plant metallothionein family is still scarce. The amino acid sequences of plant MTs are distinctively different to the sequences of other MT species. The protein under investigation, Musa acuminata (banana) MT3, belongs to the plant MT fruit-specific p3 subfamily. With a total of 10 cysteine residues, MT3 features a cysteine content and percentage that is more comparable to fungal and prokaryotic MTs than to the well characterized mammalian iso-forms. The gene sequence encoding MT3 was cloned into a suitable vector and the protein was recombinantly overexpressed in Escherichia coli. MT3 is able to coordinate a maximum of four divalent d¹⁰ metal ions under the formation of metal-thiolate clusters. The hitherto unknown spectroscopic behavior of MT3 in combination with the metal ions Zn²⁺, Cd²⁺, Pb²⁺, and Hg²⁺ will be presented and gives rise to the existence of a weaker metal ion coordination site. The pH stability of the investigated zinc and cadmium clusters is comparable to the values found for other plant metallothioneins though significantly lower than for the mammalian iso-forms. Possible metal-thiolate cluster structures will additionally be discussed.     

Recent developments in quantification methods for metallothionein.

The metallothioneins (MT), a family of proteins with relatively low molecular weight (6-7 kDa), are characterised by the intrinsic presence of 20 cysteinyl groups in their structure, which confers unique metal binding properties to the molecule. Since MT are involved in biological roles, quantification of MT remains an important task. To date, a large number of determination methods have been developed. In this paper recent developments, from 1995 to the present, in methodology employed in quantification studies of total MT and MT polymorphism are described. Different fields were taken into consideration, such as (i) separation techniques and hyphenated systems, (ii) electrochemical methods, (iii) immunological methods and (iv) quantification of MT mRNA. The data presented are based on our own and published results. A brief overview of the use of metallothionein as a biomarker is included as a relevant example of the importance of MT quantification. Finally, general problems associated with determination and evaluation of obtained results within the above four topics are mentioned.     

Isolation and characterization of a self-sufficient one-domain protein. (Cd)-metallothionein from Eisenia foetida.

Earthworms have been shown to accumulate trace elements in general, and particularly high amounts of metal ions such as cadmium, copper and zinc. The earthworm's response to metal contamination has been linked to the induction and expression of metallothionein (MT) proteins, a detoxification strategy analogous to that found in other biological systems. The present study focuses on an inducible Cd-MT isolated from the compost-dwelling brandling worm Eisenia foetida (Savigny). A full characterization of the protein (including protein induction, MT cDNA, amino-acid sequence and metal stoichiometry) revealed a new dimension of knowledge to the molecular genetic information available to date. Whereas the elucidated cDNA codes for a putative protein which possesses 80 amino-acid residues, the characterized protein bears only 41 amino acids. The isolated product has evidently attained its size and shape by cleavage near the N-terminal site and at the linker region between the two putative metal-binding domains of the translated product, yielding a small MT moiety which contains 12 Cys residues (including one triple Cys-motif) binding four cadmium ions. It can be shown that the isolated MT molecule represents a self-sufficient one-domain MT which is stable in vitro. The isolation of the single-domain MT peptide raises the question about the method of formation and significance in vivo of such small MT moieties from tissues of E. foetida and possibly other terrestrial invertebrates. In this respect, two hypotheses are discussed: firstly, the possibility of formation of small MT peptides due to enzymatic cleavage of the intact protein during the process of preparation and isolation; and secondly, the possibility of deliberate post-translational processing of the translated gene product to yield functional one-domain MT moieties.     

Metal binding properties and structure of a type III metallothionein from the metal hyperaccumulator plant Noccaea caerulescens

Metallothioneins (MT) are low molecular weight proteins with cysteine-rich sequences that bind heavy metals with remarkably high affinities. Plant MTs differ from animal ones by a peculiar amino acid sequence organization consisting of two short Cys-rich terminal domains (containing from 4 to 8 Cys each) linked by a Cys free region of about 30 residues. In contrast with the current knowledge on the 3D structure of animal MTs, there is a striking lack of structural data on plant MTs. We have expressed and purified a type III MT from Noccaea caerulescens (previously Thlaspi caerulescens). This protein is able to bind a variety of cations including Cd(2+), Cu(2+), Zn(2+) and Pb(2+), with different stoichiometries as shown by mass spectrometry. The protein displays a complete absence of periodic secondary structures as measured by far-UV circular dichroism, infrared spectroscopy and hydrogen/deuterium exchange kinetics. When attached onto a BIA-ATR biosensor, no significant structural change was observed upon removing the metal ions.     

Binding of coagulation factor XI to washed human platelets

The binding of human coagulation factor XI to washed human platelets was studied in the presence of zinc ions, calcium ions, and high molecular weight kininogen. Significant factor XI binding occurred at physiological levels of these metal ions when high molecular weight kininogen was present. Binding required platelet stimulation and was specific, reversible, and saturable. Scatchard analysis of the binding yielded approximately 1500 binding sites per platelet with an apparent dissociation constant of approximately 10 nM. Since the concentration of factor XI in plasma is about 25 nM, this suggests that in plasma factor XI binding sites on stimulated platelets might be saturated. Calcium ions and high molecular weight kininogen acted synergistically to enhance the ability of low concentrations of zinc ions to promote factor XI binding. The similarity between the concentrations of metal ions optimal for factor XI binding and those optimal for high molecular weight kininogen binding, as well as the ability of high molecular weight kininogen to modulate these metal ion effects, implies that factor XI and high molecular weight kininogen may form a complex on the platelet surface as they do in solution and on artificial negatively charged surfaces.     

水生动物金属硫蛋白分子毒理学研究进展

随着现代工业的迅速发展,重金属污染问题日益严重。重金属离子主要通过水及食物进入生物机体并累积,对机体的生长发育与新陈代谢产生危害。金属硫蛋白（MT）是一种低分子量、富含半胱氨酸的蛋白质,广泛存在于大多数生物体内,在必需金属元素稳态调节、非必需金属元素解毒以及抗氧化等过程中具有重要作用,因此,MT可作为检测水生生态系统中重金属污染的潜在生物标记,其分子毒理学已成为研究热点。综述了MT的结构、功能、分类与分布,以及鱼类、甲壳类和软体动物的MT分子毒理学研究概况。     

Possible role for metallothionein in protection against radiation-induced oxidative stress. Kinetics and mechanism of its reaction with superoxide and hydroxyl radicals

Rabbit liver metallothionein-1 (Mr 6500), which contains zinc and/or cadmium ions, appears to scavenge free hydroxyl (.OH) and superoxide (O-.2) radicals produced by the xanthine/xanthine oxidase reaction much more effectively than bovine serum albumin (Mr 65 000) which was used as a control. Kinetic competition studies between metallothionein and either a spin trap for .OH or ferricytochrome c for O-.2 radicals, gave bimolecular rate constants of the order of kOH/MT approximately equal to 10(12) M-1 X s-1 and kO-2/MT approximately equal to 5 X 10(5) M-1 X s-1, respectively. The former value suggests that all 20 cysteine sulfur atoms are involved in this quenching process and that they all act in the diffusion control limit. The aerobic radiolysis of an aqueous solution of metallothionein, generating O-.2 and .OH radicals, induced metal ion loss and thiolate oxidation. These effects could be reversed by incubation of the irradiated protein with reduced glutathione and the appropriate bivalent metal ion. Metallothionein appears to be an extraordinarily efficient .OH radical scavenger even when compared to proteins 10-50-times its molecular weight. Moreover, hydroxyl radical damage to metallothionein appears to occur at the metal-thiolate clusters, which may be repaired in the cell by reduced glutathione. Metallothionein has the characteristics of a sacrificial but renewable cellular target for .OH-mediated cellular damage.     

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.     

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.     

Influence of zinc ions on protein secretion in a heavy metal tolerant strain of the ericoid mycorrhizal fungas Oidiodendron maius

A heavy metal tolerant strain of the ericoid mycorrhizal species Oidiodendron maius, isolated from soil heavily contaminated with zinc, was previously shown to tolerate high concentrations of zinc and cadmium ions in the growth medium. We have investigated some of the specific molecular responses of this fungal strain to the presence of increasing concentrations of zinc ions in the growth medium. In particular, we show that zinc ions induce a general change in the array of secreted proteins, with a shift towards the production of more basic, low molecular weight polypeptides. Some of these proteins were microsequenced and identified through homology search in databases. Among them are hydrolytic enzymes (nuclease, proteinase, lysozyme) and two superoxide dismutase isoforms. The latter are antioxidant enzymes known to play a role in heavy metal response in plants, animals and microorganisms.     

Redox biochemistry of mammalian metallothioneins

Metallothionein (MT) is a generic name for certain families of structurally rather variable metal-binding proteins. While purely chemical or biological approaches failed to establish a single physiologic function for MTs in any species, a combination of chemical and biological approaches and recent progress in defining the low but significant concentrations of cytosolic free zinc(II) ions have demonstrated that mammalian MTs function in cellular zinc metabolism in specific ways that differ from conventional knowledge about any other metalloprotein. Their thiolate coordination environments make MTs redox-active zinc proteins that exist in different molecular states depending on the availability of cellular zinc and the redox poise. The zinc affinities of MTs cover a range of physiologic zinc(II) ion concentrations and are modulated. Oxidative conditions make more zinc available, while reductive conditions make less zinc available. MTs move from the cytosol to cellular compartments, are secreted from cells, and are taken up by cells. They provide cellular zinc ions in a chemically available form and participate in cellular metal muffling: the combination of physiologic buffering in the steady state and the cellular redistribution and compartmentalization of transiently elevated zinc(II) ion concentrations in the pre-steady state. Cumulative evidence indicates that MTs primarily have a redox-dependent function in zinc metabolism, rather than a zinc-dependent function in redox metabolism.     

Cadmium accumulation in organs of the scallop Mizuhopecten yessoensis--II. Subcellular distribution of metals and metal-binding proteins

Cd accumulation in the hepatopancreas and gills of the scallop resulted in an increase of metal concentration in the cytoplasm, while in control animals the general amount of Cd in the hepatopancreas was concentrated in the microsomes and cytoplasm. Cd appears to be equally distributed among high molecular weight proteins and metallothioneins in control animals. It was shown that during the experiment the metal was bound mainly to high molecular weight proteins. After 30 days of exposure of scallops to flowing water Cd was redistributed to metallothionein (MT)-like proteins. Cd concentration in the lipids of the hepatopancreas of control and experimental scallops was equal.