Structural and functional characterization of the Zn(II) site in dimethylargininase-1 (DDAH-1) from bovine brain. Zn(II) release activates DDAH-1.

L-N(omega),N(omega)-dimethylarginine dimethylaminohydrolase-1 (DDAH-1) is a Zn(II)-containing enzyme that, through hydrolysis of side-chain methylated l-arginines, regulates the activity of nitric-oxide synthase. Herein we report the structural and functional properties of the Zn(II)-binding site in DDAH-1 from bovine brain. Activity measurements of the native and metal-free enzyme have revealed that the endogenously bound Zn(II) inhibits the enzyme. Native DDAH-1 could be fully or partially activated using various concentrations of phosphate, imidazole, histidine, and histamine, a process that is paralleled by the release of Zn(II). The slow activation of the enzyme by the bulky complexing agents EDTA and 1,10-phenantroline suggests that the Zn(II)-binding site is partially buried in the protein structure. The apparent Zn(II)-dissociation constant of 4.2 nm, determined by 19F NMR using the chelator 5F-BAPTA (1,2-bis(2-amino-5-fluorophenoxy)ethane-N,N,N',N'-tetraacetic acid), lies in the range of intracellular free Zn(II) concentrations. These results suggest a regulatory role for the Zn(II)-binding site. The coordination environment of the Zn(II) in DDAH-1 has been examined by Zn K-edge x-ray absorption spectroscopy. The extended x-ray absorption fine structure observed is consistent with Zn(II) being coordinated by 2 S and 2 N (or O) atoms. The biological implications of these findings are discussed.

Roles of the metallothionein family of proteins in the central nervous system.

Metallothioneins (MTs) constitute a family of proteins characterized by a high heavy metal [Zn(II), Cu(I)] content and also by an unusual cysteine abundance. Mammalian MTs are comprised of four major isoforms designated MT-1 trough MT-4. MT-1 and MT-2 are expressed in most tissues including the brain, whereas MT-3 (also called growth inhibitory factor) and MT-4 are expressed predominantly in the central nervous system and in keratinizing epithelia, respectively. All MT isoforms have been implicated in disparate physiological functions, such as zinc and copper metabolism, protection against reactive oxygen species, or adaptation to stress. In the case of MT-3, an additional involvement of this isoform in neuromodulatory events and in the pathogenesis of Alzheimer's disease has also been suggested. It is essential to gain insight into how MTs are regulated in the brain in order to characterize MT functions, both in normal brain physiology, as well as in pathophysiological states. The focus of this review concerns the biology of the MT family in the context of their expression and functional roles in the central nervous system.

Reactivity of Cd7-metallothionein with Cu(II) ions: evidence for a cooperative formation of Cd3,Cu(I)5-metallothionein.

Reaction of Cd7-metallothionein-2 (MT) with Cu(II) ions has been studied by a variety of spectroscopic techniques including UV-absorption, circular dichroism (CD) and luminescence spectroscopy. The addition of up to 5 Cu(II) equivalents to Cd7-MT resulted in a cooperative formation of the monomeric Cd3,Cu5-MT form, as revealed by the analytical data and the presence of isosbestic or isodichroic points in the respective UV and CD spectra. The presence of Cu(I) luminescence and the absence of Cu(II) EPR signal indicated that copper is bound in the Cu(I) oxidation state, i.e., Cd3,Cu(I)5-MT. Consequently, the reduction of Cu(II) ions is accompanied by the oxidation of thiolate ligands of the protein. The absorption features and the luminescence data at 77 K are consistent with the presence of an air-stable Cu(I)-cluster in Cd3,Cu(I)5-MT. The participation of other ligands, besides cysteine thiolates, in metal coordination cannot be ruled out. With more than 5 Cu(II) equivalents added a mixture of unstable MT metalloforms were formed. The concomitant reduction and binding of copper ions by metallated MT represent a new aspect of the MT structure.

Solution structure of native proteins with irregular folds from Raman optical activity.

Raman optical activity (ROA) spectra have been measured for the proteins hen phosvitin, yeast invertase, bovine alpha-casein, soybean Bowman-Birk protease inhibitor, and rabbit Cd(7)-metallothionein, all of which have irregular folds in the native state. The results show that ROA is able to distinguish between two types of disorder. Specifically, invertase, alpha-casein, the Bowman-Birk inhibitor, and metallothionein appear to possess a "static" type of disorder similar to that in disordered states of poly(L-lysine) and poly(L-glutamic acid); whereas phosvitin appears to possess a more "dynamic" type of disorder similar to that in reduced (unfolded) lysozyme and ribonuclease A and also in molten globule protein states. In the delimiting cases, static disorder corresponds to that found in loops and turns within native proteins with well-defined tertiary folds that contain sequences of residues with fixed but nonrepetitive phi,psi angles; and dynamic disorder corresponds to that envisaged for the model random coil in which there is a distribution of Ramachandran phi,psi angles for each amino acid residue, giving rise to an ensemble of interconverting conformers. In both cases there is a propensity for the phi,psi angles to correspond to the alpha, beta and poly(L-proline) II (PPII) regions of the Ramachandran surface, as in native proteins with well-defined tertiary folds. Our results suggest that, with the exception of invertase and metallothionein, an important conformational element present in the polypeptide and protein states supporting the static type of disorder is that of the PPII helix. Long sequences of relatively unconstrained PPII helix, as in alpha-casein, may impart a plastic (rheomorphic) character to the structure.

A colorimetric 96-well microtiter plate assay for the determination of enzymatically formed citrulline.

l-Citrulline constitutes a product of a number of enzymatic reactions. In the past a number of colorimetric methods for the determination of l-citrulline, upon its chemical modification with diacetyl monoxime at 95 degrees C, have been reported. However, all these methods are time- and material-consuming. In this work, using the same chemical reaction, a new method for the use in 96-well polystyrene microtiter plates was developed. The method is fast and requires substantially less material as the enzymatic reaction is performed in a volume of 60 microl. The applicability of this enzymatic assay was established using l-N(omega), N(omega)-dimethylarginine dimethylaminohydrolase, which generates l-citrulline from side-chain methylated derivatives of l-arginine. The detection limit for l-citrulline is about 0.2 nmol. In addition, our studies show that most commonly used biochemical buffers and buffer additives do not affect the assay. This method may prove useful in the studies of other l-citrulline producing enzymes including nitric oxide synthase.

Effect of the two conserved prolines of human growth inhibitory factor (metallothionein-3) on its biological activity and structure fluctuation: comparison with a mutant protein.

Human neuronal growth inhibitory factor, a metalloprotein classified as metallothionein-3 (MT-3), impairs the survival and the neurite formation of cultured neurons. In these studies the double P7S/P9A mutant (mutMT-3) and single mutants P7S and P9A of human Zn(7)-MT-3 were generated, and their effects on the biological activity and the structure of the protein were examined. The biological results clearly established the necessity of both proline residues for the inhibitory activity, as even single mutants were found to be inactive. Using electronic absorption, circular dichroism (CD), magnetic CD (MCD), and (113)Cd NMR spectroscopy, the structural features of the metal-thiolate clusters in the double mutant Cd(7)-mutMT-3 were investigated and compared with those of wild-type Cd(7)-MT-3 [Faller, P., Hasler, D. W., Zerbe, O., Klauser, S., Winge, D. R., and Vasák, M. (1999) Biochemistry 38, 10158] and the well characterized Cd(7)-MT-2a from rabbit liver. Similarly to (113)Cd(7)-MT-3 the (113)Cd NMR spectrum of (113)Cd(7)-mutMT-3 at 298 K revealed four major and three minor resonances (approximately 20% of the major ones) between 590 and 680 ppm, originating from a Cd(4)S(11) cluster in the alpha-domain and a Cd(3)S(9) cluster in the beta-domain, respectively. Due to the presence of dynamic processes in the structure of MT-3 and mutMT-3, all resonances showed the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz). However, whereas in (113)Cd(7)-mutMT-3 the temperature rise to 323 K resulted in a major recovery of the originally NMR nondetectable population of the Cd(3)S(9) cluster resonances, no such temperature effect was observed in (113)Cd(7)-MT-3. To account for the observed NMR features, a dynamic structural model for the beta-domain is proposed, which involves a folded and a partially unfolded state. It is suggested that in the partially unfolded state a slow cis/trans isomerization of Cys-Pro(7) or Cys-Pro(9) amide bonds in (113)Cd(7)-MT-3 takes place and that this process represents a rate-limiting step in a correct domain refolding. In addition, closely similar apparent stability constants of human MT-3, mutMT-3, and rabbit MT-2a with Cd(II) and Zn(II) ions were found. These results suggest that specific structural features dictated by the repetitive (Cys-Pro)(2) sequence in the beta-domain of MT-3 and not its altered metal binding affinity compared to MT-1/MT-2 isoforms are responsible for the biological activity of this protein.

Optical and TDPAC spectroscopy of Hg(II)-rubredoxin: model for a mononuclear tetrahedral [Hg(CysS)4]2- center. ISOLDE Collaboration.

Rubredoxins possess a well-defined mononuclear tetrahedral tetrathiolate metal binding site, a feature exploited by several investigations to study the spectroscopic characteristics and the coordination chemistry of different metal ions at this binding site. In the present work, Hg(II)-substituted rubredoxin (Rd) from Desulfovibrio gigas has been studied by electronic absorption, circular dichroism (CD), magnetic circular dichroism (MCD), and time differential perturbed angular correlation of gamma-rays (TDPAC) spectroscopies. The TDPAC spectrum of 199mHg-Rd at pH 8 exhibits a prevailing nuclear quadrupole interaction (NQI) with a precession frequency of omega1=0.09 Grad/s and an asymmetry parameter eta=0, features characteristic of a slightly distorted tetrahedral tetrathiolate metal coordination, i.e, a HgCysS4 center. In addition, three minor populated NQIs have also been detected. They may represent a trigonal HgS3 (omega1=1.13 Grad/s, eta=0.21), a digonal HgS2 (omega1= 1.34 Grad/s, eta =0.20), and a digonal Hg(II) coordination (omega = 1.58 Grad/s, eta =0.18) with unidentified ligands. Since similar studies at pH 2.5 revealed a time-dependent increase of the HgCysS4 population, the low populated sites may represent intermediate Hg(II) complexes formed prior to the generation of the thermodynamically stable structure. The metal-induced absorption envelope of Hg-Rd reveals three distinct transitions with Gaussian-resolved maxima located at 230, 257, and 284 nm, which are paralleled by dichroic features in the corresponding difference CD spectrum of Hg(II)-Rd versus apo-Rd. Based on the optical electronegativity theory of J*rgensen, the lowest energy transition has been attributed to a CysS-Hg(II) charge-transfer excitation. The Td type of metal coordination in Hg-Rd is supported by the presence of an unresolved A-term with a negative lobe at 295 nm in the difference MCD spectrum. These results point to the usefulness of optical and TDPAC spectroscopies for studying Hg(II) sites in other proteins.

Metal-thiolate clusters in neuronal growth inhibitory factor (GIF).

Human neuronal growth inhibitory factor (GIF) is a metallothionein-like protein specific to the central nervous system, which has been linked to Alzheimer's disease. In this article a short overview of the biological and structural properties of native Cu4,Zn3-GIF are described. Moreover, metal-thiolate clusters formed in the synthetic beta-domain (residues 1-32) and the alpha-domain (residues 32-68) both with native CuI and ZnII, and as a spectroscopic probe also with Cd(II) are discussed. The cluster formation was followed by electronic absorption, circular dichroism (CD), magnetic circular dichroism (MCD) and 113Cd NMR spectroscopy and, in the special case of Cu(I) complexes, by luminescence spectroscopy at 77 K. These structural features are compared with those of recombinant Zn7- and 113Cd7-GIF. The structural studies suggest the existence of distinct MeII4S11 and MeII3S9 clusters located in the mutually interacting alpha- and beta-domains, respectively, of Cd7-GIF. In addition, evidence for a highly dynamic and flexible structure of this protein is presented.

Metallothioneins: new functional and structural insights.

In the past few years, tissue-specific mammalian metallothioneins (i. e. metallothionein-3 and metallothionein-4) have been discovered that possess distinct functional properties. Other recent developments include an insight into the role of the widely expressed mammalian metallothionein-1 and metallothionein-2 isoforms in zinc homeostasis and apoptosis. The three-dimensional structure of the evolutionary distant sea urchin Cd(7)-metallothionein A, which contains two metal-thiolate clusters, supports previous conclusions regarding the functional importance of this structural motif. Despite correlated efforts involving techniques of structural biochemistry and molecular biology, the primary function of metallothioneins remains enigmatic.

Zinc transfer potentials of the alpha - and beta-clusters of metallothionein are affected by domain interactions in the whole molecule.

The alpha- and beta-polypeptides of human metallothionein (isoform 2), obtained by chemical synthesis, were converted into their respective zinc/thiolate clusters, and each domain was investigated separately. Proton titration data for the N-terminal beta-domain fit a simple model with three ionizations of the same apparent pK(a) value of 4.9 and a collective binding constant for zinc of 5 x 10(-12) M at pH 7.0. The zinc cluster in the C-terminal alpha-domain is more stable than that in the beta-domain. Its pH titration is also more complex, indicating at least two classes of zinc sites with different affinities. The whole molecule is stabilized with regard to the individual domains. Chemical modification implicates lysine side chains in both the stabilization of the beta-domain cluster and the mutual stabilization of the domains in the whole molecule. The two zinc clusters also differ in the reactivity of their cysteine sulfurs and their potential to donate zinc to an acceptor molecule dependent on its type and characteristics. The isolated beta-domain cluster reacts faster with Ellman's reagent and is a better zinc donor toward zinc-depleted sorbitol dehydrogenase than is the isolated alpha-domain cluster, whereas the reverse is observed when a chelating agent is the zinc acceptor. Thus, although each cluster assembles independently of the other, the cumulative properties of the individual domains do not suffice to describe metallothionein either structurally or functionally. The two-domain structure of the whole molecule is important for its interaction with ligands and for control of its reactivity and overall conformation.

Evidence for a dynamic structure of human neuronal growth inhibitory factor and for major rearrangements of its metal-thiolate clusters.

Human neuronal growth inhibitory factor (GIF), a metallothionein-like protein classified as metallothionein-3, impairs the survival and the neurite formation of cultured neurons. Despite its approximately 70% amino acid sequence identity with those of mammalian metallothioneins (MT-1 and MT-2 isoforms), only GIF exhibits growth inhibitory activity. In this study, structural features of the metal-thiolate clusters in recombinant Zn(7)- and Cd(7)-GIF, and in part also in synthetic GIF (68 amino acids), were investigated by using circular dichroism (CD) and (113)Cd NMR. The CD and (113)Cd NMR studies of recombinant Me(7)-GIF confirmed the existence of distinct Me(4)S(11)- and Me(3)S(9)-clusters located in the alpha- and beta-domains of the protein, respectively. Moreover, a mutual structural stabilization of both domains was demonstrated. The (113)Cd NMR studies of recombinant (113)Cd(7)-GIF were conducted at different magnetic fields (66.66 and 133.33 MHz) and temperatures (298 and 323 K). At 298 K the spectra revealed seven (113)Cd signals at 676, 664, 651, 644, 624, 622, and 595 ppm. A striking feature of all resonances is the absence of resolved homonuclear [(113)Cd-(113)Cd] couplings and large apparent line widths (between 140 and 350 Hz), which account for the absence of cross-peaks in [(113)Cd, (113)Cd] COSY. On the basis of a close correspondence in chemical shift positions of the (113)Cd signals at 676, 624, 622, and 595 ppm with those obtained in our previous studies of (113)Cd(4)-GIF(32-68) [Hasler, D. W., Faller, P., and Vasák, M. (1998) Biochemistry 37, 14966], these resonances can be assigned to a Cd(4)S(11)-cluster in the alpha-domain of (113)Cd(7)-GIF. Consequently, the remaining three (113)Cd signals at 664, 651, and 644 ppm originate from a Me(3)S(9) cluster in the beta-domain. However, the latter resonances show a markedly reduced and temperature-independent intensity (approximately 20%) when compared with those of the alpha-domain, indicating that the majority of the signal intensity remained undetected. To account for the observed NMR features of (113)Cd(7)-GIF, we suggest that dynamic processes acting on two different NMR time scales are present: (i) fast exchange processes among conformational cluster substates giving rise to broad, weight-averaged resonances and (ii) additional very slow exchange processes within the beta-domain associated with the formation of configurational cluster substates. The implications of the structure fluctuation for the biological activity of GIF are discussed.

Dimethylargininase, a nitric oxide regulatory protein, in Alzheimer disease.

In this study, we show that dimethylargininase, a zinc protein involved in the regulation of nitric oxide synthase, is specifically elevated in neurons displaying cytoskeletal abnormalities and oxidative stress in Alzheimer disease (AD) while none of this enzyme was found in neurons in age-matched control cases. Seen in the context of earlier studies showing widespread nitric oxide related damage in AD and the role of dimethylargininase to activate nitric oxide synthetase, through catalytic removal of its endogenous inhibitors, these findings indicate major alterations in nitric oxide regulation in AD. Further, that low levels of zinc specifically inhibit dimethylargininase may provide a link between the numerous studies showing specific abnormalities in zinc and oxidative stress. Finally, our results provide additional evidence that oxidative stress- and nitric oxide-mediated events play important roles in the pathogenesis of AD.

Growth inhibitory factor and zinc affect neural cell cultures in a tissue specific manner.

Deficiency of neuronal growth inhibitory factor (GIF) and abnormalities in zinc homeostasis have been suggested to play a role in the neuropathogenesis of Alzheimer's disease. We report here that embryonic chick cerebral cell cultures zinc and copper containing GIF in the presence of marmoset hippocampal extract reduces significantly and concentration dependently mitochondrial succinate dehydrogenase activity (MTT) and cell mass. In contrast, no indications could be found that GIF affected neural retina cell cultures. Our results suggest that the observed effects of GIF are not elicited by zinc.

Metal-thiolate clusters in the C-terminal domain of human neuronal growth inhibitory factor (GIF).

Neuronal growth inhibitory factor (GIF), a metallothionein-like protein (metallothionein-3), impairs the survival and neurite formation of cultured neurons. Native GIF contains 4 Cu(I) and three Zn(II) ions organized in homometallic metal-thiolate clusters. However, the cluster localization is not known. In this study, the metal-thiolate clusters formed with monovalent and divalent metal ions in the C-terminal domain of human GIF [GIF(32-68)] containing 11 cysteines were investigated. The cluster formation was followed by using electronic absorption, circular dichroism (CD), and magnetic circular dichroism (MCD) spectroscopy, and in the case of Cu(I) complexes also by luminescence spectroscopy at 77 K. Spectroscopic studies on the Cu(I)-GIF(32-68) complexes showed the successive formation of two air-sensitive Cu4S8-9- and Cu6S11-clusters. With Zn(II) and Cd(II) ions, a well-defined M4S11-cluster is formed in which each metal ion is tetrahedrally coordinated by cysteine thiolates. In the 113Cd NMR spectra of 113Cd4-GIF(32-68), recorded at 293 and 323 K, all four 113Cd resonances at 672.8, 620.9, 629.6, and 564.2 ppm were observed only at 323 K. Their detection at elevated temperature indicates a conformational flexibility of this domain. Evidence for the existence of a Cd6-GIF(32-68) complex, contaning two more weakly bound Cd(II) ions, was also obtained. The formation of this complex requires the transformation of some originally terminal thiolates of the Cd4S11-cluster to bridging thiolates, suggesting a more accessible cluster structure. Such properties of Cd4-GIF(32-68) have not been observed with the Cd4S11-cluster in the isolated alpha-domain (amino acids 31-61) of metallothioneins. The significance of Cu- and Zn-clusters for the structure of native GIF is discussed.

Structural characterization of Cu(I) and Zn(II) sites in neuronal-growth-inhibitory factor by extended X-ray absorption fine structure (EXAFS).

Neuronal-growth-inhibitory factor (GIF) is a metalloprotein specific to the central nervous system which has been linked to Alzheimer's disease. The high metal content, approximately seven metal atoms/protein molecule, and 70% sequence identity to mammalian metallothioneins (MT), including a preserved array of 20 cysteinyl residues, place GIF in the family of MT. In contrast to MT, native GIF isolated from human or bovine brain contains an unusual metal composition, viz. four Cu(I) and three Zn(II) per polypeptide chain. Cu and/or Zn K-edge X-ray absorption spectra have been recorded for native Cu, Zn-GIF, Zn-substituted GIF, and these metals bound to the 32-residue N-terminal domain, Cu4-, Cu6- or Zn3-GIF-(1-32) at 77 K. The results are consistent with the metals being bound to the protein by cysteinyl residues in every case. The Cu-S distance is approximately 2.25 A and the EXAFS is considered to be consistent with primarily trigonal coordination of the Cu(I); Cu...Cu backscattering is observed at approximately 2.67 A, indicative of the formation of Cu(x)(Scys)y clusters. Thus, the Cu(I) environment is similar to that observed in MT. This is also the case for Zn(II), with 4 S at approximately 2.34 A. However, in contrast to Zn-MT for Zn-substituted GIF and Zn3-GIF-(1-32), Zn...Zn backscattering is observed at approximately 3.28 A. The significance of these results are discussed with respect to the specific biological activity of GIF.

Modulation of DNA binding of a tramtrack zinc finger peptide by the metallothionein-thionein conjugate pair.

The ability of metallothionein (MT) to modulate DNA binding by a two-finger peptide of Tramtrack (TTK), a CCHH zinc transcription factor, was investigated using metal-bound and metal-deficient forms of rabbit MT-2 and the TTK peptide. Thionein inhibited DNA binding by zinc-bound TTK, and Zn-MT restored DNA-binding by zinc-deficient apo-TTK. "Free" zinc at low concentrations was as effective as Zn-MT in restoring DNA binding by apopeptide but was inhibitory at concentrations equal to zinc bound to 2 mol eq and higher of Zn-MT. Substitution of cadmium for zinc reduced the affinity of the peptide for its DNA binding site. This effect was reversed by incubation with Zn-MT. The circular dichroic spectra of the TTK peptide indicated that zinc removal resulted in loss of alpha-helical structures, which are sites of DNA contact points. Reconstitution with cadmium resulted in stoichiometric substitution of 2 mol of Cd/mol of peptide but not recovery of alpha-helical structures. Incubation of Cd-TTK with Zn-MT restored the secondary structure expected for zinc-bound TTK. The ability of Zn-MT and thionein to restore or inhibit DNA-binding by TTK was associated with effects on the metallation status of the peptide and related alterations in its secondary structure.

Characterization of dimethylargininase from bovine brain: evidence for a zinc binding site.

Dimethylargininase (EC 3.5.3.18) is involved in the regulation of the levels of the natural occurring free arginine derivatives L-Nomega,Nomega-dimethylarginine and L-Nomega-methylarginine, which are reversible inhibitors of nitric oxide synthase. A dimethylargininase has been isolated from bovine brain tissue and was characterized by using immunological, kinetic, and spectroscopic techniques. Western blot analysis using polyclonal antibodies revealed that the enzyme is widely distributed in bovine with the highest relative concentrations found in brain and kidney tissue. A similar tissue distribution has also been reported for the other so far isolated dimethylargininase from rat kidney [Ogawa, T., Kimoto, M., and Sasaoka, K. (1989) J. Biol. Chem. 264, 10205-10209]. The bovine enzyme is a monomeric, globular protein (molecular mass approximately 31.2 kDa) containing one tightly bound Zn2+ ion, which can be removed by dialysis against 1,10-phenanthroline. The determination of kinetic constants for both the native (holo-protein) and the zinc-depleted (apo-protein) enzyme at 37 degrees ¿C established that the dimethylargininase is not a zinc hydrolase. The specific activity was 0.66 unit/mg for the holo-protein and 0.19 unit/mg for the apo-protein. The secondary structure determination of the native enzyme by circular dichroism revealed 41% alpha-helix and 32% beta-sheet and beta-turn structure. In the apo-enzyme, a small, but significant decrease in the alpha-helical content (5%) was observed, consistent with a marked decrease in enzymatic activity to 30%. Upon preincubation of both enzyme forms at 50 degrees C, only the holo-enzyme showed a residual enzymatic activity. In thermostability studies, a 7 degrees C lower apparent Tm value was observed for the apo-enzyme compared to the 66 degrees C for the holo-enzyme, suggesting that the zinc ion has a structure-stabilizing role. Besides the tightly bound zinc, additional Zn2+ ions inhibit the enzyme competitively with a Ki value of 2.0 microM. A possible interrelationship between dimethylargininase and nitric oxide synthase is discussed.

Application of 113Cd NMR to metallothioneins.

Metallothioneins constitute a class of ubiquitously occurring low molecular mass proteins (6-7 kDa) possessing two cysteine thiolate-based metal clusters usually formed by the preferential binding of d10 metal ions such as ZnII and CdII. The three-dimensional solution structure of mammalian proteins has been determined by two-dimensional NMR spectroscopy of 113Cd7-metallothionein. The structure shows two protein domains encompassing the M3(CysS)9- and M4(CysS)11-cluster with each metal ion being tetrahedrally coordinated by thiolate ligands. The application of 113Cd NMR proved to be indispensable in the structural studies of metallothioneins. Thus, both homonuclear 113Cd decoupling studies and 113Cd-113Cd COSY of 113Cd7-metallothionein established the existence of two metal-thiolate clusters in this protein. The identification of sequence specific cysteine-cadmium coordinative bonds came from heteronuclear 113Cd-1H COSY experiments. Independently, the 113Cd NMR characterization of the intermediate metal-protein complexes, leading to the cluster structure in 113Cd7-metallothionein, revealed a stepwise cluster formation process with the Cd4(CysS)11-cluster being formed first. The recent demonstration of a Karplus-like dependence between the heteronuclear3 J(113Cd, 1H) coupling constants for the cysteine C beta protons and the H beta-C beta-S gamma -Cd dihedral angles should allow to derive the geometry of the CD-(S-Cys) centers in various metallothioneins and related metalloproteins. A possible application of 113Cd NMR to the study of metallothioneins in the environment is discussed.

Distinct metal-thiolate clusters in the N-terminal domain of neuronal growth inhibitory factor.

Neuronal growth inhibitory factor (GIF), a brain-specific metallothionein-like protein (metallothionein-3), impairs the survival and neurite formation of cultured neurons. The metal distribution in isolated Cu4,Zn3-GIF is not known. In the present studies, the metal-thiolate clusters formed with monovalent and divalent metal ions in the N-terminal domain of human GIF [GIF(1-32)] were investigated. The cluster formation was followed by using electronic absorption, circular dichroism (CD), and magnetic circular dichroism (MCD), and in the case of Cu(I) complexes also by luminescence spectroscopy at 77 K. With Cu(I) ions, two well-defined clusters are formed involving the nine cysteine ligands of GIF(1-32), i.e., Cu4S9- and Cu6S9-clusters. In contrast to the Cu6S9-cluster, the Cu4S9-cluster shows a remarkable stability to air oxidation. As similar properties and spectral features have also been observed with isolated Cu4-5,Zn2-3-GIF, the presence of a Cu4-cluster in this GIF form is suggested. The studies with Zn(II), Cd(II), and Co(II) ions indicated the presence of a Me3S9-cluster in GIF(1-32). However, spectral features of these metal derivatives substantially differ from those reported for the corresponding Me3S9-cluster in the beta-domain of metallothioneins, suggesting structural differences. A large conformational flexibility of the Zn3- and Cd3-GIF(1-32) structures, characterized by short T2 proton relaxations, precluded their investigation by NMR methods. The significance of Cu- and Zn-clusters for the structure of biologically active GIF(1-32) is discussed.