Metallothionein-3 is a component of a multiprotein complex in the mouse brain.

Metallothionein (MT)-3, originally called growth inhibitory factor (GIF), was initially identified through its ability to inhibit the growth of neuronal cells in the presence of brain extract. MT-3 is the brain specific isoform of the MT family whose specific biological activity associates it with neurological disorders. Indeed, studies report that MT-3 is decreased by ~30% in brains of patients with Alzheimer disease (AD). Furthermore, many lines of evidence suggest that MT-3 engages in specific protein interactions. To address this, we conducted immunoaffinity chromatography experiments using an immobilized anti-mouse MT-3 antibody. We identified five associated proteins from the pool of sixteen recovered using mass spectrometry and tandem mass spectrometry after in-gel trypsin digestion of bands from the affinity chromatography. The proteins identified were: heat shock protein 84 (HSP84), heat shock protein 70 (HSP70), dihydropyrimidinase-like protein-2 (DRP-2), creatine kinase (CK) and beta-actin. Coimmunoprecipitation experiments, also conducted on whole mouse brain extract using the anti-mouse MT-3 antibody along with commercially available antibodies against HSP84 and CK, confirmed that these three proteins were in a single protein complex. Immunohistochemical experiments were then conducted on the perfused mouse brain that confirmed the in situ colocalization of CK and MT-3 in the hippocampus region. These data provide new insights into the involvement of MT-3 in a multiprotein complex, which will be used to understand the biological activity of MT-3 and its role in neurological disease.

Oxidative dimerization in metallothionein is a result of intermolecular disulphide bonds between cysteines in the alpha-domain.

Upon storage under aerobic conditions metallothioneins (MTs) form a new species, which is characterized by a molecular mass approximately twice the size of monomeric MT and shifted (113/111)Cd- and (1)H-NMR resonances. The investigation of this oxidative dimerization process by NMR spectroscopy allowed us to structurally characterize this MT species that has been described to occur in vivo and might be synthesized under conditions of oxidative stress. The oxidative dimer was characterized by the formation of an intermolecular cysteine disulphide bond involving the alpha-domain, and a detailed analysis of chemical shift changes and intermolecular nuclear Overhauser effects points towards a disulphide bond involving Cys(36). In contrast to the metal-bridged (non-oxidative) dimerization, the metal-cysteine cluster structures in both MT domains remain intact and no conformational exchange or metal-metal exchange was observed. Also in contrast to the many recently reported oxidative processes which involve the beta-domain cysteine groups and result in the increased dynamics of the bound metal ions in this N-terminal domain, we found no evidence for any increased dynamics in the alpha-domain metals following this oxidation. Therefore these findings provide additional corroboration that metal binding in the C-terminal alpha-domain is rather tight, even under conditions of a changing cellular oxidation potential, compared with the more labile/dynamic nature of the metals in the N-terminal beta-domain cluster under similar conditions.

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.

Re-evaluation of the binding of ATP to metallothionein.

In a recent paper Jiang et al. (Jiang, L. J., Maret, W. & Vallee, B. L. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 9146-9149) reported that metallothionein interacts with adenosine triphosphate (ATP) to form a 1:1 complex with a dissociation constant of K(d) = 176 +/- 33 microM at pH 7.4. In an effort to characterize further this interaction using nuclear magnetic resonance spectroscopy, titration calorimetry, gel-filtration chromatography, affinity chromatography, and ultrafiltration, we were unable to find any evidence for the binding of ATP to metallothionein.

The roles of Glu-327 and His-446 in the bisphosphatase reaction of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase probed by NMR spectroscopic and mutational analyses of the enzyme in the transient phosphohistidine intermediate complex.

The bisphosphatase domain derived from the rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase was studied by 1H-13C HMQC NMR spectroscopy of the histidine C2' and H2' nuclei. The bacterially expressed protein was specifically labeled with 13C at the ring C2' position of the histidines. Each of the seven histidine residues gave rise to a single cross-peak in the HMQC spectra, and these were assigned by use of a series of histidine-to-alanine point mutants. His-304, His-344, and His-469 exhibit 13C and 1H resonances that titrated with pH, while the remaining histidine-associated resonances did not. The 13C and 1H chemical shifts indicate that at neutral pH, His-304 and His-446 are deprotonated, while His-469 is protonated. The pKa of His-344 was determined to be 7.04. The 13C chemical shifts suggest that the deprotonated His-258 exists as the N1' tautomer, while His-392 and His-419 are protonated in the resting, wild-type enzyme. Mutation of the remaining member of the catalytic triad, Glu-327, to alanine in the resting enzyme caused an upfield shift of 1.58 and 1.30 ppm in the 1H and 13C dimensions, respectively, and significant narrowing of the His-258 cross-peak. Mutation of His-446 to alanine produced perturbations of the His-258 cross-peak that were similar to those detected in the E327A mutant. The His-392 resonances were also shifted by the E327A and H446A mutations. These observations strongly suggest that residues His-258, Glu-327, His-392, and His-446 exist within a network of interacting residues that encompasses the catalytic site of the bisphosphatase and includes specific contacts with the C-terminal regulatory region of the enzyme. The specifically 13C-labeled bisphosphatase was monitored during turnover by HMQC spectra acquired from the transient N3' phosphohistidine intermediate complex in the wild-type enzyme, the E327A mutant, and the H446A mutant. These complexes were formed during reaction with the physiological substrate fructose-2, 6-bisphosphate. Upon formation of the phosphohistidine at His-258, the 13C and 1H resonances of this residue were shifted downfield by 1.7 and 0.31 ppm, respectively, in the wild-type enzyme. The upfield shifts of the His-258 resonances in the E327A and H446A mutant resting enzymes were reversed when the phosphohistidine was formed, generating spectra very similar to that of the wild-type enzyme in the intermediate complex. In contrast, the binding of fructose-6-phosphate, the reaction product, to the resting enzyme did not promote significant changes in the histidine-associated resonances in either the wild-type or the mutant enzymes. The interpretation of these data within the context of the X-ray crystal structures of the enzyme is used to define the role of Glu-327 in the catalytic mechanism of the bisphosphatase and to identify His-446 as a putative link in the chain of molecular events that results in activation of the bisphosphatase site by cAMP-dependent phosphorylation of the hepatic bifunctional enzyme.

Three-dimensional solution structure of mouse [Cd7]-metallothionein-1 by homonuclear and heteronuclear NMR spectroscopy.

Sequential 1H-NMR assignments of mouse [Cd7]-metallothionein-1 (MT1) have been carried out by standard homonuclear NMR methods and the use of an accordion-heteronuclear multiple quantum correlation (HMQC) experiment for establishing the metal, 113Cd2+, to cysteine connectivities. The three-dimensional structure was then calculated using the distance constraints from two-dimensional nuclear Overhauser effect (NOE) spectroscopy spectra and the Cys-Cd connectivities as input for a distance geometry-dynamical simulated annealing protocol in X-PLOR 3.851. Similar to the mammalian MT2 isoforms, the homologous primary structure of MT1 suggested two separate domains, each containing one metal cluster. Because there were no interdomain constraints, the structure calculation for the N-terminal beta- and the C-terminal alpha-domain were carried out separately. The structures are based on 409 NMR constraints, consisting of 381 NOEs and 28 cysteine-metal connectivities. The only elements of regular secondary structure found were two short stretches of 3(10) helices along with some half-turns in the alpha-domain. Structural comparison with rat liver MT2 showed high similarity, with the beta-domain structure in mouse MT1 showing evidence of increased flexibility compared to the same domain in MT2. The latter was reflected by the presence of fewer interresidue NOEs, no slowly exchanging backbone amide protons, and enhanced cadmium-cadmium exchange rates found in the beta-domain of MT1.

Sensitivity-enhanced detection of fast exchanging protons by an exchange-edited gradient HEHAHA-HSQC experiment.

An experiment is presented which allows for the sensitivity-enhanced measurement of proton exchange rates in a HSQC type experiment. Instead of using INEPT type transfer of magnetization from protons to heteronuclei and vice versa, we have used heteronuclear Hartmann-Hahn transfer, which is known to have higher sensitivity in the presence of chemical exchange. Direct NOE's between NH protons and alpha-protons are suppressed by an exchange-editing step unless the alpha-resonances are degenerate with the water resonance. A comparison between the exchange-edited HEHAHA-HSQC and a standard exchange-edited HSQC experiment performed on the uniformly 15N-labeled staphylococcal nuclease H124L shows an enhancement of approximately 100% with the former experiment. A set of one-dimensional exchange-edited spectra of urea was used for evaluating the ability to extract exchange rates using the presented experiment.

NMR spectroscopic studies of I = 1/2 metal ions in biological systems.

This article reviews the use of nuclear magnetic resonance methods of spin 1/2 metal nuclei to probe the metal binding site(s) in a variety of metalloproteins. The majority of the studies have involved native Zn(II) and Ca(II) metalloproteins where there has been isostructural substitution of these metal ions with the I = 1/2 (111/113)Cd(II) ion. Also included are recent studies that have utilized the 109Ag(I) ion to probe Cu(I) sites in yeast metallothionein and 199Hg(II) as a probe of the metal binding sites in mercury resistance proteins. Pertinent aspects for the optimal execution of these experiments along with the procedures for the metal substitution reactions are discussed together with the presentation of a 113Cd chemical shift correlation map with ligand type and coordination number. Specific examples of protein systems studied using the (111/113)Cd and 109Ag nuclei include the metallothionein superfamily of Zn(II)- and Cu(I)-binding proteins from mammalian, invertebrate, and yeast systems. In addition to the structural features revealed by these metal ion nuclear magnetic resonance studies, important new information is frequently provided about the dynamics at the active-site metal ion. In an effort for completeness, other less frequently used spin 1/2 metal nuclei are mentioned.

HIV protease substrate conformation: modulation by cyclophilin A.

Cyclophilin A (CyPA), a cytosolic peptidyl-prolyl trans-cis isomerase can accelerate the trans-cis isomerization of Xxx-Pro peptide bonds. One- and two-dimensional 1H-NMR spectroscopy were used to determine that the heptapeptide Ser-Gln-Asn-Tyr-Pro-Ile-Val, a model peptide of an HIV-1 protease cleavage site in the gag polyprotein of HIV-1, is a substrate for CyPA. Experiments revealed a slow exchange about the Tyr-Pro peptide bond with 30 +/- 5% in the cis conformation (pH 1-9). While the interconversion rate is too slow to measure by kinetic NMR methods in the absence of CyPA, these methods, saturation transfer and NOE experiments, established that CyPA enhanced the rate of trans-cis interconversion, a process inhibited by cyclosporin A (CsA). With a substrate:CyPA ratio of 40:1, an interconversion rate of 2.5 s(-1) at 25 degrees C was observed.

Impact of angiotensin-converting enzyme substrate conformation on fractional hydrolysis in lung.

We examined the hydrolysis kinetics of benzoyl-phenylalanyl-glycyl-proline (BPGP) in the isolated perfused lung and in vitro for evidence of preferential hydrolysis of the trans isomer by angiotensin-converting enzyme (ACE). Nuclear magnetic resonance spectroscopy showed that BPGP exists as cis and trans isomers in a ratio of 44:56. After a single pass through the perfused rabbit lung over a wide range of infused BPGP concentrations, 42% of the BPGP was not hydrolyzed. In single-pass bolus-injection studies, 41% of the injected BPGP was not hydrolyzed, and very little further hydrolysis occurred in a second passage of the bolus through the lungs. In rat lung recirculation and in vitro studies of BPGP hydrolysis by ACE, approximately 60% of the substrate was hydrolyzed rapidly compared with the remaining approximately 40%, and the peptidyl-prolyl cis-trans isomerase cyclophilin increased the rate of the slower phase of the reaction in both kinds of experiments. We conclude that the rapid hydrolysis phase represents primarily the hydrolysis rate of the trans isomer and the slower phase the cis-trans isomerization rate, suggesting that the trans isomer of BPGP is preferentially hydrolyzed by ACE in the perfused lung and in vitro.

3D solution structure of copper and silver-substituted yeast metallothioneins.

3D solution structural calculations for yeast silver(I)-substituted metallothionein (MT) and native copper(I) MT were completed using experimentally determined NOE and dihedral angle constraints, in conjunction with experimentally derived metal-to-Cys connectivities for AgMT which were assumed identical for CuMT. For the first 40 residues in both structures, the polypeptide backbone wraps around the metal cluster in two large parallel loops separated by a deep cleft containing the metal cluster. Minor differences between the two structures include differences in hydrogen bonds and the orientation of the N-terminus with the overall protein volume conserved to within 6.5%.

Visual impairment in severe and profound sensorineural deafness.

The frequency of reversible and irreversible visual impairment was determined in children with severe and profound sensorineural deafness, as subnormal vision can adversely affect their educational and social development. Eighty three of 87 such children attending an audiology service were examined to assess the incidence and severity of visual impairment. Each child underwent a detailed ophthalmic assessment. The criteria for visual impairment were visual acuity < 6/9 Snellen or equivalent and/or abnormal binocular vision. Forty five had a normal ophthalmic examination (54.2%). Twenty nine had visual impairment (34.9%) and nine had ophthalmological abnormalities that did not interfere with vision (10.9%). A higher proportion of children with risk factors for visual pathology demonstrated visual impairment than those in whom there were no risk factors. None the less, 44% of visual impairment was among patients without risk factors. The results underline the need to examine all children with severe and profound sensorineural deafness soon after diagnosis and indicate that children with multiple handicaps have a greater likelihood of visual impairment (11 of 14 cases).

Identification of transient intermediates in the bisphosphatase reaction of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase by 31P-NMR spectroscopy.

31P-NMR spectroscopy was used to identify reaction intermediates during catalytic turn-over of the fructose-2,6-bisphosphatase domain (Fru-2,6-P2ase) of the bifunctional enzyme, 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase. When fructose-2,6-bisphosphate (Fru-2,6-P2) was added to the enzyme, the 31P-NMR spectrum showed three resonances in addition to those of free substrate: the phosphohistidine (His-P) intermediate, the C-6 phosphoryl group of fructose-6-phosphate bound to the phosphoenzyme, and phosphate generated by the hydrolysis of substrate. Direct analysis of the alkali-denatured phospho-enzyme intermediate by 1H-31P heteronuclear multiple quantum-filtered coherence spectroscopy confirmed the formation of 3-N-phosphohistidine. Binding of fructose 6-phosphate to the bisphosphatase was detected by a down-field shift and broadening of the C-6 phosphoryl resonance. The down-field shift was greater in the presence of the phosphoenzyme intermediate. Inhibition of Fru-2,6-P2 hydrolysis by fructose 6-phosphate and Fru-2,6-P2 was shown to involve binding of the sugar phosphates to the phosphoenzyme. This study provides new experimental evidence in support of the reaction mechanism of Fru-2,6-P2ase and suggests that the steady-state His-P intermediate exists primarily in the E-P.fructose 6-phosphate complex. These results lay a solid foundation for the use of 31P-NMR magnetization transfer studies to provide an in-depth analysis of the bisphosphatase reaction mechanism.

Expression of human cyclophilin-40 and the effect of the His141-->Trp mutation on catalysis and cyclosporin A binding.

The cDNA encoding a human cytosolic 40-kDa cyclophilin (CyP-40) has been inserted into a modified pGEX-3X expression vector and expressed in Escherichia coli to yield recombinant CyP-40 at levels up to 4 mg/l medium. The protein was purified to homogeneity using a cyclosporin affinity matrix and gel filtration. The recombinant CyP-40 showed peptidyl-prolyl cis-trans isomerase activity (kcat/Km = 1.12 x 10(6) M-1.s-1) comparable to that of bovine brain CyP-40. The weak affinity of CyP-40 for cyclosporin A was postulated to arise from a histidine residue that replaces a tryptophan residue critical for cyclosporin A binding and highly conserved in other cyclophilins that have high affinity for cyclosporin A. Site-directed mutagenesis to replace His141 by tryptophan yielded a protein with an approximately 20-fold greater affinity for cyclosporin A (Kdapp 11.5 +/- 2 nM as determined by tryptophan fluorescence measurements). The intrinsic isomerase activity of this mutant protein with succinyl-Ala-Ala-Pro-Phe 4-nitroanilide as substrate was about nine times greater than the value obtained for the nonmutated recombinant CyP-40 and had an activity similar to that of CyP-18. NMR difference spectroscopy and molecular modelling revealed a cyclosporin-A-binding domain that is similar to that of CyP-18.

Characterization of the calcium-binding sites of calcineurin B.

Calcineurin (CaN) is a calcium- and calmodulin-dependent serine/threonine phosphatase whose inhibition by the immunosuppressant-immunophilin complexes (cyclosporin-cyclophilin and FK506-FKBP) is considered key to the mechanism of immunosuppression. CaN is a heterodimer, consisting of a 59 kDa catalytic subunit (A) and a 19 kDa calcium-binding regulatory subunit (B). The latter is postulated to harbor four calcium binding domains of the EF hand type. The titration of the CaN B apoprotein with the isomorphic Cd2+ was followed by 113Cd NMR and these data support one high-affinity metal binding site and three lower-affinity ones. Flow dialysis data with Ca2+ indicate one high affinity calcium binding site with Kd approximately 2.4 x 10(-8) M and three other sites with Kd approximately 1.5 x 10(-5) M. The chemical shifts of all four 113Cd resonances (-75, -93, -106 and -119 ppm) are in the same range as found in other 113Cd substituted calcium-binding proteins, and are indicative of all-oxygen coordination of pentagonal bipyramidal geometry.

Three-dimensional solution structure of Callinectes sapidus metallothionein-1 determined by homonuclear and heteronuclear magnetic resonance spectroscopy.

Metallothionein is a cysteine-rich metal-binding protein whose biosynthesis is closely regulated by the level of exposure of an organism to zinc, copper, cadmium, and other metal salts. The metallothionein from Callinectes sapidus is known to bind six divalent metal ions in two separate metal-binding clusters. Heteronuclear 1H-113Cd and homonuclear 1H-1H NMR correlation experiments have been used to establish that the two clusters reside in two distinct protein domains. The three-dimensional solution structure of the metallothionein has been determined using the distance and angle constraints derived from these two-dimensional NMR data sets and a distance geometry/simulated annealing protocol. There are no interdomain short distance (< or = 4.5 A) constraints observed in this protein, enabling the calculation of structures for the N-terminal, beta domain and the C-terminal, alpha domain separately. A total of 18 structures were obtained for each domain. The structures are based on a total of 364 experimental NMR restraints consisting of 277 approximate interproton distance restraints, 12 chi 1 and 51 phi angular restraints, and 24 metal-to-cysteine connectivities obtained from 1H-113Cd correlation experiments. The only element of regular secondary structure in either of the two domains is a short segment of helix in the C-terminal alpha domain between Lys42 and Thr48. The folding of the polypeptide backbone chain in each domain, however, gives rise to several type I beta turns. There are no type II beta turns.

Solution conformation of a cyclophilin-bound proline isomerase substrate.

Cyclophilin (CyP) is the 17.8-kDa cytosolic receptor of the immunosuppressant cyclosporin A (CsA) and also a peptidyl prolyl cis-trans isomerase (PPIase). In order to gain insights into the PPIase mechanism, transferred nuclear Overhauser effect (TRNOE) measurements by two-dimensional 1H NMR were used to determine the conformation of the isomerase-bound standard model substrate suc-AAPF-pNA. Results indicate a cis-like conformation for the CyP-bound substrate with the A-P peptide bond being no more than 40 degrees out of planarity.

Copper- and silver-substituted yeast metallothioneins: sequential 1H NMR assignments reflecting conformational heterogeneity at the C terminus.

Complete 1H NMR sequential assignments have been made for copper(I)- and silver (I)-substituted metallothionein (MT) from Saccharomyces cerevisiae using standard 2D 1H NMR methods. The fingerprint region of the COSY spectrum of both metalloproteins shows a doubling of a few backbone proton resonances from residue K41 onward in the C terminus. This doubling of resonances is absent in the spectrum of the truncated mutant protein that lacks the five C-terminal residues which includes two cysteines. Concurrently, it has been established from a comparison of the heteronuclear 1H-109 Ag multiple-quantum coherence transfer (HMQC) spectrum on the silver-substituted mutant and the wild-type protein that metal ligation is similar in both molecules. Thus, the 2 C-terminal Cys are not essential for metal cluster formation in the wild-type yeast MT and only 10 of the 12 Cys present in this protein appear to be involved in ligating the 7 mol of bound metal ions. A qualitative analysis of the coupling constant, hydrogen exchange, and NOE data indicates the presence of many type I beta-turns and the lack of any other regular secondary structural elements. A comparison of chemical shifts and NOE data for native copper- and silver-substituted yeast MT indicates a high degree of conservation of structural elements in both proteins. Therefore, it seems reasonable to conclude that the metal to Cys connectivities which are obtained directly from the HMQC data on silver-substituted metallothionein are conserved in the native copper protein. Interestingly, a mixture of both 2 and 3 coordination was found for the bound Ag(I) ions in a single Ag7Cys10 cluster. This mixed coordination number and a single cluster arrangement is most probably also shared with the Cu(I) ion coordination in the native protein.

Biologically active Arg-Gly-Asp oligopeptides assume a type II beta-turn in solution.

The sequence Arg-Gly-Asp (RGD) has been found to be the consensus sequence of matrix proteins for binding cell surface receptors (integrins). Studies with synthetic peptides containing the RGD sequence show that the biological activity of these oligopeptides is removed upon a conservative substitution of Glu for Asp in the RGD sequence. Two-dimensional 1H NMR methods were used to investigate the secondary structures in aqueous solution for two such oligopeptides of differing biological activity. The sequence Tyr-Gly-Arg-Gly-Asp-Ser-Pro, which binds to selected integrins, is found to assume a type II beta-turn at both pH 4 and 7. In contrast, the sequence Tyr-Gly-Arg-Gly-Glu-Ser-Pro, which does not interfere with integrin-mediated cell attachment, is found to assume a type I or III beta-turn at both pH 4 and 7. This comparison confirms not only that oligopeptides can assume a secondary structure in aqueous solution, but also that these structures may be important to biological functions.