Electronic absorption and EPR spectroscopy of copper alcohol dehydrogenase: pink, violet and green forms of a type 1 copper center analog.

Blue and non-blue states of the copper center in copper-substituted alcohol dehydrogenase (EC 1.1.1.1) can be attained by coenzyme binding and/or ligand binding to the copper ion. Copper alcohol dehydrogenase has been studied by electronic absorption, CD and EPR spectroscopy in the presence and absence of coenzyme. On the basis of previous work on blue (Type 1) copper proteins with a CuSS*N2 chromophore the assignment of charge transfer transitions in copper alcohol dehydrogenase is discussed. The latter contains a CuS2N(OH2) unit in the ligand-free protein and a CuS2N2 unit in the ternary complex with NAD+ and pyrazole. It is proposed that the energy of the charge transfer transitions can be used as a structural marker in combination with EPR data. A comparison is made between the spectroscopic properties of the ternary complex of copper alcohol dehydrogenase and the copper centers in stellacyanin and cytochrome-c oxidase (CuA) in order to test the validity of recent structural models of the type CuS2N2, i.e., a cupric ion coordinated to two thiolate ligands. Finally, a close resemblance between the electronic absorption spectra of copper alcohol dehydrogenase and those of other variants of Type 1 copper centers such as the 'unusual' copper center of nitrous oxide reductase is noted as an indication of similar coordination environments.

Human liver aldehyde dehydrogenases: new method of purification of the major mitochondrial and cytosolic enzymes and re-evaluation of their kinetic properties.

A new purification procedure, based on dye-adsorption and affinity chromatography, has been developed for the isolation of the two major ALDH isozymes from human liver: ALDH-1 (cytosolic, pI 5.2) and ALDH-2 (mitochondrial, pI 4.9). The procedure affords milligram quantities of ALDH-1 and -2 at 850- and 275-fold purifications, respectively, from 50 g of liver in two days. Kinetic parameters for acetaldehyde oxidation were determined with these purified enzymes, because there is a wide discrepancy in the absolute magnitude of these parameters in the biochemical literature. The Michaelis constants for ALDH-1 and -2, determined from initial velocities (for ALDH-1) and single reaction progress curves (for ALDH-2), are 180 +/- 10 microM and 0.20 +/- 0.02 microM, respectively (pH 7.5 and 9.5, saturating NAD+ in both cases). This three orders of magnitude difference in Km values is much greater than that reported previously in all but one study.

An EPR study of the blue copper center in horse liver alcohol dehydrogenase.

Active-site specifically reconstituted Cu2+ horse liver alcohol dehydrogenase (alcohol:NAD+ oxidoreductase, EC 1.1.1.1) shows optical and EPR spectra similar to those of native blue copper (Type 1) proteins. EPR spectra at different temperatures and frequencies reveal a heterogeneity of the copper center: a minor 'non-blue' species with axial line shape (g parallel = 2.16, g perpendicular = 2.04; A parallel = 100 x 10(-4) cm-1), which accounts for approximately 10% of the total copper and is not accessible to ligands and a major blue species with rhombic line shape (g1 = 2.21, g2 = 2.06, g3 = 2.03, A1 = 50 x 10(-4) cm-1, A2 = 30 x 10(-4) cm-1, A3 = 76 x 10(-4) cm-1), which is accessible to ligands and participates in redox reactions. The major blue species in cupric horse liver alcohol dehydrogenase is metastable, since it is reduced in a process markedly accelerated in the presence of oxygen or hydrogen peroxide. In addition, the reduction depends on the presence of exogenous metal ligands or coenzymes. Whereas the binary complex enzyme-NAD+ is even more susceptible to bleaching than the free enzyme, the cupric center is stable towards bleaching in the binary complex enzyme-NADH. In the discussion the redox properties and coordination chemistry of Cu2+ in horse liver alcohol dehydrogenase and copper proteins are compared.

X-ray absorption edge spectroscopy of Co(II)-binding sites of copper- and zinc-containing proteins.

X-ray absorption near-edge spectroscopy (XANES) of Co(II) in three derivatives of superoxide dismutase, namely [Cu(II)-Co(II)], [Cu(I)-Co(II)] and [...-Co(II)], suggests a tetrahedral coordination of the metal for all compounds. Significant differences, detected in the spectrum of the [Cu(II)-Co(II)] derivative as compared to the other species, indicate that a conformational change and/or a different charge of the imidazole bridging the two metal sites in superoxide dismutase occur in coincidence with the change of copper valence. The XANES spectra of the cobalt derivatives of alcohol dehydrogenase, carbonic anhydrase and stellacyanin show features that can be accounted for by an increasing degree of covalency in the metal first sphere of coordination, in the following order: alcohol dehydrogenase greater than stellacyanin greater than superoxide dismutase greater than or equal to carbonic anhydrase.

Domain-specific fluorescence resonance energy transfer (FRET) sensors of metallothionein/thionein.

Each of the two domains of mammalian metallothioneins contains a zinc-thiolate cluster. Employing site-directed mutagenesis and chemical modification, fluorescent probes were introduced into human metallothionein (isoform 2) with minimal perturbations of the structures of these clusters. The resulting FRET (fluorescence resonance energy transfer) sensors are specific for each domain. The design and construction of a sensor for the alpha-domain cluster is based on a FRET pair where a C-terminally added tryptophan serves as the donor for a fluorescence acceptor attached to a free cysteine in the linker region between the two domains. Molecular modeling studies and steady-state fluorescence polarization anisotropy measurements suggest unrestricted motion of the tryptophan donor, but limited motion of the AEDANS ([[(amino)ethyl]amino]naphthalene-1-sulfonic acid) acceptor, putting constraints on the use of the alpha-domain sensor with this FRET pair as a spectroscopic ruler. The fluorescent metallothioneins allow distance measurements during binding and removal of metals in the individual domains. The overall dimensions of the apoprotein, thionein, for which no structural information is available, do not seem to be significantly different from those of the holoprotein. The single- and double-labeled fluorescent metallothioneins overcome a longstanding impediment in studies of the function of this protein, namely its lack of intrinsic probe characteristics.

Catalytic oxidation of zinc/sulfur coordination sites in proteins by selenium compounds.

Zinc/thiolate (cysteine) coordination occurs in a very large number of proteins. These coordination sites are thermodynamically quite stable. Yet the redox chemistry of thiolate ligands confers extraordinary reactivities on these sites. The significance of such ligand-centered reactions is that they affect the binding and release of zinc, thus helping to distribute zinc, and perhaps controlling zinc-dependent cellular events. One new aspect focuses on the thiolate ligands of zinc as targets for the redox action of selenium compounds. A distinctive feature of this chemistry is the capacity of selenols to catalyze the oxidation of zinc/thiolate sites. We here use a chromophoric compound, 2-nitrophenylselenocyanate, to investigate its reaction mechanism with the zinc/thiolate clusters of metallothionein, a protein that is a cellular reservoir for zinc and together with its apoprotein, thionein, is involved in zinc distribution as a zinc donor/acceptor pair. The reaction is particularly revealing as it occurs in two steps. A selenenylsulfide intermediate is formed in the fast oxidative step, followed by the generation of 2-nitrophenylselenol that initiates the second, catalytic step. The findings demonstrate the high reactivity of selenium compounds with zinc/thiolate coordination sites and the potent catalytic roles that selenoproteins and selenium redox drugs may have in affecting gene expression via modulation of the zinc content of zinc finger proteins.

Metallothionein/disulfide interactions, oxidative stress, and the mobilization of cellular zinc.

Glutathione disulfide, the major cellular disulfide, releases zinc from metallothionein (MT) [W. Maret (1994) Oxidative metal release from metallothionein via zinc-thiol/disulfide interchange, Proc. natn. Acad. Sci. U.S.A. 91, 237-241]. Here, the interaction of rabbit liver MT-II with other selected biological disulfides (coenzyme A/glutathione mixed disulfide, coenzyme A disulfide, and cystamine) was investigated by measuring concomitant release of radioactive 65-zinc from MT. These disulfides react more rapidly than glutathione disulfide, thus underscoring the reactivity of zinc sulfur bonds in the clusters of MT and the importance of the MT/disulfide interaction as a chemical mechanism for mobilizing zinc from a thermodynamically stable zinc complex. Two implications of these in vitro findings are discussed. (i) Apparently, in the case of zinc which is redox inert, Nature has availed itself of the redox activity of the cysteine ligand to mobilize the metal, and, presumably to permit redox-control of cellular zinc distribution. The mobilization of zinc from MT suggests a possible function of MT as a physiological zinc donor. (ii) A shift of the glutathione redox balance under conditions of oxidative stress will accelerate metal release from MT. Such a disturbance of metal metabolism has important consequences for the progression of diseases such as Alzheimer's and Parkinson's disease where oxidative stress occurs in affected brain tissue.

Active site-specifically reconstituted nickel(II) horse liver alcohol dehydrogenase: optical spectra of binary and ternary complexes with coenzymes, coenzyme analogues, substrates, and inhibitors.

Insertion of nickel ions into the empty catalytic site of horse liver alcohol dehydrogenase yields an active enzyme with 65% metal substitution and about 12% intrinsic activity. The electronic absorption spectrum is characterized by bands at 357 nm (2900 M-1 cm-1), 407 nm (3500 M-1 cm-1), 505 nm (300 M-1 cm-1), 570 nm (approximately equal to 130 M-1 cm-1), and 680 nm (approximately equal to 80 M-1 cm-1). The absorption and CD spectra are similar to those of nickel(II) azurin and nickel(II) aspartate transcarbamoylase and prove coordination of the nickel(II) ions to sulfur in a distorted tetrahedral coordination geometry. Changes of the spectra upon ligand binding at the metal or conformation changes of the protein induced by coenzyme, or both, indicate alterations of the metal geometry. The chromophoric substrate trans-4-(N, N-dimethylamino)-cinnamaldehyde forms a ternary complex with Ni(II) liver alcohol dehydrogenase and the coenzyme analogue 1,4,5,6-tetrahydronicotinamide-adenine-dinucleotide, stable between pH 6 and 10. The corresponding ternary complex with NADH is only stable at pH greater than 9.0. The spectral redshifts induced in the substrate are 11 nm larger than those found in the zinc enzyme. We suggest direct coordination of the substrate to the catalytic metal on which acts as a Lewis acid in both substrate coordination and catalysis.

Active site-specific reconstituted copper(II) horse liver alcohol dehydrogenase: a biological model for type 1 Cu2+ and its changes upon ligand binding and conformational transitions.

Insertion of Cu2+ ions into horse liver alcohol dehydrogenase depleted of its catalytic Zn2+ ions creates an artificial blue copper center similar to that of plastocyanin and similar copper proteins. The esr spectrum of a frozen solution and the optical spectra at 296 and 77 K are reported, together with the corresponding data for binary and ternary complexes with NAD+ and pyrazole. The binary complex of the cupric enzyme with pyrazole establishes a novel type of copper proteins having the optical characteristics of Type 1 and the esr parameters of Type 2 Cu2+. Ternary complex formation with NAD+ converts the Cu2+ ion to a Type 1 center. By an intramolecular redox reaction the cuprous enzyme is formed from the cupric enzyme. Whereas the activity of the cupric alcohol dehydrogenase is difficult to assess (0.5%-1% that of the native enzyme), the cuprous enzyme is distinctly active (8% of the native enzyme). The implications of these findings are discussed in view of the coordination of the metal in native copper proteins.

Enzyme regulation by reversible zinc inhibition: glycerol phosphate dehydrogenase as an example.

Since cellular zinc is not freely available as the inorganic ion, zinc proteins must acquire their metal from some other source. But how, when, and where they acquire it is unknown. Metallothionein can participate in the controlled delivery of zinc by binding it with high stability and by mobilizing it through a novel biochemical mechanism that critically depends on the redox activity of the zinc-sulfur bond. Thus, metallothionein activates zinc-depleted alcohol (sorbitol) dehydrogenases by glutathione-modulated zinc transfer. In addition to its catalytic, co-catalytic, and/or structural roles in a myriad of enzymes, zinc also inhibits some enzymes that are not necessarily zinc enzymes, e.g. glyceraldehyde and glycerol phosphate dehydrogenases, and aldehyde dehydrogenase. Zinc inhibits glycerol phosphate dehydrogenase with an IC(50) value of 100 nM. Zinc binding is slow at low pH, but instantaneous at high pH. Thionein, the apoprotein of metallothionein, re-activates the zinc-inhibited enzyme. Tight inhibition by zinc and activation of glycerol phosphate dehydrogenase by thionein, a biological chelating agent, provide further support that modulation of zinc binding by metallothionein and thionein is a physiological mechanism of enzyme regulation. Since glycerol phosphate dehydrogenase is a key enzyme in energy metabolism, the effect of zinc is expected to elicit significant physiological responses.

Cobalt(II)-substituted class III alcohol and sorbitol dehydrogenases from human liver.

The catalytic zinc atoms in class III (chi) alcohol dehydrogenase (ADH) and sorbitol dehydrogenase (SDH) from human liver have been specifically removed and replaced by cobalt(II) with a new ultrafiltration technique. The electronic absorption spectrum of class III cobalt ADH (epsiolon 638 = 870 M-1 cm-1) is nearly identical with those of active site substituted horse EE and human class I (beta 1 beta 1) cobalt ADH. Thus, the coordination environment of the catalytic metal is strictly conserved in these enzymes. However, significant differences are noted when the spectra of class III ADH-coenzyme complexes are compared to the corresponding spectra of the horse enzyme. The spectrum of class III ADH.NADH is split into three bands, centered at 680, 638, and 562 nm. The class III ADH.NAD+ species resembles the alkaline form of the corresponding horse enzyme complex but without exhibiting the pH dependence of the latter. These spectral changes underscore the role of the coenzymes in differentially fine tuning the catalytic metal for its particular function in each ADH. The noncatalytic zinc of class III ADH exchanges with cobalt at pH 7.0. While 9 residues out of 15 in the loop surrounding the noncatalytic zinc of class III ADH differ from those of the class I ADH, the electronic absorption spectra of cobalt in the noncatalytic metal site of class III ADH establish that the coordination environment of this site is conserved as well. The spectrum of cobalt SDH differs significantly from those of cobalt ADHs.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxidative metal release from metallothionein via zinc-thiol/disulfide interchange.

Mammalian metallothionein has been postulated to play a pivotal role in cellular zinc distribution. All seven of its metal atoms are bound with high thermodynamic stability in two clusters buried deeply in the molecule. If the protein is to function in metal delivery, there must be a biological mechanism to facilitate metal release. One means to achieve this would be a labilization of the clusters by interaction of metallothionein with an appropriate cellular ligand. To search for such a mediator, we have designed a rapid radiochromatographic method that can detect changes in the zinc content of 65Zn-labeled metallothionein in response to other biomolecules. Using this methodology, we have established that rabbit liver metallothionein 2 interacts with glutathione disulfide with concomitant release of zinc. Under conditions of pseudo-first-order kinetics, the monophasic reaction depends linearly on the concentration of glutathione disulfide in the range from 5 to 30 mM with a second-order rate constant k = 4.9 x 10(-3)s-1.M-1 (pH 8.6; 25 degrees C). Apparently, zinc release does not involve direct access of glutathione disulfide to the inner coordination sphere of the metals. Rather it appears that the solvent-accessible zinc-bound thiolates in two clefts of each domain of metallothionein [Robbins, A. H., McRee, D. E., Williamson, M., Collett, S. A., Xuong, N. H., Furey, W. F., Wang, B. C. & Stout, C. D. (1991) J. Mol. Biol. 221, 1269-1293] participate in a thiol/disulfide interchange with glutathione disulfide. This rate-limiting initial S-thiolation, which occurs with indistinguishable rates in both clusters, then causes the clusters to collapse and release their zinc. Such a mechanism of metal release would link the control of the metal content of metallothionein to the cellular glutathione redox status and raises important questions about the physiological implications of this observation with regard to a role of glutathione in zinc metabolism and in making zinc available for other biomolecules.

The function of zinc metallothionein: a link between cellular zinc and redox state.

A chemical and biochemical mechanism of action of the metallothionein (MT)/thionein (T) couple has been proposed. The mechanism emphasizes the importance of zinc/sulfur cluster bonding in MT and the significance of the two cluster networks as redox units that confer mobility on otherwise tightly bound and redox-inert zinc in MT. In this article, it is further explored how this redox mechanism controls the metabolically active cellular zinc pool. The low redox potential of the sulfur donor atoms in the clusters readily allows oxidation by mild cellular oxidants with concomitant release of zinc. Such a release by oxidants and the preservation of zinc binding by antioxidants place MT under the control of the cellular redox state and, consequently, energy metabolism. The binding of effectors, e.g., ATP, elicits conformational changes and alters zinc binding in MT. The glutathione/glutathione disulfide redox couple as well as selenium compounds effect zinc delivery from MT to the apoforms of zinc enzymes. This novel action of selenium on zinc/sulfur coordination sites has significant implications for the interaction between these essential elements. Tight binding and kinetic lability, modulation of MT by cellular ligands and the redox state, control of MT gene expression by zinc and many other inducers all support a critical function of the MT/T system in cellular homeostasis and distribution of zinc.

Retinal is not formed in vitro by enzymatic central cleavage of beta-carotene.

Rat intestinal mucosa was prepared and incubated with beta-carotene by the procedure of Goodman and Olson [Goodman, DeW. S., & Olson, J.A. (1969) Methods Enzymol. 15, 462-475] to determine beta-carotene cleavage activity. A new detection system for the reaction products of the described enzyme beta-carotene 15,15'-dioxygenase (EC 1.13.11.21) employs solvent extraction of retinoids and carotenoids followed by high-performance liquid chromatography separation and photometric detection of the pigments. It has not detected any newly formed retinal or other retinoids in the intestinal protein preparations from normal or vitamin A deficient rats. The latter were chosen as a possible source of more active enzyme preparations. With corresponding blank samples subjected to identical conditions of incubation but without added protein, small amounts of beta-apocarotenals could be detected. They were previously reported as cleavage products of beta-carotene [Ganguly, J., & Sastry, P.S. (1985) World Rev. Nutr. Diet. 45, 198-220] but are clearly not formed as a result of an enzymatic reaction. The failure to detect in vitro enzymatic central or random cleavage of the beta-carotene molecule in extracts of rat intestinal mucosa emphasizes the need to reevaluate the existing theory of conversion of beta-carotene into vitamin A.