The binding of 1,10-phenanthroline to specifically active-site cobalt(II)-substituted horse-liver alcohol dehydrogenase. A probe for the open-enzyme conformation

We have studied the binding of 1,10-phenanthroline to specifically active-site cobalt(II)-substituted horse-liver alcohol dehydrogenase [Co(II)-LADH]. The dissociation constant is a factor of 6500 smaller than in the native enzyme. Spectral evidence is given which shows that 1,10-phenanthroline does not remove the catalytic Co(II) ion and that binding of 1,10-phenanthroline renders the catalytic metal ion pentacoordinate. The maximum limiting rate constant for the association of 1,10-phenanthroline to Co(II)-LADH is about 60 s-1. This is about a third of the value (169 s-1) determined for native horse-liver alcohol dehydrogenase, Zn(II)LADH [Frolich et al. (1978) Arch. Biochem. Biophys. 189, 471-480]. For cadmium(II)-substituted horse-liver alcohol dehydrogenase, [Cd(II)LADH] the maximum limiting rate constant for association of 1,10-phenanthroline increased to 590 s-1. These findings demonstrate that the rate-limiting step is strongly dependent on the chemical nature of the catalytic metal ion and its immediate environment. 1,10-Phenanthroline is shown to bind to the Co(II)-LADH.NAD+ complex in the open conformation. The maximum limiting rate constant remains unchanged in the presence of NAD+. The data have been used to derive a kinetic scheme for the formation of ternary complexes including NAD+ that involves a slow intermediary step.     

The catalytic metal atoms of cobalt substituted liver alcohol dehydrogenase.

The catalytic and non-catalytic Zn atom pairs of horse liver alcohol dehydrogenase (LADH) have been replaced sequentially either by ⁶⁵Zn, Co or ⁶⁵Zn and Co. The Co derivatives exhibit characteristic spectra. When Co replaces the Zn atoms which exchange secondly, enzymatic activity is altered, and both imidazole and 1,10-phenanthroline (OP) significantly modify the spectrum of the catalytic Co atoms. Further, due to the removal of cobalt, the instantaneous and reversible OP inhibition of the native enzyme becomes time-dependent and irreversible. Jointly, these data identify the pair of metal atoms of LADH which exchange secondly under the present conditions as the catalytic one. The approach described provides a basis for the differentiation of catalytic and non-catalytic metal atoms of multichain metalloenzymes.     

Substrate specificity and stereoselectivity of horse liver alcohol dehydrogenase. Kinetic evaluation of binding and activation parameters controlling the catalytic cycles of unbranched, acyclic secondary alcohols and ketones as substrates of the native and active-site-specific Co(II)-substituted enzyme

1. The steady-state parameters kcat and Km and the rate constants of hydride transfer for the substrates isopropanol/acetone; (S)-2-butanol, (R)-2-butanol/2-butanone; (S)-2-pentanol, (R)-2-pentanol/2-pentanone; 3-pentanol/3-pentanone; (S)-2-octanol and (R)-2-octanol have been determined for the native Zn(II)-containing horse-liver alcohol dehydrogenase (LADH) and the specific active-site-substituted Co(II)LADH. 2. A combined evaluation of steady-state kinetic data and rate constants obtained from stopped-flow measurements, allowed the determination of all rate constants of the following ordered bi-bi mechanism: E in equilibrium E.NAD in equilibrium E.NAD.R1R2 CHOH in equilibrium E.NADH.R1R2CO in equilibrium E.NADH in equilibrium E. 3. On the basis of the different substrate specificities of LADH and yeast alcohol dehydrogenase (YADH), a procedure has been developed to evaluate the enantiomeric product composition of ketone reductions. 2-Butanone and 2-pentanone reductions revealed (S)-2-butanol (86%) and (S)-2-pentanol (95%) as the major products. 4. The observed enantioselectivity implies the existence of two productive ternary complexes; E.NADH.(pro-S) 2-butanone and E.NADH.(pro-R) 2-butanone. All rate constants describing the kinetic pathways of the system (S)-2-butanol, (R)-2-butanol/2-butanone have been determined. These data have been used to estimate the expected enantiomer product composition of 2-butanone reductions using apparent kcat/Km values for the two different ternary-complex configurations of 2-butanone. Additionally, these data have been used for computer simulations of the corresponding reaction cycles. Calculated, simulated and experimental data were found to be in good agreement. Thus, the system (S)-2-butanol, (R)-2-butanol/2-butanone is the first example of a LADH-catalyzed reaction for which the stereochemical course could be described in terms of rate constants of the underlying mechanism. 5. The effects of Co(II) substitution on the different steps of the kinetic pathway have been investigated. The free energy of activation is higher for alcohol oxidation and lower for ketone reduction when catalyzed by Co(II)LADH in comparison to Zn(II)LADH. However, the free energies of binding are affected by metal substitution in such a way that the enantioselectivity of ketone reduction is not significantly changed by the substitution of Co(II) for Zn(II). 6. Evaluation of the data shows that substrate specificity and stereoselectivity result from combination of the free energies of binding and activation, with differences in binding energies as the dominating factors. In this regard, the interactions of substrate molecules with the protein moiety are dominant over the interactions with the catalytic metal ion.     

Cadmium-109 as a probe of the metal binding sites in horse liver alcohol dehydrogenase.

The noncatalytic and catalytic zinc atoms of horse liver alcohol dehydrogenase, [(LADH)Zn2Zn2] or LADH, have been replaced differentially with 109Cd by equilibrium dialysis, resulting in two new enzymatically active species, [(LADH)109Cd2Zn2] and [(LADH)109Cd2109Cd2]. The UV difference spectra of the cadmium enzymes vs. native [(LADH)Zn2Zn2] reveal maxima at 240 nm with molar absorptivities, delta epsilon 240, of 1.6 X 10(4) M-1 cm-1 per noncatalytic 109Cd atom and 0.9 X 10(4) M-1 cm-1 per catalytic 109Cd atom, consistent with coordination of the metals by four and two thiolate ligands, respectively, strikingly similar to the 250-nm charge-transfer absorbance in metallothionein. Carboxymethylation of the Cys-46 ligand to the catalytic metal in LADH presumably lowers the overall stability constant of the coordination complex and results in loss of catalytic 109Cd or catalytic cobalt but not catalytic zinc from the enzyme.     

Manganese(II) tri-tert-butoxysilanethiolate complexes with imidazole-based coligands: a neutral complex with four independent ligands and MNOS2 core (M=Mn) related to the liver alcohol dehydrogenase catalytic center (M=Zn)

The reaction of [Mn{SSi(OBu(t))3}2(MeOH)4] with imidazole and its two methyl substituted derivatives leads to different types of heteroleptic manganese(II) thiolate complexes. Reaction with 1-methylimidazole gives the silanethiolate devoid of methanol but with two nitrogen ligands and thus central MnN(2)S(2) core. The reaction with imidazole leads to the methanol solvated complex with only one nitrogen ligand but manganese coordination sphere enlarged to MnO(2)NS(2) due to an O,S-chelation by tri-tert-butoxysilanethiolate ligand. Molecules of this compound interact through a set of N-H...(Me)O-H...S hydrogen bonds with methanol hydroxyl group being simultaneously acceptor and donor. With 2-methylimidazole the product is an assembly of two different neutral complexes joined again by hydrogen bonds, however, this time of N-H...S type. One of these complexes has the previously mentioned MnO(2)NS(2) core. The second neutral complex exhibits four donor atoms (MnNOS(2)core) derived from four independent ligands, i.e., two silanethiolate rests, one N-heterocyclic base and one alcohol. This structure presents similarities with a zinc-based alcohol dehydrogenase active site that have never been obtained before, including with other metals (Zn, Co). It may, therefore, be considered the first neutral structural model of liver alcohol dehydrogenase (LADH).     

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.     

Kinetics and mechanisms of the recombination of Zn2+, Co2+, and Ni2+ with the metal-depleted catalytic site of horse liver alcohol dehydrogenase

The kinetics of the recombination of the metal-depleted active site of horse liver alcohol dehydrogenase (LADH) with metal ions have been studied over a range of pH and temperature. The formation rates were determined optically, by activity measurements, or by using the pH change during metal incorporation with a pH-indicator as monitor. The binding of Zn2+, Co2+, and Ni2+ ions occurs in a two-step process. The first step is a fast equilibrium reaction, characterized by an equilibrium constant K1. The spectroscopic and catalytic properties of the native or metal-substituted protein are recovered in a slow, monomolecular process with the rate constant k2. The rate constants k2 5.2 X 10(-2) sec-1 (Zn2+), 1.1 X 10(-3) sec-1 (Co2+), and 2 X 10(-4) sec-1 (Ni2+). The rate constants increase with increasing pH. Using temperature dependence, the activation parameters for the reaction with Co2+ and Ni2+ were determined. Activation energies of 51 +/- 2.5 kJ/mol (0.033 M N-Tris-(hydroxymethyl)methyl-2-aminomethane sulfonic acid (TES), pH 6, 9) for Co2+ and 48.5 +/- 4 kJ/mol (0.033 M TES, pH 7, 2) for Ni2+ at 23 degrees C were found. The correspondent activation entropies are - 146 +/- 10 kJ/mol K for Co2+ and - 163 +/- 9 kJ/mol K for Ni2+. Two protons are released during the binding of Zn2+ to H4Zn(n)2 LADH in the pH range 6.8-8.1. The binding of coenzyme, either reduced or oxidized, prevents completely the incorporation of metal ions, suggesting that the metal ions enter the catalytic site via the coenzyme binding domain and not through the hydrophobic substrate channel.     

The involvement of the bridging imidazolate in the catalytic mechanism of action of bovine superoxide dismutase.

The pulse-radiolysis method has been used to study the catalytic mechanism of O2 leads to dismutation by the Co(II)-substituted bovine erythrocuprein (superoxide dismutase, EC 1.15.1.1). Catalysis is accompanied by spectral changes that may be interpreted in terms of rapid protonation and deprotonation of the Cu-facing nitrogen atom of the imidazolate that bridges the Cu(II) and the Co(II) [or Zn(II)] in the oxidized enzyme. This rapid change permits the possibility that the imidazole is a proton donor in the catalytic reduction of O2 leads to.     

Metal-directed affinity labeling of zinc(II), cobalt(II) and cadmium(II) horse liver alcohol dehydrogenases

The active site metal in horse liver alcohol dehydrogenase has been studied by metal-directed affinity labeling of the native zinc(II) enzyme and that substituted with cobalt(II) or cadmium(II). Reversible binding of bromoimidazolyl propionic acid to the cobalt enzyme blueshifts the visible absorption band originating from the catalytic cobalt atom at 655 to 630 nm. Binding of imidazole to the cobalt(II) enzyme redshifts the 655 nm band to 667 nm. Addition of bromoimidazolyl propionic acid blueshifts this 667 nm band back to 630 nm. This proves direct binding of the label to the active site metal in competition with imidazole. The affinity of the label for the reversible binding site in the three enzymes follows the order Zn ? Cd ? Co. After reversible complex formation, bromoimidazolyl propionic acid alkylates cysteine-46, one of the protein ligands to the active site metal. The nucleophilic reactivity of this metal-mercaptide bond in each reversible complex follows the order Co ? Zn ? Cd.     

Nuclear magnetic resonance studies of substrate interaction with cobalt substituted alcohol dehydrogenase from liver.

The role of zinc in liver alcohol dehydrogenase has been studied by replacement of 1.3 and 3.5 of the four Zn(II) ions with Co(II) and measuring the effects of the paramagnetic Co(II) on the relaxation rates of the protons of water, ethanol, and isobutyramide. Water relaxation studies at 8, 24, 100, and 220 MHz indicate two classes of bound Co(II). The similar to 2 readily replaced Co(II) ions retain one fast exchanging water proton in their inner coordination spheres, while the similar to 2 slowly exchanging Co(II) ions coordinate no detectable water protons, indicating that the former replaced Zn(II) at the "catalytic sites" and the latter replaced Zn(II) at the "structural sites" detected crystallographically. Ethanol, acetaldehyde, and isobutyramide bind with appropriate affinities to the Co(II) substituted alcohol dehydrogenases decreasing the number of fast exchanging protons at the catalytic Co(II) site by greater than or equal to 54 percent. Coenzyme binding causes smaller changes in the water relaxation rate which may be due to local conformation changes. The paramagnetic effects of Co(II) at the catalytic site on the relaxation rates of the methyl protons of isobutyramide at 100 and 220 MHz indicate that this analog binds at a site 9.1 A from the catalytic Co(II). This distance decreases to 6.9 A when NADH is bound, and a Co(II) to methyne proton distance of 6.6 A is determined indicating a conformation change leading to the formation of a second sphere enzyme-Co(II)-isobutyramide complex in which a hydroxyl or water ligand intervenes between the metal and the substrate analog. Similar behavior is observed in the enzyme-ethanol complexes. The paramagnetic effects of Co(II), at the catalytic site, on the relaxation rates of the protons of ethanol at 100 and 220 MHz, indicate that this substrate bind at a site 12-14 A distant from the catalytic Co(II) but that this distancedecreases to 6.3 A in the abortive enzyme-NADH-ethanol complex. The role of the catalytic Co(II) thus appears to be the activation of a hydroxyl or water ligand which polarizes the aldehyde carbonyl group by hydrogen bonding. The role of the structural Co(II), which is more distant from isobutyramide (9-11 A), may be that of a template for protein conformation changes. By combining the present distances with those from previous magnetic resonance studies on the liver enzyme, the arrangement of coenzyme, metal, and substrate at the active site in solution can be constructed. This arrangement is consistent with that of ADP-ribose and zinc in the crystalline complex of liver alcohol dehydrogenase as determined by X-ray crystallography (Branden et al., (1973), Proc. Natl. Acad. Sci. U.S.A.70, 2439).     

Resonance Raman spectra of copper(II)-substituted liver alcohol dehydrogenase: a type 1 copper analogue

Liver alcohol dehydrogenase (LADH) with copper in place of the catalytic zinc has recently been proposed to contain a type 1 site analogous to that in "blue" copper proteins. Resonance Raman spectra for the copper-substituted enzyme, Cu(II) X LADH, and its binary complexes with reduced nicotinamide adenine dinucleotide (NADH) and pyrazole support this viewpoint. These spectra have two dominant features: a sharp peak at approximately 415 cm-1, which is believed to be associated with vibration of the single histidine ligand, and a broader, asymmetric band at approximately 350 cm-1, whose components are assigned predominantly to vibrational modes of the two cysteinate ligands. The high frequency of these transitions, which is reminiscent of the blue copper proteins, is ascribed to the tetrahedral nature of the metal site that produces unusually short Cu-S bonds and coupled vibrational modes. Solvent exchange with H218O reveals no contribution to the resonance Raman spectrum of the water molecule, which is a metal ligand in free Cu(II) X LADH; however, the spectrum of the binary complex with pyrazole has several new peaks attributable, in part, to pyrazole ligation. The strong similarity among the vibrational spectra demonstrates that the Cu(II) environment in alcohol dehydrogenase maintains its near-tetrahedral geometry in the various enzyme derivatives. The resonance Raman spectrum of Ni(II) X LADH is close to that of Cu(II) X LADH and suggests a similar tetrahedral site. The Raman spectra presented here together with available optical and EPR data indicate that Cu(II) X LADH belongs to the type 1 copper classification and, thus, can provide new insights into this unusual coordination geometry.     

Inactivation of Lipoamide Dehydrogenase by Cobalt(II) and Iron(II) Fenton Systems: Effect of Metal Chelators, Thiol Compounds and Adenine Nucleotides

Fe(II)-and Co(II)-Fenton systems (FS) inactivated the lipoamide reductase activity but not the diaphorase activity of pig-heart lipoamide dehydrogenase (LADH). The Co(II) system was the more effective as LADH inhibitor. Phosphate ions enhanced the Fe(II)-FS activity. EDTA, DETAPAC, DL-histidine, DL-cysteine, glutathione, DL-dithiothreitol, DL-lipoamide, DL-thioctic acid, bathophenthroline, trypanothione and ATP, but not ADP or AMP, prevented LADH inactivation. Reduced disulfide compounds were more effective protectors than the parent compounds. Mg ions counteracted ATP protective action. Glutathione and DL-dithiothreitol partially restored the lipoamide dehydrogenase activity of the Fe(II)-FS-inhibited LADH. DL-histidine exerted a similar action on the Co(II)-FS-inhibited enzyme. Ethanol, mannitol and benzoate did not prevent LADH inactivation by the assayed Fenton systems and, accordingly, it is postulated that site-specific generated HO'radicals were responsible for LADH inactivation. With the Co(II)-FS, oxygen reactive species other than HO, might contribute to LADH inactivation.     

Evidence for catalytic dismutation of superoxide by cobalt(II) derivatives of bovine superoxide dismutase in aqueous solution as studied by pulse radiolysis.

By using the technique of pulse radiolysis to generate O2-., it is demonstrated that Co(II) derivatives of bovine superoxide dismutase in which the copper alone and both the copper and zinc of the enzyme have been substituted by Co(II), resulting in (Co,Zn)- and (Co,Co)-proteins, are capable of catalytically dismutating O2-. with 'turnover' rate constants of 4.8 X 10(6) dm3.s-1.mol-1 and 3.1 X 10(6) dm3.s-1.mol-1 respectively. The activities of the proteins are independent of the pH (7.4-9.4) and are about three orders of magnitude less than that of the native (Cu,Zn)-protein. The rate constants for the initial interaction of O2-. with the Co-proteins were determined to be (1.5-1.6) X 10(9) dm3.s-1.mol-1; however, in the presence of phosphate, partial inhibition is apparent [k approximately (1.9-2.3) X 10(8) dm3.s-1.mol-1]. To account for the experimental observations, two reaction schemes are presented, involving initially either complex-formation or redox reactions between O2-. and Co(II). This is the first demonstration that substitution of a metal into the vacant copper site of (Cu,Zn)-protein results in proteins that retain superoxide dismutase activity.     

Octahedral metal coordination in the active site of glyoxalase I as evidenced by the properties of Co(II)-glyoxalase I

Co(II)-glyoxalase I has been prepared by reactivation of apoenzyme from human erythrocytes with Co2+. The visible absorption spectrum showed maxima at 493 and 515 nm and shoulders at 465 and 615 nm. The absorption coefficients at 493 and 515 nm were 35 and 33 M-1 cm-1/cobalt ion, respectively; i.e. 70 and 66 M-1 cm-1 for the dimeric metalloprotein. The product of the enzymatic reaction, S-D-lactoylglutathione, although binding to Co(II)-glyoxalase I, had no demonstrable effect on the visible absorption spectrum, indicating binding outside the first coordination sphere of the metal. The EPR spectrum at 3.9 K was characterized by g1 approximately 6.6, g2 approximately 3.0, and g3 approximately 2.5, and eight hyperfine lines with A1 = 0.025 cm-1. Binding of the strong competitive inhibitor S-p-bromobenzylglutathione to Co(II)-glyoxalase I gave three g values: 6.3, 3.4, and 2.5, indicating a conformational change affecting the environment of the metal ion. Both optical and EPR spectra strongly suggest a high spin Co2+ with octahedral coordination in the active site of the enzyme. The similarities in kinetic properties between native Zn(II)-glyoxalase I and enzyme substituted with Mg2+, Mn2+, or Co2+ is consistent with the view that these enzyme forms have the same metal coordination in the protein.     

Crystal-structure determination of reduced nicotinamide adenine dinucleotide complex with horse liver alcohol dehydrogenase maintained in its apo conformation by zinc-bound imidazole

A crystallographic study to 2.4-A resolution of the ternary complex between horse liver alcohol dehydrogenase (LADH), NADH, and the effector molecule imidazole (Im) (LADH-NADH-Im) is presented. The ligand binding and the changes in the protein structure due to ligand interactions were interpreted from difference electron density maps calculated with phase angles derived from the refined native enzyme model. The complex crystallizes in the orthorhombic space group C2221, and the enzyme structure remains in the apo conformation in which the active-site cleft is not entirely shielded from the solvent. NADH binds in an extended conformation, and the protein-coenzyme interactions are weaker compared to other complexes. The B-stereospecific side of the nicotinamide ring faces the catalytic center (LADH is known to be an A-side-specific enzyme). However, the reactive carbon atom C4 of the ring has a similar position in relation to active-center groups in this structure compared to LADH complexes where the A side of the ring faces the substrate site. The carboxamide group is situated within hydrogen-bonding distance to the sulfur of Cys-46, which is one of the three protein ligands to the active-site zinc atom. The imidazole molecule is directly ligated to the metal ion, which has a roughly tetrahedral geometry in the complex.     

The Glu(B13) carboxylates of the insulin hexamer form a cage for Cd2+ and Ca2+ ions

Substitution of Cd2+ for Zn2+ yields a hexameric insulin species containing 3 mol of metal ion per hexamer. The Cd2+ binding loci consist of the two His(B10) sites and a new site involving the Glu(B13) residues located at the center of the hexamer [Sudmeier, J. L., Bell, S. J., Storm, M. C., & Dunn, M. F. (1981) Science (Washington, D.C.) 212, 560-562]. Substitution of Co2+ or Co3+ for Zn2+ gives hexamers containing 2 mol of metal per hexamer. Insulin solutions to which both Cd2+ and Co2+ have been added in a ratio of 6:2:1 [In]:[Co2+]:[Cd2+] followed by oxidation to the exchange-inert Co3+ state yield stable hybrid species containing both Co3+ and Cd2+ with a composition of (In)6(Co3+)2Cd2+. The kinetics of the reaction of 2,2',2"-terpyridine (terpy) with the exchange-labile (In)6(Cd2+)2 and (In)6(Co2+)2 derivatives are biphasic and involve the rapid formation of an intermediate with coordination of one terpy molecule to each protein-bound metal ion; then, in a rate-limiting step the terpy-coordinated metal ion dissociates from the protein, and a second molecule of terpy binds to the metal ion to form a bis complex. Reaction of the exchange-inert Co3+ ions of (In)6(Co3+)2 with terpy is a slow apparent first-order process (t1/2 = 13.1 h). In contrast to the kinetic behavior of (In)6(Co2+)2 and (In)6(Cd2+)2, the Cd2+ ions bound to the hybrid (In)6(Co3+)2Cd2+ react quite slowly with terpy (t1/2 = 1 h at pH 8.0).(ABSTRACT TRUNCATED AT 250 WORDS)     

Supramolecular structures of metronidazole and its copper(II), cobalt(II) and zinc(II) coordination compounds

In this work we present the synthesis and structural and spectroscopic characterization of Cu(II), Co(II) and Zn(II) coordination compounds with the antibiotic metronidazole ([double bond]emni). Coordination to metal ions is through its imidazolic nitrogen, while the hydroxyethyl and nitro groups act as supramolecular synthons. [Co(emni)(2)Br(2)], and [Zn(emni)(2)X(2)] (X(-)=Cl, Br) stabilize zig-zag chains, and a 2D supramolecular structure is formed by inter-chain contacts through inter-molecular hydrogen-bonding. Pleated sheet or layers are formed by [Co(emni)(2)Cl(2)] and [Cu(emni)(2)Cl(H(2)O)](2)Cl(2), respectively. The dinuclear Cu(II) compound [Cu(emni)mu(O(2)CMe)(2)](2) gives a one-dimensional zig-zag arrangement. The contribution of metal ions in metronidazole coordination compounds is shown in the stabilization of the different aggregate structures.     

Coordination geometry for cadmium in the catalytic zinc site of horse liver alcohol dehydrogenase: studies by PAC spectroscopy

Active site substituted Cd(II) horse liver alcohol dehydrogenase has been studied by Perturbed Angular Correlation of Gamma rays Spectroscopy during turnover conditions for benzaldehyde and 4-trans-(N,N-dimethylamino)cinnamaldehyde. The ternary complex between alcohol dehydrogenase NAD⁺ and Cl^–, and the binary complex between alcohol dehydrogenase and orthophenanthroline have also been studied. The Nuclear Quadrupole Interaction parameters have been interpreted in terms of different coordination geometries for Cd(II) in the catalytic zinc site of the enzyme. Calculation of the nuclear quadrupole interaction for cadmium in the catalytic site of the enzyme with and without coenzyme, based upon the four coordinated geometries determined from X-ray diffraction, agrees with the experimentally determined values. The ternary complexes between enzyme, NAD⁺ and either Cl^– or trifluoroethanol and the binary complex between enzyme and orthophenanthroline have almost identical spectral parameters which are not consistent with a four coordinated geometry, but are consistent with a five coordinated geometry. The nonprotein ligands for the ternary complex with trifluoroethanol are suggested to be an alkoxide group and a water molecule. The Nuclear Quadrupole Interaction parameters for the productive ternary complex between enzyme, NADH and an aldehyde is consistent with the four coordinated geometry predicted from X-ray diffraction data having the carbonyl group of the aldehyde substituting the water molecule as ligand to the metal.Abbreviations LADH Horse liver alcohol dehydrogenase - H₄Zn₂LADH derivative of LADH free of zinc in the catalytic site - ¹¹¹CdZn₂LADH derivative of LADH with ¹¹¹Cd (carrier free) in the catalytic site - Cd₂Zn₂LADH derivative of LDH with 2 mole of Cd(II) per mole LADH in the catalytic site - PAC pertubed angular correlation of gamma rays - NQI Nuclear quadrupole interaction - AOM Angular overlap model - trifluoroethanol 2,2,2-trifluoroethanol - DACA trans-4-(N,N-dimethylamino)cinnamaldehyde - NAD⁺ and NADH oxidized and reduced nicotinamide adenine dinucleotide - NADH₂ reduced 1,4,5,6-tetrahydronicotinamide adenine dinucleotide The experimental work was carried out at the Niels Bohr Institute Risø, 4000 Roskilde and Blegdamsvej 19, 2100 Copenhagen, Denmark Offprint requests to: R. Bauer