The interaction of adenine with its binding site in rabbit muscle glyceraldehyde 3-phosphate dehydrogenase studied by fluorescence decay.

The fluorescence decay mechanism of 1, N⁶-ethenoadenosine diphosphoribose bound to rabbit muscle glyceraldehyde 3-phosphate dehydrogenase markedly differs from that of the intact coenzyme analog (εNAD⁺) bound to the same enzyme. In the latter case the fluorescence is partially quenched by interactions between the ethenoadenine ring and amino acid residues in its binding site. Binding of the nicotinamide moiety of the coenzyme thus affects the relative orientation of the adenine ring within its binding site leading to the quenching interactions. The interactions of the adenine group with its binding site induce conformational changes in the enzyme which affect the binding of additional coenzyme molecules. The nicotinamide base thus determines, indirectly, the negative cooperativity found in NAD⁺ binding.     

Studies of coenzyme binding to rabbit muscle glyceraldehyde-3-phoshate dehydrogenase.

The binding of NAD+, NADH and adenosine diphosphoribose (Ado-PP-Rib) to a stable, highly active and nucleotide-free preparation of rabbit muscle glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate: NAD+ oxidoreductase (phosphorylating), EC 1.2.1.12) has been studied. All three nucleotides quench the protein fluorescence to the same extent when they bind to the enzyme, and this property has been used to measure the dissociation constants for the two high-affinity binding sites for the nucleotides. The results indicate negative interactions between, or non-identify of, these two binding sites, to which NAD+ and NADH bind with similar affinity. The binding of NAD+ to the enzyme has been studied by spectrophotometric titrations at 360 nm. It appears that the binding of NAD+ to each of the four subunits of the enzyme contributes equally to the intensity of this 'Racker' band. The dissociation constants associated with the binding of the third and fourth molecules of NAD+ estimated from such titrations confirm some previous estimates. The binding of NADH to the enzyme causes a decrease of intensity of the absorbance of the coenzyme at 340 nm, and the dissociation constants for binding of the third and fourth molecules of NADH have been estimated from spectrophotometric titrations. They are the same as those for NAD+. Judging by the apparent dissociation constants, negative interactions on binding the third molecule of NAD+ or NADH are more marked than those associated with the binding of the second and fourth molecules, suggesting that a major conformational change occurs at half-saturation of the tetramer with coenzyme.     

On the mechanism of biological methane formation: structural evidence for conformational changes in methyl-coenzyme M reductase upon substrate binding

Methyl-coenzyme M reductase (MCR) catalyzes the final reaction of the energy conserving pathway of methanogenic archaea in which methylcoenzyme M and coenzyme B are converted to methane and the heterodisulfide CoM-S-S-CoB. It operates under strictly anaerobic conditions and contains the nickel porphinoid F430 which is present in the nickel (I) oxidation state in the active enzyme. The known crystal structures of the inactive nickel (II) enzyme in complex with coenzyme M and coenzyme B (MCR-ox1-silent) and in complex with the heterodisulfide CoM-S-S-CoB (MCR-silent) were now refined at 1.16 A and 1.8 A resolution, respectively. The atomic resolution structure of MCR-ox1-silent describes the exact geometry of the cofactor F430, of the active site residues and of the modified amino acid residues. Moreover, the observation of 18 Mg2+ and 9 Na+ ions at the protein surface of the 300 kDa enzyme specifies typical constituents of binding sites for either ion. The MCR-silent and MCR-ox1-silent structures differed in the occupancy of bound water molecules near the active site indicating that a water chain is involved in the replenishment of the active site with water molecules. The structure of the novel enzyme state MCR-red1-silent at 1.8 A resolution revealed an active site only partially occupied by coenzyme M and coenzyme B. Increased flexibility and distinct alternate conformations were observed near the active site and the substrate channel. The electron density of the MCR-red1-silent state aerobically co-crystallized with coenzyme M displayed a fully occupied coenzyme M-binding site with no alternate conformations. Therefore, the structure was very similar to the MCR-ox1-silent state. As a consequence, the binding of coenzyme M induced specific conformational changes that postulate a molecular mechanism by which the enzyme ensures that methylcoenzyme M enters the substrate channel prior to coenzyme B as required by the active-site geometry. The three different enzymatically inactive enzyme states are discussed with respect to their enzymatically active precursors and with respect to the catalytic mechanism.     

Kinetics of coenzyme binding to liver alcohol dehydrogenase in the pH range 10-12

On- and off-velocity constants for NADH and NAD+ binding to liver alcohol dehydrogenase in the pH range 10-12 have been determined by stopped-flow kinetic methods. The results are consistent with previously reported equilibrium binding data and proposals attributing the main effects of pH on coenzyme binding to ionization of Lys-228 and zinc-bound water. Deprotonation of the group identified as Lys-228 decreases the NADH and NAD+ association rates by a factor exceeding 20 and has no detectable effect on the coenzyme dissociation rates in the examined pH range. Ionization of the group identified as zinc-bound water causes a 3-fold increase of the rate of NADH dissociation from the enzyme, and decreases the rate of NAD+ dissociation by a factor of 200. The NADH and NAD+ association rates are decreased by a factor of 30 and 5, respectively. The observed effects of pH can be rationalized in terms of electrostatic interactions of the ionizing groups with the charges present on the coenzyme molecules and lend support to the idea that binding of the coenzyme nicotinamide ring occurs subsequent to binding of the AMP portion of the coenzyme.     

Sturgeon glyceraldehyde-3-phosphate dehydrogenase.

The formation of binary complexes between sturgeon apoglyceralddhyde-3-phosphate dehydrogenase, coenzymes (NAD+ and NADH) and substrates (phosphate, glyceraldehyde 3-phosphate and 1,3-bisphosphoglycerate) has been studied spectrophotometrically and spectrofluorometrica-ly. Coenzyme binding to the apoenzyme can be characterized by several distinct spectroscopic properties: (a) the low intensity absorption band centered at 360 nm which is specific of NAD+ binding (Racker band); (b) the quenching of the enzyme fluorescence upon coenzyme binding; (c) the quenching of the fluorescence of the dihydronicotinamide moiety of the reduced coenzyme (NADH); (D) the hypochromicity and the red shift of the absorption band of NADH centered at 338 nm; (e) the coenzyme-induced difference spectra in the enzyme absorbance region. The analysis of these spectroscopic properties shows that up to four molecules of coenzyme are bound per molecule of enzyme tetramer. In every case, each successively bound coenzyme molecule contributes identically to the total observed change. Two classes of binding sites are apparent at lower temperatures for NAD+ Binding. Similarly, the binding of NADH seems to involve two distinct classes of binding sites. The excitation fluorescence spectra of NADH in the binary complex shows a component centered at 260 nm as in aqueous solution. This is consistent with a "folded" conformation of the reduced coenzyme in the binary complex, contradictory to crystallographic results. Possible reasons for this discrepancy are discussed. Binding of phosphorylated substrates and orthophosphate induce similar difference spectra in the enzyme absorbance region. No anticooperativity is detectable in the binding of glyceraldehyde 3-phosphate. These results are discussed in light of recent crystallographic studies on glyceraldehyde-3-phosphate dehydrogenases.     

Kinetics of enzyme-coenzyme interactions by NMR spectroscopy.

The kinetics for the binding of coenzymes to H4 and M4 lactate dehydrogenase from chicken were investigated by nuclear magnetic resonance spectroscopy. With detailed computer analysis, some kinetic parameters were extracted from the chemical shifts and the linewidth of the observed coenzyme resonances at various enzyme/coenzyme ratios and temperatures. The results of the analysis indicated that the dissociation rates of coenzymes from the enzyme/coenzyme complexes are slower with the H4 isozyme than those involving the M4 isozyme. The lifetimes for the NAD+-enzyme complexes are on the order of 1 msec while those for the NADH-enzyme complexes are on the order of 10 ms (at room temperature). Much shorter transverse relaxation times of the coenzyme resonances were observed in NADH-enzyme complexes than those in the NAD+-enzyme complexes. The calculated kinetic constants are in good agreement with the previous studies by stopped-flow and temperature jump methods. A generalized NMR kinetic treatment for the binding of small molecules to a macromolecule is presented.     

Room temperature phosphorescence of Trp-314 as a monitor of subunit communications in alcohol dehydrogenase from horse liver

The phosphorescence properties of liver alcohol dehydrogenase from horse were characterized at limiting concentrations of coenzyme and coenzyme analogues. The emission decay kinetics of Trp-314 in strong, slowly exchanging, ternary complexes with NADH/isobutyramide, NAD/pyrazole, and NADH/dimethyl sulfoxide displays a markedly nonexponential character. The analysis of decay components over the saturation curve reveals that the phosphorescence from singly bound protein molecules has a lifetime from 1 to 1.3 s, which is 2-3 times larger than observed with fully bound and unliganded enzyme. The remarkably tighter configuration reported by the triplet probe for the coenzyme-binding domain in half-saturated macromolecules is not exclusive of strongly inhibited ternary complexes. Measurements on binary complexes with NADH, ADPR, and the inactive coenzyme analogue 1,4,5,6-tetrahydronicotinamide adenine dinucleotide confirm that binding of the ligand to one subunit has qualitatively the same influence on protein structure. If the lifetime of Trp-314 provides clear evidence for an appreciable change in conformation at half-binding that is apparently triggered by the ADPR fragment of the coenzyme, such communication between subunits does not lead to allosteric phenomena in coenzyme binding.     

Binding of coenzyme and substrate and coenzyme analogues to 6-phosphogluconate dehydrogenase from sheep liver. An X-ray study at 0.6 nm resolution.

The analogues of the coenzyme NADP+, nicotinamide--8-bromo-adenine dinucleotide phosphate (Nbr8ADP+) and 3-iodopyridine--adenine dinucleotide phosphate (io3PdADP+), were prepared. Nbr8ADP+ was found to be active in the hydrogen transfer adn io3PdADP+ is a coenzyme competitive inhibitor for 6-phosphogluconate dehydrogenase. The binding of NADP+, NADPH and NADPH together with 6-phosphogluconate as well as that of both analogues to crystals of the enzyme 6-phosphogluconate dehydrogenase has been investigated at 0.6-nm resolution using difference electron density maps. The molecules bind in a similar position in a cleft in the enzyme subunit distant from the dimer interface. The orientation of the coenzyme in the site has been determined from the io3PdADP+ -NADP+ difference density. The ternary complex difference density extends beyond that of the nicotinamide moiety of the coenzyme and tentatively indicates substrate binding. No clear identification of the bromine atom of Nbr8ADP+ can be made. However, the analogue is bound more deeply in the cleft than is NADP+. The NADPH density is the most clearly defined and has thus been used to fit a molecular model using an interactive graphics system, checking for preferred geometry. A possible conformation is presented which is significantly different from that of NAD+ in the lactate dehydrogenase ternary complex.     

Specific interactions of 3-phosphoglyceroyl-glyceraldehyde-3-phosphate dehydrogenase with coenzymes.

The binding of oxidized and reduced coenzyme (NAD+ and NADH) to 3-phosphoglyceroyl-glyceraldehyde-3-phosphate dehydrogenase has been studied spectrophotometrically and fluorimetrically. The binding of NAD+ to the acylated sturgeon enzyme is characterized by a significant quenching of the enzyme fluorescence (about 25%) and the induction of a difference spectrum in the ultraviolet absorbance region of the enzyme. Both of these spectroscopic properties are quantitatively distinguishable from those of the corresponding binary enzyme-NAD+ complex. Binding isotherms estimated by gel filtration of the acylated enzyme are in close agreement to those obtained by spectrophotometric and fluorimetric titrations. Up to four NAD+ molecules are bound to the enzyme tetramer. No anticooperativity can be detected in the binding of oxidized coenzyme, which is well described on the basis of a single class of four binding sites with a dissociation constant of 25 muM at 10 degrees C, pH 7.0. The binding of NADH to the acylenzyme has been characterized spectrophotometrically. The absorption band of the dihydronicotinamide moiety of the coenzyme is blue-shifted to 335 nm with respect to free NADH. In addition, a large hypochromicity (23%) is observed together with a significant increase of the bandwidth at half height of this absorption band. This last property is specific to the acylenzyme-DADH complex, since it disappears upon arsenolysis of the acylenzyme. The binding affinity of NADH to the acylated enzyme has been estimated by performing simultaneous spectrophotometric and fluorimetric titrations of the NADH appearance upon addition of NAD+ to a mixture of enzyme and excess glyceraldehyde 3-phosphate. In contrast to NAD+, the reduced coenzyme NADH appears to be relatively strongly bound to the acylated enzyme, the dissociation constant of the acylenzyme-NADH complex being estimated as 2.0 muM at 25 degrees C. In addition a large quenching of the NADH fluorescence (about 83%) is observed. The comparison of the dissociation constants of the coenzyme-acylenzyme complexes and the corresponding Michaelis constants suggests a reaction mechanism of the enzyme in which significant formation and dissociation of NAD+-acylenzyme and NADH-acylenzyme complexes occur. Under physiological conditions the activity of the enzyme can be regulated by the ratio of oxidized and reduced coenzymes. Possible reasons for the lack of anticooperativity in coenzyme binding to the acylated form of the enzyme are discussed.     

Catalytic function of a tyrosyl residue in tryptophanase

Tryptophanase has an essential tyrosyl residue/active site which can be modified by tetranitromethane. Pyridoxal 5'-phosphate can prevent this modification efficiently, whereas pyridoxal 5'-phosphate N-oxide cannot, indicating that the free pyridinium N is required for the interaction of the coenzyme with the tyrosyl residue, probably via a hydrogen bond. The weakened binding of the coenzyme to the modified enzyme was confirmed on gel filtration, the modified enzyme being dissociated from the coenzyme seven-fold faster than the native enzyme. Furthermore, absorption spectral analyses demonstrated that the modified enzyme can catalyze the transaldimination step, but fails to abstract the alpha-H of substrates. The tyrosyl residue, therefore, not only participates in coenzyme binding, but also contributes to alpha-H labilization.     

Binding to chicken liver lactatedehydrogenase (author's transl)]

Some information about the lactate dehydrogenase NAD binding site has been obtained by working with coenzymes analogs of incomplete molecules. 5'AMP, 5'-ADP, ATP, 5'-c-AMP and 3'(2)-AMP inhibit chicken liver LDH activity competitively with NADH. 5"-AMP and 5'-ADP show a stronger inhibition power than ATP, suggesting that the presence of one or two phosphate groups at the 5' position of adenosine, is essential for the binding of the coenzyme analogs at the enzyme binding site. Ribose and ribose-5'-P do not appear to inhibit the LDH activity, proving that purine base lacking mononucleotides do not bind to the enzyme. 5"-ADPG inhibits LDH activity in the exactly as 5'-ADP, showing that ribose moiety may be replaced by glucose, without considerable effects on the coenzyme analog binding. 2'-desoxidenosin-5'-phosphate proves to be a poorer inhibitor of the LDH activity than 5'-AMP, indicating that an interaction between the--OH groups and the amino-acids of the LDH active center takes place. Nicotinamide does not produce any inhibition effect, while NMN and CMP induce a much weaker inhibition than the adenine analogues, thus indicating a lesser binding capacity to the enzyme. Therefore, the LDH binding site seems to show some definite specificity towards the adenina groups of the coenzyme.     

The stabilization by a coenzyme analog of a conformational change induced by substrate in 6-phosphogluconate dehydrogenase.

The reaction of NADP⁺ with periodate yields a coenzyme analog that can be bound to the NADP⁺ binding site of 6-phosphogluconate dehydrogenase from Candida utilis. This coenzyme analog can be irreversibly bound to the enzyme by reduction with sodium borohydride. The binding of one molecule of inhibitor to only one of the two subunits of the enzyme causes the inactivation of this subunit but does not alter the catalytic activity of the other subunit. Thus the two subunits do not have apparent catalytic interactions. When the reaction between the enzyme and the coenzyme analog is carried out in the presence of the substrate, the covalent modification of only one subunit causes the inactivation of both subunits. In this case the two subunits show an extreme negative cooperativity. It is suggested that the binding of the substrate induces in the enzyme molecule a conformational change that is stabilized by the irreversible binding of the coenzyme analog.     

Malate dehydrogenase, circular dichroism difference spectra of porcine heart mitochondrial and supernatant enzymes, binary enzyme-coenzyme, and ternary enzyme-coenzyme-substrate analog complexes.

Circular dichroism spectra and circular dichroism difference spectra, generated when porcine heart mitochondrial and supernatant malate dehydrogenase bind coenzymes or when enzyme dihydroincotinamide nucleotide binary complexes bind substrate analogs, are presented. No significant changes are observed in protein chromophores in the 200- to 240-nm spectral range indicating that there is apparently little or no perturbation of the alpha helix or peptide backbone when binary or ternary complexes are formed. Quite different spectral perturbances occur in the two enzymes with reduced coenzyme binding as well as with substrate-analog binding by enzyme-reduced coenzyme binding. Comparison of spectral perturbations in both enzymes with oxidized or reduced coenzyme binding suggests that the dihydronicotinamide moiety of the coenzyme interacts with or perturbs indirectly the environment of aromatic amino acid residues. Reduced coenzyme binding apparently perturbs tyrosine residues in both mitochondrial malate dehydrogenase and lactic dehydrogenase. Reduced coenzyme binding perturbs tyrosine and tryptophan residues in supernatant malate dehydrogenase. The number of reduced coenzyme binding sites was determined to be two per 70,000 daltons in the mitochondrial enzyme, and the reduced coenzyme dissociation constants, determined through the change in ellipticity at 260 nm, with dihydronicotinamide adenine dinucleotide binding, were found to be good agreement with published values (Holbrook, J. J., and Wolfe, R. G. (1972) Biochemistry 11, 2499-2502) obtained through fluorescence-binding studies and indicate no apparent extra coenzyme binding sites. When D-malate forms a ternary complex with malate dehydrogenase-reduced coenzyme complexes, perturbation of both adenine and dihydronicotinamide chromophores is evident. L-Malate binding, however, apparently produces only a perturbation of the adenine chromophore in such complexes. Since the coenzyme has been found to bind in an open conformation on the surface of the enzyme and the substrate analogs bind at or very near the dihydronicotinamide moiety binding site, protein conformational changes are implicated during ternary complex formation with D-malate which can effect the adenine chromophore at some distance from the substrate binding site.     

Pre-steady-state kinetic studies on the Glu171Gln active site mutant of adenosylcobalamin-dependent glutamate mutase

Glutamate-171 is involved in recognizing the amino group of the substrate in glutamate mutase. The effect of mutating this residue to glutamine on the ability of the enzyme to catalyze the homolysis of adenosylcobalamin has been investigated using UV-visible stopped-flow spectroscopy. Although Glu171 does not contact the coenzyme, the mutation results in the apparent rate constants for substrate-induced homolysis of the coenzyme that are slower by 7-fold and 13-fold with glutamate and methylaspartate, respectively, than those measured for the wild-type enzyme; furthermore, it weakens the binding of these substrates by approximately 50-fold and approximately 400-fold, respectively. These observations lend support to the idea that the enzyme may use substrate binding energy to accelerate homolysis of the coenzyme. The mutation also results in isotope effects on coenzyme homolysis that are much smaller than the very large effects observed when the wild-type enzyme is reacted with deuterated substrates. This observation is consistent with adenosylcobalamin homolysis being slowed relative to hydrogen abstraction from the substrate.     

D-glyceraldehyde-3-phosphate dehydrogenase subunit cooperativity studied using immobilized enzyme forms

Tetrameric D-glyceraldehyde-3-phosphate dehydrogenase (EC 1.2.1.12) isolated from rabbit skeletal muscle was covalently bound to CNBr-activated Sepharose 4B via a single subunit. Catalytically active immobilized dimer and monomeric forms of the enzyme were prepared after urea-induced dissociation of the tetramer. A study of the coenzyme-binding properties of matrix-bound tetrameric, dimeric and monomeric species has shown that: (1) an immobilized tetramer binds NAD+ with negative cooperativity, the dissociation constants being 0.085 microM for the first two coenzyme molecules and 1.3 microM for the third and the fourth one; (2) coenzyme binding to the dimeric enzyme form also displays negative cooperativity with Kd values of 0.032 microM and 1.1 microM for the first and second sites, respectively; (3) the binding of NAD+ to a monomer can occur with a dissociation constant of 1.6 microM which is close to the Kd value for low-affinity coenzyme binding sites of the tetrameric or dimeric enzyme forms. In the presence of NAD+ an immobilized monomer acquires a stability which is not inferior to that of a holotetramer. The catalytic properties of monomeric and tetrameric enzyme forms were compared and found to be different under certain conditions. Thus, the monomers of rabbit muscle D-glyceraldehyde-3-phosphate dehydrogenase displayed a hyperbolic kinetic saturation curve for NAD+, whereas the tetramers exhibited an intermediary plateau region corresponding to half-saturating concentrations of NAD+. At coenzyme concentrations below half-saturating a monomer is more active than a tetramer. This difference disappears at saturating concentrations of NAD+. Immobilized monomeric and tetrameric forms of D-glyceraldehyde-3-phosphate dehydrogenase from baker's yeast were also used to investigate subunit interactions in catalysis. The rate constant of inactivation due to modification of essential arginine residues in the holoenzyme decreased in the presence of glyceraldehyde 3-phosphate, probably as a result of conformational changes accompanying catalysis. This effect was similar for monomeric and tetrameric enzyme forms at saturating substrate concentrations, but different for the two enzyme species under conditions in which about one-half of the active centers remained unsaturated. Taken together, the results indicate that association of D-glyceraldehyde-3-phosphate dehydrogenase monomers into a tetramer imposes some constraints on the functioning of the active centers.(ABSTRACT TRUNCATED AT 400 WORDS)     

Electrostatic field effects of coenzymes on ligand binding to catalytic zinc in liver alcohol dehydrogenase

The synergism between coenzyme and anion binding to liver alcohol dehydrogenase has been examined by equilibrium measurements and transient-state kinetic methods to characterize electrostatic interactions of coenzymes with ligands which are bound to the catalytic zinc ion of the enzyme subunit. Inorganic anions typically exhibit an at least 200-fold higher affinity for the general anion-binding site than for catalytic zinc on complex formation with free enzyme. Acetate and SCN- interact more strongly with catalytic zinc in the enzyme X NAD+ complex than with the general anion-binding site in free enzyme. CN- shows no significant affinity for the general anion-binding site, but combines to catalytic zinc in the absence as well as the presence of coenzymes. Coordination of CN- to catalytic zinc weakens the binding of NADH by a factor of 50, and tightens the binding of NAD+ to approximately the same extent through interactions which do not include any contributions from covalent adduct formation between CN- and NAD+. These observations provide unambiguous information about the magnitude of electrostatic field effects of coenzymes on anion (e.g. hydroxyl ion) binding to catalytic zinc. They lead to the important inference that coenzyme binding must be strongly affected by ionization of zinc-bound water irrespective of the actual acidity of the latter group. It is concluded on such grounds that the much debated pH dependence of coenzyme binding to liver alcohol dehydrogenase must derive from ionization of zinc-bound water. The assumption that such is not the case leads to the inference that there is no detectable effect of ionization of zinc-bound water on coenzyme binding over the pH range 6-12, a possibility which is definitely excluded by the present results.     

The reaction of bovine glutamate dehydrogenase with periodate-oxidised ADP

1. The reactive analogue oADP produced by periodate oxidation of ADP has been studied as a potential affinity label for the enzyme bovine glutamate dehydrogenase, using circular dichroism (CD) difference spectroscopy to monitor specific binding. 2. The analogue binds stoichiometrically, rapidly and reversibly to the adenine nucleotide binding site with Kd approximately equal to 12 microM (20 degrees C, pH 7) with characteristic intensification of the adenine nucleotide CD at 260 nm. 3. This complex is unstable and decays with a half-life of about 1.5 h; the analogue then becomes attached as a Schiff base to a number of subsidiary sites, including the enzyme active site, with partial inactivation of the enzyme. 4. Depending upon initial concentration of oADP, the enzyme activity is progressively lost during the slow reaction; following borohydride reduction, up to four molecules of analogue are bound/subunit. 5. Protection against loss of enzyme activity is afforded by the coenzyme NAD+ plus glutarate or L-hydroxyglutarate (an effective inhibitor), or by glutarate alone, but not by NAD+ alone. 6. Spectroscopic and protection studies indicate that after the decay of the specific CD signal, the enzyme retains the capacity to bind ADP, but that this is progressively lost in parallel with decay of enzymic activity. 7. The results are consistent with proximity or functional interaction between the adenine nucleotide site and the coenzyme binding portion of the active site. 8. Thus oADP does not act as a true affinity label for the adenine nucleotide binding site, but the reaction subsequent to binding at that site shows some specificity directed towards the active site.     

Letter: L-3-hydroxyacyl coenzyme A dehydrogenase: crystallographic properties of the pig heart enzyme

Crystals of l-3-hydroxyacyl coenzyme A dehydrogenase from pig heart that are suitable for X-ray analysis have been prepared and characterized. The enzyme is a mitochondrial protein important in the beta oxidation of fatty acids. It is of special interest because it requires coenzyme A-related molecules for its catalytic activity. For one of the crystalline forms of the enzyme, the X-ray data tend to confirm chemical observations that the molecule is a dimer of identical subunits.     

The interaction of liver alcohol dehydrogenase with NADH as studied by differential protein denaturation.

Heat denaturation of horse liver alcohol dehydrogenase was followed in the presence of isobutyramide at various degrees of saturation of the binding sites by NADH. A study of the fluorescence enhancement which is observed when an excess of NADH is added to the partially denatured mixtures provides information regarding the relative concentrations of mono- and bioccupied enzyme molecules. This approach is of value in situations when the association constants for coenzyme are so large that the concentration of the free ligand is negligible. The results obtained indicate that the binding of NADH to liver alcohol dehydrogenase follows the statistically predicted distribution. At the same time evidence was obtained for interaction between the two subunits of the enzyme.     

Ligand-induced conformational changes within a hexameric Acyl-CoA thioesterase

Acyl-coenzyme A (acyl-CoA) thioesterases play a crucial role in the metabolism of activated fatty acids, coenzyme A, and other metabolic precursor molecules including arachidonic acid and palmitic acid. These enzymes hydrolyze coenzyme A from acyl-CoA esters to mediate a range of cellular functions including β-oxidation, lipid biosynthesis, and signal transduction. Here, we present the crystal structure of a hexameric hot-dog domain-containing acyl-CoA thioesterase from Bacillus halodurans in the apo-form and provide structural and comparative analyses to the coenzyme A-bound form to identify key conformational changes induced upon ligand binding. We observed dramatic ligand-induced changes at both the hot-dog dimer and the trimer-of-dimer interfaces; the dimer interfaces in the apo-structure differ by over 20% and decrease to about half the size in the ligand-bound state. We also assessed the specificity of the enzyme against a range of fatty acyl-CoA substrates and have identified a preference for short-chain fatty acyl-CoAs. Coenzyme A was shown both to negatively regulate enzyme activity, representing a direct inhibitory feedback, and consistent with the structural data, to destabilize the quaternary structure of the enzyme. Coenzyme A-induced conformational changes in the C-terminal helices of enzyme were assessed through mutational analysis and shown to play a role in regulating enzyme activity. The conformational changes are likely to be conserved from bacteria through to humans and provide a greater understanding, particularly at a structural level, of thioesterase function and regulation.