Fluorescence properties of reduced thionicotinamide--adenine dinucleotide and of its complex with octopine dehydrogenase.

Reduced 3-thionicotinamide--adenine dinucleotide (sNADH) is shown to be fluorescent, with an emission maximum at 510 nm when excited in the region of the absorption maximum (398 nm), and with a very low quantum yield, (3.4 +/- 0.5) x 10(-4). The interaction between sNADH and octopine dehydrogenase was investigated by ultraviolet-difference spectroscopy and fluorescence. Some surprising fluorescence features were found when sNADH was bound to the enzyme in the presence of D-octopine, as follows. (a) There is an unusually high enhancement of the dinucleotide fluorescence (by at least a factor of 100) attended by a 40-nm blue shift of the emission maximum. (b) The protein fluorescence is quenched almost completely. (c) The bound coenzyme analog undergoes a photoreaction, which proceeds differently from that occurring the free form. These features appear to be unique to the octopine.sNADH complex, as for example they are not present when sNADH is bound to horse liver alcohol dehydrogenase, or when NADH is bound to octopine dehydrogenase. The possible origin of these fluorescence features is discussed. Binding and kinetic studies were carried out with sNAD and sNADH. It was found that sNAD neither binds nor acts kinetically as a coenzyme. sNADH exhibits relatively good binding, with Km and Ki values close to those of the natural coenzyme, but the turnover number is 460 times smaller than that with NADH. The kinetic consequences of these findings are discussed. The sNADH dissociation constants were determined as a function of temperature, and appear to be practically temperature-independent in the range 10--40 degrees C. It seems thus, in agreement with previous studies, that the interaction between octopine dehydrogenase and coenzymes proceeds athermically, regardless of the structure, affinity, and chemical reactivity of the coenzyme. The possible biological and chemical meaning of this finding is discussed.     

Circular dichroic properties and conformation of thionicotinamide dinucleotides.

The spectroscopic properties of the 3-thioamide analogues of coenzymes NAD and NADH (sNAD and sNADH) have been investigated in order to obtain information about their conformational properties. In particular, ultraviolet absorption and circular dichroism properties of solutions in phosphate buffer pH 7 and ethanol were studied. Also equimolar mixtures of AMP and sNMN(H), obtained by cleaving the coenzymes with phosphodiesterase, were investigated using the same solvents. The appearance of a couplet around 260 nm, which is not present for the mixture of sNMN and AMP, suggests a stacking interaction of the two aromatic moieties in sNAD. This conclusion is further substantiated by a hyperchroism of the ultraviolet absorption band in the 260-nm region in both sNAD and sNADH. The comparison of the ultraviolet and circular dichroic properties of intact and cleaved coenzymes in the different solvent systems makes it possible to single out the bands which are more sensitive to conformation changes (i.e. to open-stacking equilibrium) and those which are sensitive to solvent effects only.     

Spectroscopic investigation of binary and ternary coenzyme complexes of yeast alcohol dehydrogenase.

Corrected fluorescence properties of yeast alcohol dehydrogenase and its coenzyme complexes have been investigated as a function of temperature. Dissociation constants have been obtained for binary and ternary complexes of NAD and NADH by following the enhancement of NADH fluorescence or the quenching of the protein fluorescence. It is found that the presence of pyrazole increases the affinity of NAD to the enzyme approximately 100-fold. The formation of the ternary enzyme - NAD - pyrazole complex is accompanied by a large change in the ultraviolet absorption properties, with a new band in the 290-nm region. Significant optical changes also accompany the formation of the ternary enzyme-NADH-acetamide complex. The possible origin for the quenching of the protein fluorescence upon coenzyme binding is discussed, and it is suggested that a coenzyme-induced conformational change can cause it. Thermodynamic parameters associated with NAD and NADH binding have been evaluated on the basis of the change of the dissociation constants with temperature. Optical and thermodynamic properties of binary and ternary complexes of yeast alcohol dehydrogenase are compared with the analogous properties of horse liver alcohol dehydrogenase.     

Selectivity in the binding of NAD(P)+ analogues to NAD- and NADP-dependent pig heart isocitrate dehydrogenases. A nuclear magnetic resonance study.

The coenzyme selectivity of pig heart NAD-dependent and NADP-dependent isocitrate dehydrogenase has been investigated by nuclear magnetic resonance through the use of coenzyme analogues. For both isocitrate dehydrogenases, more than 10-fold lower maximal activity is observed with thionicotinamide adenine dinucleotide [sNAD(P)+] than with NAD(P)+ or acetylpyridine adenine dinucleotide [acNAD-(P)+] as coenzyme. Nuclear Overhauser effect measurements failed to reveal any differences in the adenine-ribose conformations among the enzyme-bound analogues. The 2'-phosphate resonance of the enzyme-bound NADP+ analogues showed the same change in chemical shift observed for the natural coenzyme and revealed the same lack of pH dependence in the range from pH 5.4 to 8.2. NADP-dependent isocitrate dehydrogenase exhibits only small differences in Michaelis constants for the coenzymes with various nicotinamide substituents, reflecting a predominant role for the adenosine moiety in binding. The conformation of the bound nicotinamide-ribose of the natural coenzymes was appreciably different from that of the coenzyme, sNAD(P)+, which shows low catalytic activity. For both isocitrate dehydrogenases, sNAD(P)+ bound to the enzymes exhibits a mixture of syn and anti conformations while only the anti conformation can be detected for NAD(P)+. Chemical shifts of NAD(P)+ enriched with 13C in the carboxamide indicate that interaction of this group with the enzymes may play a role in positioning the nicotinamide ring to participate in catalysis. Our results suggest that, although interaction of the nicotinamide moiety with the enzymes contributes relatively little to the energy of interaction in the binary complex, the enzymes must correctly position this group for the catalytic event.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Mechanism of inhibition of Ca2+-transport activity of sarcoplasmic reticulum Ca2+-ATPase by anisodamine

The mechanism of inhibition of Ca2+-transport activity of rabbit sarcoplasmic reticulum Ca 2+-ATPase (SERCA) by anisodamine (a drug isolated from a medicinal herb Hyoscyamuns niger L) was investigated by using ANS (1-anilino-8-naphthalenesulfonate) fluorescence probe, intrinsic fluorescence quenching and Ca 2+-transport activity assays. The number of ANS binding sites for apo Ca2+-ATPase was determined as 8, using a multiple-identical binding site model. Both anisodamine and Ca2+ at millimolar level enhanced the ANS binding fluorescence intensities. Only anisodamine increased the number of ANS molecules bound by SERCA from 8 to 14. The dissociation constants of ANS to the enzyme without any ligand, with 30 mM anisodamine and with 15 mM Ca 2 were found to be 53.0 microM, 85.0 microM and 50.1 microM, respectively. Both anisodamine and Ca2+ enhanced the ANS binding fluorescenc with apparent dissociation constants of 7.6 mM and 2.3 mM, respectively, at a constant concentration of the enzyme. Binding of anisodamine significantly decreased the binding capacity of Ca2+ with the dissociation constant of 9.5 mM, but binding of Ca2+ had no obvious effect on binding of anisodamine. Intrinsic fluorescence quenching and Ca2+-transport activity assays gave the dissociation constants of anisodamine to SERCA as 9.7 and 5.4 mM, respectively, which were consistent with those obtained from ANS-binding fluorescence changes during titration of SERCA with anisodamine and anisodamine + 15 mM Ca2+, respectively. The results suggest that anisodamine regulates Ca2+-transport activity of the enzyme, by stabilizing the trans-membrane domain in an expanded, inactive conformation, at least at its annular ring region.     

UDP-galactose 4-epimerase from Kluyveromyces fragilis: equilibrium unfolding studies

UDP-galactose 4-epimerase from yeast (Kluyveromyces fragilis) is a homodimer of total molecular mass 150 kDa having possibly one mole of NAD/dimer acting as a cofactor. The molecule could be dissociated and denatured by 8 M urea at pH 7.0 and could be functionally reconstituted after dilution with buffer having extraneous NAD. The unfolded and refolded equilibrium intermediates of the enzyme between 0-8 M urea have been characterized in terms of catalytic activity, NADH like characteristic coenzyme fluorescence, interaction with extrinsic fluorescence probe 1-anilino 8-naphthelene sulphonic acid (ANS), far UV circular dichroism spectra, fluorescence emission spectra of aromatic residues and subunit dissociation. While denaturation monitored by parameters associated with active site region e.g. inactivation and coenzyme fluorescence, were found to be cooperative having delta G between -8.8 to -4.4 kcals/mole, the overall denaturation process in terms of secondary and tertiary structure was however continuous without having a transition point. At 3 M urea a stable dimeric apoenzyme was formed having 65% of native secondary structure which was dissociated to monomer at 6 M urea with 12% of the said structure. The unfolding and refolding pathways involved identical structures except near the final stage of refolding where catalytic activity reappeared.     

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.     

A spectroscopic and conformational study of pertussis toxin

The conformation of native pertussis toxin has been investigated by secondary structure prediction and by circular dichroism, fluorescence and second-derivative ultraviolet absorption spectroscopy. The far-ultraviolet circular dichroic spectrum is characteristic of a protein of high beta-sheet and low alpha-helix content. This is also shown by an analysis of the circular dichroic spectrum with the Contin programme which indicates that the toxin possesses 53% beta-sheet, 10% alpha-helix and 37% beta-turn/loop secondary structure. Second-derivative ultraviolet absorption spectroscopy suggests that 34 tyrosine residues are solvent-exposed and quenching of tryptophan fluorescence emission has shown that 4 tryptophan residues are accessible to iodide ions. One of these tryptophans appears to be in close proximity to a positively charged side-chain, since only 3 tryptophans are accessible to caesium ion fluorescence quenching. When excited at 280 nm, the emission spectrum contains a significant contribution from tyrosine fluorescence, which may be a consequence of the high proportion (55%) of surface-exposed tyrosines. No changes in the circular dichroic spectra of the toxin were found in the presence of the substrate NAD. However, NAD did quench both tyrosine and tryptophan fluorescence emission but did not change the shape of the emission spectrum, or the accessibility of the tryptophans to either the ionic fluorescence quenchers or the neutral quencher acrylamide.     

An ultraviolet resonance Raman study of dehydrogenase enzymes and their interactions with coenzymes and substrates

Ultraviolet resonance Raman (UVRR) spectra, with 260-nm excitation, are reported for oxidized and reduced nicotinamide adenine dinucleotides (NAD+ and NADH, respectively). Corresponding spectra are reported for these coenzymes when bound to the enzymes glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and liver and yeast alcohol dehydrogenases (LADH and YADH). The observed differences between the coenzyme spectra are interpreted in terms of conformation, hydrogen bonding, and general environment polarity differences between bound and free coenzymes and between coenzymes bound to different enzymes. The possibility of adenine protonation is discussed. UVRR spectra with 220-nm excitation also are reported for holo- and apo-GAPDH (GAPDH-NAD+ and GAPDH alone, respectively). In contrast with the 260-nm spectra, these show only bands due to vibrations of aromatic amino acid residues of the protein. The binding of coenzyme to GAPDH has no significant effect on the aromatic amino acid bands observed. This result is discussed in the light of the known structural change of GAPDH on binding coenzyme. Finally, UVRR spectra with 240-nm excitation are reported for GAPDH and an enzyme-substrate intermediate of GAPDH. Perturbations are reported for tyrosine and tryptophan bands on forming the acyl enzyme.     

Spectral studies on two genetic forms of the human serum proteinase inhibitor, alpha-1-antitrypsin.

alpha-1-antitrypsin, the major inhibitor of proteolytic enzymes in human serum, was isolated from normal individuals (protease inhibitor type MM) and from those with an inherited deficiency (protease inhibitor type ZZ) of circulatory protein. The two proteins were compared by circular dichroism spectroscopy, and by fluorescence quenching experiments using anionic (I-), and neutral (acrylamide) probes. Both proteins share a similar secondary structure, i.e. approximately 45--50% alpha-helix and 15--20% beta-structure. Evidence was accumulated to show that the microenvironment in the vicinity of the three tryptophanyl residues is altered in Z form as compared to the M form as shown by (a) the absence of the positive dichroic band in the region 290--300 nm of the circular dichroism spectra, (b) a greater than 50% increase in quantum yield in the tryptophanyl fluorescence emission spectra, (c) an increased accessibility of tryptophan to quenching by iodide, and (d) acrylamide quenching experiments which indicate that all tryptophanyl residues in the Z protein are quenched equally or that quenching is dominated by a single residue, while in the M protein, heterogeneous quenching occurs. The potential significance of these findings in terms of alpha-1-antitrypsin deficiency state are discussed.     

The allosteric mechanism of bovine liver glutamate dehydrogenase. Evidence from circular-dichroism studies for a conformational change in the ternary complex enzyme-(oxidized nicotinamide-adenine dinucleotide)-glutarate.

1. Computer averaging of multiple scans was used to refine the circular dichroism spectrum of bovine liver glutamate dehydrogenase, revealing well-defined structure in the aromatic region. 2. The circular dichroism of NAD+ bound to glutamate dehydrogenase is strongly negative at 260nm, probably owing to immobilization of the adenosine moiety. Loss of the characteristic adenine-nicotinamide interaction suggests that the coenzyme is bound in an unstacked conformation. 3. Glutarate and succinate, substrate analogues that are both inhibitors competitive with glutamate, do not significantly perturb the circular-dichroism spectrum of the enzyme in the absence of NAD+. 4. In the presence of NAD+, 150nM-succinate decreases the negative circular dichroism corresponding to bound coenzyme, but does not affect the protein circular dichroism. However, ISOmM-glutarate causes profound alternations of the circular-dichroism spectra of the bound NAD+ and of the enzyme, indicative of a protein conformational change. This direct evidence of conformational change specifically promoted by C5 dicarboxylates confirms the previous inference from protection studies. 5. The conformational change is discussed in relation to the allosteric mechanism of glutamate dehydrogenase.     

Interaction of the fluorescent analogue stearoyl-(1,N6)-etheno coenzyme A with chicken liver acetyl coenzyme A carboxylase

The interaction of stearoyl-(1,N6)-etheno coenzyme A (stearoyl-epsilon-CoA) with acetyl coenzyme A carboxylase was investigated by using fluorescence spectroscopy. The fluorescence emission of stearoyl-epsilon-CoA was partially quenched by acetyl coenzyme A carboxylase. Analysis of the data for dissociation constant (KD) and the stoichiometry of the interaction (n) gave values of 5.06 nM and 1.2, respectively, at pH 7.6 in 50 mM Tris-HCl and 25 degrees C. The KD value is comparable to the inhibition constant (Ki) obtained previously by others for the inhibition of rat liver acetyl coenzyme A carboxylase by long chain fatty acyl-CoAs. Citrate (which is known to polymerize and thus activate carboxylase) caused a partial quenching of the protein fluorescence of carboxylase, presumably due to polymerization of the enzyme. The quenching of the stearoyl-epsilon-CoA fluorescence caused by carboxylase as well as the inhibition of carboxylase activity by stearoyl-epsilon-CoA was reversed by citrate, but only in the presence of 6-O-methylglucose polysaccharide which forms a stable complex with fatty acyl-CoA. This shows that the stearoyl-epsilon-CoA bound to the enzyme is displaced by citrate only in the presence of an acceptor of fatty acyl-CoA. These results support the reciprocal relationship of citrate and fatty acyl-CoA in the regulation of acetyl coenzyme A carboxylase.     

Accessibility of adenine binding sites in dehydrogenases to small molecules studied by fluorescence quenching.

Quenching of the fluorescence of ethenoadenine derivatives by iodide ions and by methionine was studied in solution and when the nucleotides were bound to several dehydrogenases. The fluorescence of epsilonADPR in neutral aqueous solution is dynamically quenched by both quenching agents. The quenching of free epsilonNAD+ by methionine was found to be predominantly static and was satisfactorily described to result from complex formation between quencher and dinucleotide. The rat constant for quenching by iodide of epsilonNAD+ in the ternary complex with LADH and pyrazole is comparable to that of free epsilonADPR or epsilonADP. it is concluded that the bound epsilon-adenine ring is partially exposed to the solvent. The opening, to the solvent, of the adenine binding site is not large enough to allow free methionine diffusion since the rate constant for quenching of bound coenzyme by this quenching agent is relatively small. The difference between the rate constants for quenching of free and enzyme bound nucleotide was used to evaluate the binding constants of epsilonADPR to GPDH, epsilonNAD+ to LDH, and oxalate to the LDH:epsilonNAD+ complex. This technique may prove to be particularly useful when the binding of a fluorescent ligand to a protein is not accompanied by significant changes in its fluorescence.     

Reversible dissociation and unfolding of aspartate aminotransferase from Escherichia coli: characterization of a monomeric intermediate

The unfolding and dissociation of the dimeric enzyme aspartate aminotransferase (D) from Escherichia coli by guanidine hydrochloride have been investigated at equilibrium. The overall process was reversible, as judged from almost complete recovery of enzymic activity after dialysis of 0.7 mg of denatured protein/mL against buffer. Unfolding and dissociation were monitored by circular dichroism and fluorescence spectroscopy and occurred in three separate phases: D in equilibrium 2M in equilibrium 2M* in equilibrium 2U. The first transition at about 0.5 M guanidine hydrochloride coincided with loss of enzyme activity. It was displaced toward higher denaturant concentrations by the presence of either pyridoxal 5'-phosphate or pyridoxamine 5'-phosphate and toward lower denaturant concentrations by decreasing the protein concentration. Therefore, bound coenzyme stabilizes the dimeric state, and the monomer (M) is inactive because the shared active sites are destroyed by dissociation of the dimer. M was converted to M* and then to the fully unfolded monomer (U) in two subsequent transitions. M* was stable between 0.9 and 1.1 M guanidine hydrochloride and had the hydrodynamic radius, circular dichroism, and fluorescence of a monomeric, compact "molten globule" state.     

Metal stoichiometry, coenzyme binding, and zinc and cobalt enchange in highly purified yeast alcohol dehydrogenase.

Yeast alcohol dehydrogenase, purified from baker's yeast under conditions which exclude contamination by extraneous metal ions, is homogeneous by analytical ultracentrifugation and disc gel electrophoresis in the presence of sodium dodecyl sulfate. The enzyme has a molecular weight of 149,000 as determined by ultracentrifugation time-lapse photography and exhibits specific activities of 430 to 480 U/mg. Zinc analysis by three independent, highly sensitive methods, i.e., atomic absorption spectrometry, atomic fluorescence spectrometry, and microwave-induced plasma emission spectrometry, demonstrates 4 g-atom of catalytically essential Zn per mole of enzyme. No other metal atoms are present in stoichiometrically significant quantities as assessed by emission spectrography. The Stoichiometry of coenzyme binding, 4 mol of NADH/mol of enzyme, is identical to that of zinc, consistent with one coenzyme binding site and one zinc atom per enzyme subunit. Conditions for exchange of the four catalytically essential zinc atoms with ⁶⁵Zn have been developed. These atoms exchange identically under all conditions examined. The resultant radiolabeled enzyme, l(YADH)⁶⁵Zn₄], has the same metal content, specific enzymatic activity, and coenzyme binding properties as the native enzyme. The ⁶⁵Zn of this enzyme serves to monitor the extent and site specificity of cobalt replacement. The fully cobalt-substituted enzyme, [(YADH)Co₄], has a specific activity of 80 U/mg, 17% that of the Zn enzyme, and exhibits absorption and circular dichroic spectra which are consistent with coordination by one or more sulfur ligands in a distorted tetrahedral geometry.     

The binding of nicotinamide-adenine dimucleotide to glyceraldehyde 3-phosphate dehydrogenase from Bacillus stearothermophilus.

The binding of NAD+ to glyceraldehyde 3-phosphate dehydrogenase (EC 1.2.1.12) from Bacillus stearothermophilus has been studied by measurement of protein fluorescence quenching. Slight negative co-operativity was observed in the binding of the third and fourth coenzyme molecules to the tetrameric enzyme. The first two coenzyme molecules were tightly bound. In this respect the enzyme resembles that from sturgeon muscle rather than that from yeast.     

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.     

Relationship between fluorescence and conformation of epsilonNAD+ bound to dehydrogenases.

This work reports on the interaction of the fluorescent nicotinamide 1,N6-ethenoadenine dinucleotide (epsilonNAD+) with horse liver alcohol dehydrogenase, octopine dehydrogenase, and glyceraldehyde-3-phosphate dehydrogenase from different sources (yeast, lobster muscle, and rabbit muscle). The coenzyme fluorescence is enhanced by a factor of 10-13 in all systems investigated. It is shown that this enhancement cannot be due to changes in the polarity of the environment upon binding, and that it must be rather ascribed to structural properties of the bound coenzyme. Although dynamic factors could also be important for inducing changes in the quantum yield of epsilonNAD+ fluorescence, the close similarity of the fluorescence enhancement factor in all cases investigated indicates that the conformation of bound coenzyme is rather invariant in the different enzyme systems and overwhelmingly shifted toward an open form. Dissociation constants for epsilonNAD+-dehydrogenases complexes can be determined by monitoring the coenzyme fluorescence enhancement or the protein fluorescence quenching. In the case of yeast glyceraldehyde-3-phosphate dehydrogenase at pH 7.0 and t = 20 degrees the binding plots obtained by the two methods are coincident, and show no cooperativity. The affinity of epsilonNAD+ is generally lower than that of NAD+, although epsilonNAD+ maintains most of the binding characteristics of NAD+. For example, it forms a tight complex with horse liver alcohol dehydrogenase and pyrazole, and with octopine dehydrogenase saturated by L-arginine and pyruvate. One major difference in the binding behavior of NAD+ and epsilonNAD+ seems to be present in the muscle glyceraldehyde-3-phosphate dehydrogenase. In fact, no difference was found for epsilon NAD+ between the affinities of the third and fourth binding sites. The results and implications of this work are compared with those obtained recently by other authors.     

Metal ion binding to alpha-lactalbumin species

A strong cation (calcium) binding site has been demonstrated to exist in several alpha-lactalbumin species; bovine, goat, human, and guinea pig. A metal ion induced conformational change occurs, resulting in a unique (10-14-nm) blue shift and relative quenching of Trp fluorescence for all species. Calcium ion binding to the alpha-lactalbumins yielded dissociation constants (Kdiss consistently in the 10(-10)--10(-12) M range, while Mn(II) binding was in the 20-30 microM range. Independent determinations of these cation binding equilibria were made by ESR measurements of free unliganded Mn(II) in titrations with the bovine species. One strong site (Kdiss = 30.5 microM) was found, which correlated directly with the fluorescence-associated cation binding, plus three weaker sites (Kdiss = 1.1, 5.0, and 5.0 mM, respectively). Several lanthanides as well as Mg(II) were found to displace Mn(II) from the strong site on bovine alpha-lactalbumin (as monitored by ESR) and to cause the identical fluorescence changes as found for Ca(II) and Mn(II) above. The importance of measuring these equilibria by both fluorescence and ESR was borne out by demonstrating the potential errors in estimating dissociation equilibria by the fluorescence method alone. Also, the errors in estimating Kdiss for samples containing partially metal bound apo-alpha-lactalbumin are described as well as rapid, sensitive methods for estimating the extent of metal-free protein and correctly accounting for residual bound metal in equilibrium calculations.