Steady-state kinetics of horse-liver alcohol dehydrogenase with a covalently bound coenzyme analogue

The steady-state kinetics of the enzyme modified by affinity labelling with NAD analogue, nicotinamide-N6-[N-(6-aminohexyl)carbamoylmethyl]-adenine dinucleotide, has been investigated using a recycling reaction with p-nitrosodimethylaniline and n-butanol as substrates and compared to the kinetics of native alcohol dehydrogenase. The modified enzyme obeys a ping-pong mechanism involving two inactive enzyme forms (enzyme-NAD and enzyme-NADH complexes in the 'open' conformations, the nicotinamide moieties of the coenzymes being out of the active center). The rate of p-nitrosodimethylaniline reduction in the reaction catalyzed by the modified enzyme is comparable to that observed in the presence of the native enzyme. On the other hand, the oxidation of butanol by the modified enzyme is essentially slower under our experimental conditions (pH 8.5). The measurements in the presence of specific alcohol dehydrogenase inhibitors competing with substrates and coenzymes (isobutyramide, pyrazole and AMP) revealed that the relative portion of the inactive 'open' form of the enzyme-NADH complex is negligible, whereas the 'open' form of the enzyme-NAD complex seems to represent a more significant portion (about 30%) under the conditions used.     

On the presence of a novel covalently bound oxidation-reduction cofactor,iron and labile sulfur in trimethylamine dehydrogenase

Trimethylamine dehydrogenase from a facultative methylotroph contains 4 g atoms each of Fe and S and an unknown, covalently bound, yellow coenzyme. The absorbance of the enzyme in the visible range (λmax=445 nm) is extensively bleached by dithionite. Reduction by substrate causes less extensive bleaching and the appearance of a three banded spectrum which may be representative of a free radical form. Denaturation liberates the FeS center(s) but not the organic coenzyme. The latter is covalently linked to the protein via an amino acid residue and is solubilized on proteolytic digestion in the form of the peptide. The coenzyme-peptide has been purified to a constant ratio of amino acid to coenzyme. The oxidized and reduced forms show maximal absorbance at 437 nm and 380 nm respectively. Based on dithionite titrations its molar absorbance at 437 nm is 12,300 in the oxidized and 4000 in the dithionite reduced form. The cofactor is very labile to photolysis giving rise to several products the predominant one of which shows fluorescence excitation and emission maxima at 394 and 500 nm, respectively. After cleavage of the hydrolyzable amino acids in HCl, the compound consumed 3 moles of periodate. Digestion with aminopeptidase M yields a compound with a single amino acid and ～1 mole of organic P present. Acid phosphatase, but not nucleotide pyrophosphatase affects its mobility. These findings suggest that the coenzyme-peptide is isolated in the form of a mononucleotide, containing a 5-carbon alcohol. The physical and chemical properties of the compound do not agree with those of known flavin or pyridoxine derivatives but are not incompatible with a covalently linked pteridine (lumazine) derivative, although no proof for such a structure is so far available.     

Identification of the covalently bound flavin of thiamin dehydrogenase.

Thiamin dehydrogenase, a flavoprotein isolated from an unidentified soil bacterium, contains 1 mol of covalently bound FAD/mol of enzyme. A flavin peptide, isolated from tryptic-chymotryptic digests of the enzyme and hydrolyzed to the FMN level, shows a pH-dependent fluorescence yield being maximal at pH 3.5 to 4.0 and decreasing over 90% at pH 7.5 with a pKa of 5.8. Acid hydrolysis of the peptide results in an aminoacylflavin which shows a pKa of fluorescence quenching of 5.2. Absorption and electron paramagnetic resonance spectral data show the covalent substituent to be at the 8alpha position of the flavin as is the case with all known enzymes containing covalently bound flavin. The aminoacylflavin gives a negative Pauly reaction but yields 1 mol of histidine on drastic acid hydrolysis thus showing an imidazole ring nitrogen as the 8alpha substituent of the flavin. The aminoacylflavin differs from synthetic 8alpha-[N(3)-histidyl]riboflavin or its acid-modified form in pKa of fluorescence quenching, in electrophoretic mobility, in being reduced by borohydride, and in being labile to storage, yielding 8-formylriboflavin. In all of these properties, however, the 8alpha-histidylriboflavin isolated from thiamin dehydrogenase is indistinguishable from 8alpha-[N(1)-histidyl]riboflavin. It is therefore concluded that the FAD moiety of thiamin dehydrogenase is covalently linked via the 8alpha-methylene group to the N(1) position of the imidazole ring of histidine.     

Human erythrocyte glucose 6-phosphate dehydrogenase. Content of bound coenzyme

A series of peptide analogs of luteinizing hormone releasing hormone (LH-RH), altered at position 6 and 10, was synthesized and evaluated $\text{in vivo}$ for the ability to induce ovulation in the diestrous rat and $\text{in vitro}$ for ability to release pituitary luteinizing hormone and follicle stimulating hormone. All the analogs with D-amino acid substitutions at position 6, even those with large bulky side chain, exhibited an amazingly high potency compared with the parent hormone, LH-RH. On the basis of the biological activities, structure-activity relationships in the central part of this molecule were discussed in detail.     

Optimizing the Michaelis complex of trimethylamine dehydrogenase: identification of interactions that perturb the ionization of substrate and facilitate catalysis with trimethylamine base.

Recent evidence from isotope studies supports the view that catalysis by trimethylamine dehydrogenase (TMADH) proceeds from a Michaelis complex involving trimethylamine base and not, as thought previously, trimethylammonium cation. In native TMADH reduction of the flavin by substrate (perdeuterated trimethylamine) is influenced by two ionizations in the Michaelis complex with pK(a) values of 6.5 and 8.4; maximal activity is realized in the alkaline region. The latter ionization has been attributed to residue His-172 and, more recently, the former to the ionization of substrate itself. In the Michaelis complex, the ionization of substrate (pK(a) approximately 6.5 for perdeuterated substrate) is perturbed by approximately -3.3 to -3.6 pH units compared with that of free trimethylamine (pK(a) = 9.8) and free perdeuterated trimethylamine (pK(a) = 10.1), respectively, thus stabilizing trimethylamine base by approximately 2 kJ mol(-1). We show, by targeted mutagenesis and stopped-flow studies that this reduction of the pK(a) is a consequence of electronic interaction with residues Tyr-60 and His-172, thus these two residues are key for optimizing catalysis in the physiological pH range. We also show that residue Tyr-174, the remaining ionizable group in the active site that we have not targeted previously by mutagenesis, is not implicated in the pH dependence of flavin reduction. Formation of a Michaelis complex with trimethylamine base is consistent with a mechanism of amine oxidation that we advanced in our previous computational and kinetic studies which involves nucleophilic attack by the substrate nitrogen atom on the electrophilic C4a atom of the flavin isoalloxazine ring. Stabilization of trimethylamine base in the Michaelis complex over that in free solution is key to optimizing catalysis at physiological pH in TMADH, and may be of general importance in the mechanism of other amine dehydrogenases that require the unprotonated form of the substrate for catalysis.     

Conformation of coenzyme fragments when bound to lactate dehydrogenase

The conformations of adenosine, 5′-AMP and 5′-ADP when bound to dogfish M₄ lactate dehydrogenase at pH 7.8 or greater have been determined at 2.8 Å resolution to investigate the events on coenzyme binding. The coenzyme fragments AMP and ADP induce a conformational change in lactate dehydrogenase at pH values less than 6.0 in the same way as do NAD⁺, NADH or ADPR at any pH value. The structure of NAD⁺ when bound to lactate dehydrogenase had previously been determined at 5.0 Å resolution. The structures of the bound adenosine, AMP, ADP and NAD⁺ are compared with the preliminary structure of NAD in a 3.0 Å resolution map of the ternary complex LDH-NAD—pyruvate. Small but significant changes in the binding of the phosphates could be important in the folding of the protein loop over the substrate binding pocket.     

Identification of a covalently bound flavoprotein in rat liver mitochondria with sarcosine dehydrogenase.

A covalently bound flavoprotein having highest molecular weight among four covalently bound flavoproteins found in rat liver mitochondria was partially purified and characterized. Its subunit molecular weight was estimated to be 94,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Its absorption maxima were observed at 353 and 460 nm. Since this flavoprotein was reduced by either sarcosine or dimethylglycine and oxidized by phenazine methosulfate, it was identified with sarcosine dehydrogenase.     

Microcoulometric analysis of trimethylamine dehydrogenase.

Trimethylamine dehydrogenase, which contains one covalently bound 6-S-cysteinyl-FMN and one Fe4S4 cluster per subunit of molecular mass 83,000 Da, was purified to homogeneity from the methylotrophic bacterium W3A1. Microcoulometry at pH 7 in 50 mM-Mops buffer containing 0.1 mM-EDTA and 0.1 M-KCl revealed that the native enzyme required the addition of 3 reducing equivalents per subunit for complete reduction. In contrast, under identical conditions the phenylhydrazine-inhibited enzyme required the addition of 0.9 reducing equivalent per subunit with a midpoint potential of +110 mV. Least-squares analysis of the microcoulometric data obtained for the native enzyme, assuming uptake of 1 electron by Fe4S4 and 2 electrons by FMN, indicated midpoint potentials of +44 mV and +36 mV for the FMN/FMN.- and FMN.-/FMNH2 couples respectively and +102 mV for reduction of the Fe4S4 cluster.     

Succinate dehydrogenase mutants of Bacillus subtilis lacking covalently bound flavin in the flavoprotein subunit

Succinate dehydrogenase consists of two unequal subunits; Fp and Ip. An FAD group is covalently linked to a histidyl residue in the Fp subunit. The mechanism by which flavin is attached to protein is not known. Covalently bound flavin was studied in wild-type and succinate-dehydrogenase-negative Bacillus subtilis. The Fp subunit of succinate dehydrogenase was found to be the only (major) flavinylated protein in the cell. Mutants lacking covalently bound flavin and still containing the Fp polypeptide are described. It is shown that the flavin is not essential for assembly and membrane binding of succinate dehydrogenase in B. subtilis.     

Thermodynamic influences on the fidelity of iron-sulphur cluster formation in proteins.

In an organism, two thermodynamic factors are important in ensuring that homometallic [4Fe-4S] cubane clusters are formed in preference to clusters containing heterometals such as Zn or Cu. These are the electronic resonance stabilisation, which boosts the binding of Fe(II) within an Fe-S cluster relative to its normally low position in the Irving-Williams order, and attenuation of the cytoplasmic concentrations of competing metals such as Zn or Cu by specific ligands.     

Participation of histidine-51 in catalysis by horse liver alcohol dehydrogenase

Histidine-51 in horse liver alcohol dehydrogenase (ADH) is part of a hydrogen-bonded system that appears to facilitate deprotonation of the hydroxyl group of water or alcohol ligated to the catalytic zinc. The contribution of His-51 to catalysis was studied by characterizing ADH with His-51 substituted with Gln (H51Q). The steady-state kinetic constants for ethanol oxidation and acetaldehyde reduction at pH 8 are similar for wild-type and H51Q enzymes. In contrast, the H51Q substitution significantly shifts the pH dependencies for steady-state and transient reactions and decreases by 11-fold the rate constant for the transient oxidation of ethanol at pH 8. Modest substrate deuterium isotope effects indicate that hydride transfer only partially limits the transient oxidation and turnover. Transient data show that the H51Q substitution significantly decreases the rate of isomerization of the enzyme-NAD(+) complex and becomes a limiting step for ethanol oxidation. Isomerization of the enzyme-NAD(+) complex is rate limiting for acetaldehyde reduction catalyzed by the wild-type enzyme, but release of alcohol is limiting for the H51Q enzyme. X-ray crystallography of doubly substituted His51Gln:Lys228Arg ADH complexed with NAD(+) and 2,3- or 2,4-difluorobenzyl alcohol shows that Gln-51 isosterically replaces histidine in interactions with the nicotinamide ribose of the coenzyme and that Arg-228 interacts with the adenosine monophosphate of the coenzyme without affecting the protein conformation. The difluorobenzyl alcohols bind in one conformation. His-51 participates in, but is not essential for, proton transfers in the mechanism.     

Magnetic-resonance studies of the geometry of bound substrate, coenzyme and activator on bovine-liver glutamate dehydrogenase.

ADP and ATP with a spin-label linked to the terminal phosphate are activators of glutamate dehydrogenase and bind to the same site as the activator ADP. There is hardly any interaction with the coenzyme site. Glutamate dehydrogenase can be modified with a ketone spin-label at a site in the active centre[Andree and Zantema, (1978) Biochemistry, 17, 778--783]. The spin-labelled activators interact with ketone spin-labelled glutamate dehydrogenase in the same way as with native glutamate dehydrogenase relative to the activator site, but show a stronger binding to the coenzyme site. Upon binding to the coenzyme site a spin-spin interaction between the ketone spin-label and the spin-labelled activators is observed. Nuclear magnetic resonance studies of the linewidth of 2-oxoglutarate and NADP+ bound to their functional sites on glutamate dehydrogenase without and with spin-labels result in distances between the ligand nuclei and the spin-labels. The results show that NADP+ binds in an open conformation consistent with the conformation in other dehydrogenases. The activator ADP binds in the neighbourhood of the active centre, but with very little or no overlap with the coenzyme site.     

Crystal structure of E.coli alcohol dehydrogenase YqhD: evidence of a covalently modified NADP coenzyme

In the course of a structural genomics program aiming at solving the structures of Escherichia coli open reading frame (ORF) products of unknown function, we have determined the structure of YqhD at 2.0A resolution using the single wavelength anomalous diffraction method at the Pt edge. The crystal structure of YqhD reveals that it is an NADP-dependent dehydrogenase, a result confirmed by activity measurements with several alcohols. The current interpretation of our findings is that YqhD is an alcohol dehydrogenase (ADH) with preference for alcohols longer than C(3). YqhD is a dimer of 2x387 residues, each monomer being composed of two domains, a Rossmann-type fold and an alpha-helical domain. The crystals contain two dimers in the asymmetric unit. While one of the dimers contains a cofactor in both subunits, only one of the subunits in the second dimer contains it, making it possible to compare bound and unbound active sites. The active site contains a Zn atom, as verified by EXAFS on the crystals. The electron density maps of NADP revealed modifications of the nicotinamide ring by oxygen atoms at positions 5 and 6. Further analysis by electrospray mass spectrometry and comparison with the mass spectra of NADP and NADPH revealed the nature of the modification and the incorporation of two hydroxyl moieties at the 5 and 6 position in the nicotinamide ring, yielding NADPH(OH)(2). These modifications might be due to oxygen stress on an enzyme, which would functionally work under anaerobic conditions.