Your search keyword '"Aldehyde Dehydrogenase chemistry"' showing total 24 results

1. Contribution of a C-Terminal Extension to the Substrate Affinity and Oligomeric Stability of Aldehyde Dehydrogenase from Thermus thermophilus HB27.

Author

Brytan W, Shortall K, Duarte F, Soulimane T, and Padrela L

Subjects

Substrate Specificity, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins genetics, Protein Multimerization, Kinetics, Catalytic Domain, Amino Acid Sequence, Thermus thermophilus enzymology, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase metabolism, Aldehyde Dehydrogenase genetics, Enzyme Stability

Abstract

Aldehyde dehydrogenase enzymes (ALDHs) are widely studied for their roles in disease propagation and cell metabolism. Their use in biocatalysis applications, for the conversion of aldehydes to carboxylic acids, has also been recognized. Understanding the structural features and functions of both prokaryotic and eukaryotic ALDHs is key to uncovering novel applications of the enzyme and probing its role in disease propagation. The thermostable enzyme ALDH Tt originating from Thermus thermophilus , strain HB27, possesses a unique extension of its C-terminus, which has been evolutionarily excluded from mesophilic counterparts and other thermophilic enzymes in the same genus. In this work, the thermophilic adaptation is studied by the expression and optimized purification of mutant ALDH Tt- 508, with a 22-amino acid truncation of the C-terminus. The mutant shows increased activity throughout production compared to native ALDH Tt , indicating an opening of the active site upon C-terminus truncation and giving rationale into the evolutionary exclusion of the C-terminal extension from similar thermophilic and mesophilic ALDH proteins. Additionally, the C-terminus is shown to play a role in controlling substrate specificity of native ALDH, particularly in excluding catalysis of certain large and certain aromatic ortho-substituted aldehydes, as well as modulating the protein's pH tolerance by increasing surface charge. Dynamic light scattering and size-exclusion HPLC methods are used to show the role of the C-terminus in ALDH Tt oligomeric stability at the cost of catalytic efficiency. Studying the aggregation rate of ALDH Tt with and without a C-terminal extension leads to the conclusion that ALDH Tt follows a monomolecular reaction aggregation mechanism.

Published

2024

2. Importance of the C-Terminus of Aldehyde Dehydrogenase 7A1 for Oligomerization and Catalytic Activity.

Author

Korasick DA, Wyatt JW, Luo M, Laciak AR, Ruddraraju K, Gates KS, Henzl MT, and Tanner JJ

Subjects

2-Aminoadipic Acid metabolism, Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase metabolism, Epilepsy genetics, Humans, Kinetics, Lysine metabolism, Protein Structure, Quaternary, Substrate Specificity, Aldehyde Dehydrogenase chemistry, Biocatalysis, Protein Multimerization genetics

Abstract

Aldehyde dehydrogenase 7A1 (ALDH7A1) catalyzes the terminal step of lysine catabolism, the NAD + -dependent oxidation of α-aminoadipate semialdehyde to α-aminoadipate. Structures of ALDH7A1 reveal the C-terminus is a gate that opens and closes in response to the binding of α-aminoadipate. In the closed state, the C-terminus of one protomer stabilizes the active site of the neighboring protomer in the dimer-of-dimers tetramer. Specifically, Ala505 and Gln506 interact with the conserved aldehyde anchor loop structure in the closed state. The apparent involvement of these residues in catalysis is significant because they are replaced by Pro505 and Lys506 in a genetic deletion (c.1512delG) that causes pyridoxine-dependent epilepsy. Inspired by the c.1512delG defect, we generated variant proteins harboring either A505P, Q506K, or both mutations (A505P/Q506K). Additionally, a C-terminal truncation mutant lacking the last eight residues was prepared. The catalytic behaviors of the variants were examined in steady-state kinetic assays, and their quaternary structures were examined by analytical ultracentrifugation. The mutant enzymes exhibit a profound kinetic defect characterized by markedly elevated Michaelis constants for α-aminoadipate semialdehyde, suggesting that the mutated residues are important for substrate binding. Furthermore, analyses of the in-solution oligomeric states revealed that the mutant enzymes are defective in tetramer formation. Overall, these results suggest that the C-terminus of ALDH7A1 is crucial for the maintenance of both the oligomeric state and the catalytic activity.

Published

2017

3. Structural and Kinetic Properties of the Aldehyde Dehydrogenase NahF, a Broad Substrate Specificity Enzyme for Aldehyde Oxidation.

Author

Coitinho JB, Pereira MS, Costa DM, Guimarães SL, Araújo SS, Hengge AC, Brandão TA, and Nagem RA

Subjects

Aldehyde Dehydrogenase chemistry, Crystallography, X-Ray, Enzyme Stability, Hydrogen-Ion Concentration, Kinetics, Protein Conformation, Substrate Specificity, Temperature, Aldehyde Dehydrogenase metabolism

Abstract

The salicylaldehyde dehydrogenase (NahF) catalyzes the oxidation of salicylaldehyde to salicylate using NAD(+) as a cofactor, the last reaction of the upper degradation pathway of naphthalene in Pseudomonas putida G7. The naphthalene is an abundant and toxic compound in oil and has been used as a model for bioremediation studies. The steady-state kinetic parameters for oxidation of aliphatic or aromatic aldehydes catalyzed by 6xHis-NahF are presented. The 6xHis-NahF catalyzes the oxidation of aromatic aldehydes with large kcat/Km values close to 10(6) M(-1) s(-1). The active site of NahF is highly hydrophobic, and the enzyme shows higher specificity for less polar substrates than for polar substrates, e.g., acetaldehyde. The enzyme shows α/β folding with three well-defined domains: the oligomerization domain, which is responsible for the interlacement between the two monomers; the Rossmann-like fold domain, essential for nucleotide binding; and the catalytic domain. A salicylaldehyde molecule was observed in a deep pocket in the crystal structure of NahF where the catalytic C284 and E250 are present. Moreover, the residues G150, R157, W96, F99, F274, F279, and Y446 were thought to be important for catalysis and specificity for aromatic aldehydes. Understanding the molecular features responsible for NahF activity allows for comparisons with other aldehyde dehydrogenases and, together with structural information, provides the information needed for future mutational studies aimed to enhance its stability and specificity and further its use in biotechnological processes.

Published

2016

4. Structural Basis of Substrate Recognition by Aldehyde Dehydrogenase 7A1.

Author

Luo M and Tanner JJ

Subjects

Aldehyde Dehydrogenase genetics, Amino Acid Sequence, Catalytic Domain physiology, Humans, Molecular Sequence Data, Protein Structure, Secondary, Substrate Specificity physiology, X-Ray Diffraction, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase metabolism

Abstract

Aldehyde dehydrogenase 7A1 (ALDH7A1) is part of lysine catabolism and catalyzes the NAD(+)-dependent oxidation of α-aminoadipate semialdehyde to α-aminoadipate. Herein, we describe a structural study of human ALDH7A1 focused on substrate recognition. Five crystal structures and small-angle X-ray scattering data are reported, including the first crystal structure of any ALDH7 family member complexed with α-aminoadipate. The product binds with the ε-carboxylate in the oxyanion hole, the aliphatic chain packed into an aromatic box, and the distal end of the product anchored by electrostatic interactions with five conserved residues. This binding mode resembles that of glutamate bound to the proline catabolic enzyme ALDH4A1. Analysis of ALDH7A1 and ALDH4A1 structures suggests key interactions that underlie substrate discrimination. Structures of apo ALDH7A1 reveal dramatic conformational differences from the product complex. Product binding is associated with a 16 Å movement of the C-terminus into the active site, which stabilizes the active conformation of the aldehyde substrate anchor loop. The fact that the C-terminus is part of the active site was hitherto unknown. Interestingly, the C-terminus and aldehyde anchor loop are disordered in a new tetragonal crystal form of the apoenzyme, implying that these parts of the enzyme are highly flexible. Our results suggest that the active site of ALDH7A1 is disassembled when the aldehyde site is vacant, and the C-terminus is a mobile element that forms quaternary structural interactions that aid aldehyde binding. These results are relevant to the c.1512delG genetic deletion associated with pyridoxine-dependent epilepsy, which alters the C-terminus of ALDH7A1.

Published

2015

5. Evidence that the C-terminal domain of a type B PutA protein contributes to aldehyde dehydrogenase activity and substrate channeling.

Author

Luo M, Christgen S, Sanyal N, Arentson BW, Becker DF, and Tanner JJ

Subjects

Aldehyde Dehydrogenase genetics, Amino Acid Sequence, Amino Acid Substitution, Bacterial Proteins genetics, Bradyrhizobium genetics, Bradyrhizobium metabolism, Catalytic Domain, Genes, Bacterial, Kinetics, Membrane Proteins genetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Protein Conformation, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Rhodobacter capsulatus genetics, Scattering, Small Angle, Sequence Homology, Amino Acid, Structural Homology, Protein, Substrate Specificity, X-Ray Diffraction, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Rhodobacter capsulatus metabolism

Abstract

Proline utilization A (PutA) is a bifunctional enzyme that catalyzes the oxidation of proline to glutamate. Structures of type A PutAs have revealed the catalytic core consisting of proline dehydrogenase (PRODH) and Δ(1)-pyrroline-5-carboxylate dehydrogenase (P5CDH) modules connected by a substrate-channeling tunnel. Type B PutAs also have a C-terminal domain of unknown function (CTDUF) that is absent in type A PutAs. Small-angle X-ray scattering (SAXS), mutagenesis, and kinetics are used to determine the contributions of this domain to PutA structure and function. The 1127-residue Rhodobacter capsulatus PutA (RcPutA) is used as a representative CTDUF-containing type B PutA. The reaction progress curve for the coupled PRODH-P5CDH activity of RcPutA does not exhibit a time lag, implying a substrate channeling mechanism. RcPutA is monomeric in solution, which is unprecedented for PutAs. SAXS rigid body modeling with target-decoy validation is used to build a model of RcPutA. On the basis of homology to aldehyde dehydrogenases (ALDHs), the CTDUF is predicted to consist of a β-hairpin fused to a noncatalytic Rossmann fold domain. The predicted tertiary structural interactions of the CTDUF resemble the quaternary structural interactions in the type A PutA dimer interface. The model is tested by mutagenesis of the dimerization hairpin of a type A PutA and the CTDUF hairpin of RcPutA. Similar functional phenotypes are observed in the two sets of variants, supporting the hypothesis that the CTDUF mimics the type A PutA dimer interface. These results suggest annotation of the CTDUF as an ALDH superfamily domain that facilitates P5CDH activity and substrate channeling by stabilizing the aldehyde-binding site and sealing the substrate-channeling tunnel from the bulk medium.

Published

2014

6. Substrate specificity, substrate channeling, and allostery in BphJ: an acylating aldehyde dehydrogenase associated with the pyruvate aldolase BphI.

Author

Baker P, Carere J, and Seah SY

Subjects

Acetaldehyde metabolism, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase genetics, Allosteric Regulation, Burkholderia chemistry, Burkholderia genetics, Burkholderia metabolism, Fructose-Bisphosphate Aldolase chemistry, Models, Molecular, Mutagenesis, Site-Directed, Protein Conformation, Substrate Specificity, Aldehyde Dehydrogenase metabolism, Burkholderia enzymology, Fructose-Bisphosphate Aldolase metabolism, Pyruvic Acid metabolism

Abstract

BphJ, a nonphosphorylating acylating aldehyde dehydrogenase, catalyzes the conversion of aldehydes to form acyl-coenzyme A in the presence of NAD(+) and coenzyme A (CoA). The enzyme is structurally related to the nonacylating aldehyde dehydrogenases, aspartate-β-semialdehyde dehydrogenase and phosphorylating glyceraldehyde-3-phosphate dehydrogenase. Cys-131 was identified as the catalytic thiol in BphJ, and pH profiles together with site-specific mutagenesis data demonstrated that the catalytic thiol is not activated by an aspartate residue, as previously proposed. In contrast to the wild-type enzyme that had similar specificities for two- or three-carbon aldehydes, an I195A variant was observed to have a 20-fold higher catalytic efficiency for butyraldehyde and pentaldehyde compared to the catalytic efficiency of the wild type toward its natural substrate, acetaldehyde. BphJ forms a heterotetrameric complex with the class II aldolase BphI that channels aldehydes produced in the aldol cleavage reaction to the dehydrogenase via a molecular tunnel. Replacement of Ile-171 and Ile-195 with bulkier amino acid residues resulted in no more than a 35% reduction in acetaldehyde channeling efficiency, showing that these residues are not critical in gating the exit of the channel. Likewise, the replacement of Asn-170 in BphJ with alanine and aspartate did not substantially alter aldehyde channeling efficiencies. Levels of activation of BphI by BphJ N170A, N170D, and I171A were reduced by ≥3-fold in the presence of NADH and ≥4.5-fold when BphJ was undergoing turnover, indicating that allosteric activation of the aldolase has been compromised in these variants. The results demonstrate that the dehydrogenase coordinates the catalytic activity of BphI through allostery rather than through aldehyde channeling.

Published

2012

7. Crystallographic snapshots of Tom20-mitochondrial presequence interactions with disulfide-stabilized peptides.

Author

Saitoh T, Igura M, Miyazaki Y, Ose T, Maita N, and Kohda D

Subjects

Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase metabolism, Amino Acid Sequence, Amino Acid Substitution, Animals, Crystallography, X-Ray, Disulfides chemistry, Membrane Transport Proteins, Mitochondrial Precursor Protein Import Complex Proteins, Mitochondrial Proteins genetics, Mitochondrial Proteins metabolism, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Interaction Domains and Motifs, Protein Stability, Protein Structure, Tertiary, Rats, Receptors, Cell Surface, Receptors, Cytoplasmic and Nuclear genetics, Receptors, Cytoplasmic and Nuclear metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Mitochondrial Proteins chemistry, Receptors, Cytoplasmic and Nuclear chemistry

Abstract

Most mitochondrial proteins are synthesized in the cytosol and imported into mitochondria. The Tom20 protein, residing on the mitochondrial surface, recognizes the N-terminal presequences of precursor proteins. We previously determined the crystal structures of the Tom20-presequence complex. The successful crystallization involved tethering the presequence to Tom20 through an intermolecular disulfide bond with an optimized linker. In this work, we assessed the tethering method. The intermolecular disulfide bond was cleaved in crystal with a reducing agent. The pose (i.e., conformation and position) of the presequence was identical to the previously determined pose. In another experiment, a longer linker than the optimized length was used for the tethering. The perturbation of the tether changed the pose slightly, but the interaction mode was preserved. These results argue against the forced interaction of the presequence by its covalent attachment to Tom20. Second, as an alternative method referred to as "molecular stiffening", we introduced a disulfide bond within the presequence peptide to restrict the freedom of the peptide in the unbound states. One presequence analogue exhibited over 100-fold higher affinity than its linear counterpart and generated cocrystals with Tom20. One of the two crystallographic snapshots revealed a known pose previously determined by the tethering method, and the other snapshot depicted a new pose. These results confirmed and extended the dynamic, multiple bound state model of the Tom20-presequence interactions and also demonstrated the validity of the molecular tethering and stiffening techniques in studies of transient protein-peptide interactions.

Published

2011

8. Mechanistic implications of the cysteine-nicotinamide adduct in aldehyde dehydrogenase based on quantum mechanical/molecular mechanical simulations.

Author

Wymore T, Deerfield DW 2nd, and Hempel J

Subjects

Aldehyde Dehydrogenase, Mitochondrial, Aldehydes chemistry, Computer Simulation, Humans, NAD chemistry, Protein Conformation, Protons, Quantum Theory, Aldehyde Dehydrogenase chemistry, Cysteine chemistry, Niacinamide chemistry

Abstract

Recent computer simulations of the cysteine nucleophilic attack on propanal in human mitochondrial aldehyde dehydrogenase (ALDH2) yielded an unexpected result: the chemically reasonable formation of a dead-end cysteine-cofactor adduct when NAD+ was in the "hydride transfer" position. More recently, this adduct found independent crystallographic support in work on formyltetrahydrofolate dehydrogenase, work which further found evidence of the same adduct on re-examination of deposited electron densities of ALDH2. Although the experimental data showed that this adduct was reversible, several mechanistic questions arise from the fact that it forms at all. Here, we present results from further quantum mechanical/molecular mechanical (QM/MM) simulations toward understanding the mechanistic implications of adduct formation. These simulations revealed formation of the oxyanion thiohemiacetal intermediate only when the nicotinamide ring of NAD+ is oriented away from the active site, contrary to prior arguments. In contrast, and in seeming paradox, when NAD is oriented to receive the hydride, disassociation of the oxyanion intermediate to form the dead-end adduct is more thermodynamically favored than maintaining the oxyanion intermediate necessary for catalysis to proceed. However, this disassociation to the adduct could be avoided through proton transfer from the enzyme to the intermediate. Our results continue to indicate that the unlikely source of this proton is the Cys302 main chain amide.

Published

2007

9. Selective alteration of the rate-limiting step in cytosolic aldehyde dehydrogenase through random mutagenesis.

Author

Ho KK, Hurley TD, and Weiner H

Subjects

Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase 1 Family, Animals, Catalysis, Cations, Divalent pharmacology, Computational Biology, Cytosol enzymology, Enzyme Activation genetics, Esterases antagonists & inhibitors, Esterases drug effects, Humans, Hydrolysis, Isoenzymes genetics, Magnesium chemistry, Models, Molecular, Mutagenesis, NAD chemistry, Nitrophenols chemistry, Point Mutation, Protein Conformation, Retinal Dehydrogenase, Sheep, Aldehyde Dehydrogenase antagonists & inhibitors, Aldehyde Dehydrogenase chemistry, Isoenzymes antagonists & inhibitors, Isoenzymes chemistry, Magnesium pharmacology

Abstract

Random mutagenesis followed by a filter-based screening assay has been used to identify a mutant of human class 1 aldehyde dehydrogenase (ALDH1) that was no longer inhibited by Mg(2+) ions but was activated in their presence. Several mutants possessed double, triple, and quadruple amino acid substitutions with a total of seven different residues being altered, but each had a common T244S change. This point mutation proved to be responsible for the Mg(2+) ion activation. An ALDH1 T244S mutant was recombinantly expressed and was used for mechanistic studies. Mg(2+) ions have been shown to increase the rate of deacylation. Consistent with the rate-limiting step for ALDH1 being changed from coenzyme dissociation to deacylation was finding that chloroacetaldehyde was oxidized more rapidly than acetaldehyde. Furthermore, Mg(2+) ions only in the presence of NAD(H) increased the rate of hydrolysis of p-nitrophenyl acetate showing that the metal only affects the binary complex. Though the rate-limiting step for the T244S mutant was different from that of the native enzyme, the catalytic efficiency of the mutant was just 20% that of the native enzyme. The basis for the change in the rate-limiting step appears to be related to NAD(+) binding. Using the structure of a sheep class 1 ALDH, it was possible to deduce that the interaction between the side chain of T244 and its neighboring residues with the nicotinamide ring of NAD(+) were an essential determinant in the catalytic action of ALDH1.

Published

2006

10. The first crystal structure of a thioacylenzyme intermediate in the ALDH family: new coenzyme conformation and relevance to catalysis.

Author

D'Ambrosio K, Pailot A, Talfournier F, Didierjean C, Benedetti E, Aubry A, Branlant G, and Corbier C

Subjects

Acylation, Aldehyde Dehydrogenase metabolism, Binding Sites, Catalysis, Coenzymes metabolism, Crystallography, X-Ray, Glyceraldehyde 3-Phosphate Dehydrogenase (NADP+) chemistry, Glyceraldehyde 3-Phosphate Dehydrogenase (NADP+) metabolism, Isomerism, Kinetics, NADP chemistry, NADP metabolism, Nicotinamide Mononucleotide chemistry, Oxidation-Reduction, Protein Conformation, Streptococcus mutans enzymology, Streptococcus mutans metabolism, Aldehyde Dehydrogenase chemistry, Coenzymes chemistry

Abstract

Crystal structures of several members of the nonphosphorylating CoA-independent aldehyde dehydrogenase (ALDH) family have shown that the peculiar binding mode of the cofactor to the Rossmann fold results in a conformational flexibility for the nicotinamide moiety of the cofactor. This has been hypothesized to constitute an essential feature of the catalytic mechanism because the conformation of the cofactor required for the acylation step is not appropriate for the deacylation step. In the present study, the structure of a reaction intermediate of the E268A-glyceraldehyde 3-phosphate dehydrogenase (GAPN) from Streptococcus mutans, obtained by soaking the crystals of the enzyme/NADP complex with the natural substrate, is reported. The substrate is bound covalently in the four monomers and presents the geometric characteristics expected for a thioacylenzyme intermediate. Control experiments assessed that reduction of the coenzyme has occurred within the crystal. The structure reveals that reduction of the cofactor upon acylation leads to an extensive motion of the nicotinamide moiety with a flip of the reduced pyridinium ring away from the active site without significant changes of the protein structure. This event positions the reduced nicotinamide moiety in a pocket that likely constitutes the exit door for NADPH. Arguments are provided that the structure reported here constitutes a reasonable picture of the first thioacylenzyme intermediate characterized thus far in the ALDH family and that the position of the reduced nicotinamide moiety observed in GAPN is the one suitable for the deacylation step within all of the nonphosphorylating CoA-independent ALDH family.

Published

2006

11. Differential effects of Mg2+ ions on the individual kinetic steps of human cytosolic and mitochondrial aldehyde dehydrogenases.

Author

Ho KK, Allali-Hassani A, Hurley TD, and Weiner H

Subjects

Acetaldehyde analogs & derivatives, Acetaldehyde metabolism, Acylation, Aldehyde Dehydrogenase antagonists & inhibitors, Aldehyde Dehydrogenase metabolism, Aldehyde Dehydrogenase 1 Family, Aldehyde Dehydrogenase, Mitochondrial, Cations, Divalent chemistry, Deuterium Exchange Measurement, Humans, Isoenzymes metabolism, Kinetics, Liver enzymology, NAD metabolism, Retinal Dehydrogenase, Substrate Specificity, Aldehyde Dehydrogenase chemistry, Cytosol enzymology, Isoenzymes chemistry, Magnesium chemistry, Mitochondria enzymology

Abstract

Although the structures of mammalian cytosolic and mitochondrial ALDH have been determined, several differences, mainly functional, between these two 70% identical isozymes remain unexplained. A major difference is the differential effect of Mg(2+) ions that inhibits the cytosolic and activates the mitochondrial isozyme. Here, we have investigated the effect of Mg(2+) ions on each individual kinetic step of ALDH1 and ALDH2. The metal ions were found not to affect either acylation or hydride transfer for either isozyme. The lack of a Mg(2+) ion effect on hydride transfer was further demonstrated with an E399Q mutant of ALDH1 whose rate-limiting step had been changed from NADH dissociation to hydride transfer. The other steps, however, were affected by Mg(2+) ions for both isozymes. The metal ions inhibited NADH dissociation, the rate-limiting step for ALDH1, and enhanced deacylation, the rate-limiting step for ALDH2. Our results indicated that, with both isozymes, Mg(2+) ions tightened the binding of NADH, and by binding to the coenzyme, they increased the nucleophilicity of the nucleophile Cys302. The inhibition of ALDH1 and activation of ALDH2 at pH 7.4 are due to their different rate-limiting steps. Mg(2+) ions affected similarly the NADH activation of the esterase reaction for both isozymes. In contrast, the metal ions affected only the NAD(+) activation of ALDH1. This latter finding and other features described here can be rationalized on the basis of the known three-dimensional structures of the isozymes.

Published

2005

12. Coenzyme isomerization is integral to catalysis in aldehyde dehydrogenase.

Author

Perez-Miller SJ and Hurley TD

Subjects

Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase genetics, Amino Acid Substitution, Binding Sites, Catalysis, Crystallography, X-Ray, Humans, Hydrogen Bonding, Hydrolysis, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Magnesium chemistry, Magnesium pharmacology, Mitochondria enzymology, Models, Molecular, Mutagenesis, Site-Directed, NAD chemistry, NAD metabolism, Protein Conformation, Aldehyde Dehydrogenase metabolism

Abstract

Crystal structures of many enzymes in the aldehyde dehydrogenase superfamily determined in the presence of bound NAD(P)(+) have exhibited conformational flexibility for the nicotinamide half of the cofactor. This has been hypothesized to be important in catalysis because one conformation would block the second half of the reaction, but no firm evidence has been put forth which shows whether the oxidized and reduced cofactors preferentially occupy the two observed conformations. We present here two structures of the wild type and two structures of a Cys302Ser mutant of human mitochondrial aldehyde dehydrogenase in binary complexes with NAD(+) and NADH. These structures, including the Cys302Ser mutant in complex with NAD(+) at 1.4 A resolution and the wild-type enzyme in complex with NADH at 1.9 A resolution, provide strong evidence that bound NAD(+) prefers an extended conformation ideal for hydride transfer and bound NADH prefers a contracted conformation ideal for acyl-enzyme hydrolysis. Unique interactions between the cofactor and the Rossmann fold make isomerization possible while allowing the remainder of the active site complex to remain intact. In addition, these structures clarify the role of magnesium in activating the human class 2 enzyme. Our data suggest that the presence of magnesium may lead to selection of particular conformations and speed isomerization of the reduced cofactor following hydride transfer.

Published

2003

13. Crystal structure of eta-crystallin: adaptation of a class 1 aldehyde dehydrogenase for a new role in the eye lens.

Author

Bateman OA, Purkiss AG, van Montfort R, Slingsby C, Graham C, and Wistow G

Subjects

Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase metabolism, Animals, Binding Sites, Catalytic Domain, Crystallins genetics, Crystallins metabolism, Crystallography, X-Ray, Lens, Crystalline metabolism, Protein Structure, Tertiary, Shrews genetics, Shrews metabolism, Aldehyde Dehydrogenase chemistry, Crystallins chemistry, Lens, Crystalline chemistry

Abstract

Eta-crystallin is a retinal dehydrogenase that has acquired a role as a structural protein in the eye lens of elephant shrews, members of an ancient order of mammals. While it retains some activity toward retinal, which is oxidized to retinoic acid, the protein has acquired a number of specific sequence changes that have presumably been selected to enhance the lens role. The crystal structure of eta-crystallin, in common with class 1 and 2 ALDHs, is a dimer of dimers. It has a better-defined NAD binding site than those of related mammalian ALDH1 enzymes with the cofactor bound in the "hydride transfer" position in all four monomers with small differences about the dimer dyads. Although the active site is well conserved, the substrate-binding site is larger in eta-crystallin, and there are some mutations to the substrate access tunnel that might affect binding or release of substrate and product. It is possible that eta-crystallin has lost flexibility to improve its role in the lens. Enhanced binding of cofactor could enable it to act as a UV/blue light filter in the lens, improving visual acuity. The structure not only gives a view of a "natural mutant" of ALDH1 illustrating the adaptive conflict that can arise in multifunctional proteins, but also provides a well-ordered NAD binding site structure for this class of enzymes with important roles in development and health.

Published

2003

14. Structural aspects of aldehyde dehydrogenase that influence dimer-tetramer formation.

Author

Rodriguez-Zavala JS and Weiner H

Subjects

Aldehyde Dehydrogenase 1 Family, Amino Acid Sequence, Arginine, Cloning, Molecular, Conserved Sequence, Dimerization, Humans, Isoenzymes chemistry, Isoenzymes metabolism, Kinetics, Macromolecular Substances, Models, Molecular, Molecular Sequence Data, Plasmids, Protein Conformation, Protein Subunits, Recombinant Fusion Proteins metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Retinal Dehydrogenase, Sequence Alignment, Sequence Homology, Amino Acid, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase metabolism

Abstract

Aldehyde dehydrogenases are isolated as dimers or tetramers but have essentially identical structures. The homotetramer (ALDH1 or ALDH2) is a dimer of dimers (A-B + C-D). In the tetrameric enzyme, Ser500 from subunit "D" interacts with Arg84, a conserved residue, from subunit "A". In the dimeric ALDH3 form, the interaction cannot exist. It has been proposed that the formation of the tetramer is prevented by the presence of a C-terminal tail in ALDH3 that is not present in ALDH1 or 2. To understand the forces that maintain the tetramer, deletion of the tail in ALDH3, addition of different tails in ALDH1, and mutations of different residues located in the dimer-dimer interface were made. Gel filtration of the recombinantly expressed enzymes demonstrated that no change in their oligomerization occurred. Urea denaturation showed a diminution to the stability of the ALDH1 mutants. The K(m) for propionaldehyde was similar to that of the wild-type enzyme, but the K(m) for NAD was altered. A double mutant of D80G and S82A produced an enzyme with the ability to form dimers and tetramers in a protein-concentration-dependent manner. Though stable, this dimeric form was inactive. The tetramer exhibited 10% activity compared with the wild type. Sequence alignment demonstrated that the hydrophobic surface area is increased in the tetrameric enzymes. The hydrophobic surface seems to be the main force that drives the formation of tetramers. The results indicated that residues 80 and 82 are involved in maintaining the tetramer after its assembly but the C-terminal extension contributes to the overall stability of the assembled protein.

Published

2002

15. Multiple conformations of NAD and NADH when bound to human cytosolic and mitochondrial aldehyde dehydrogenase.

Author

Hammen PK, Allali-Hassani A, Hallenga K, Hurley TD, and Weiner H

Subjects

Aldehyde Dehydrogenase metabolism, Biological Transport physiology, Coenzymes chemistry, Coenzymes metabolism, Cytosol enzymology, Fluorescence Polarization methods, Humans, Mitochondria enzymology, Molecular Conformation, NAD metabolism, Aldehyde Dehydrogenase chemistry, Magnesium chemistry, NAD chemistry, Protons

Abstract

Crystallographic analysis revealed that the nicotinamide ring of NAD can bind with multiconformations to aldehyde dehydrogenase (ALDH) (Ni, L., Zhou, J., Hurley, T. D., and Weiner, H. (1999) Protein Sci. 8, 2784-2790). Electron densities can be defined for two conformations, neither of which appears to be compatible with the catalytic reaction. In one conformation, it would prevent glutamate 268 from functioning as a general base needed to activate the catalytic nucleophile, cysteine 302. In the other conformation, the nicotinamide is too far from the enzyme-substrate adduct for efficient hydride transfer. In this study, NMR and fluorescence spectroscopies were used to demonstrate that NAD and NADH bind to human liver cytosol and mitochondrial ALDH such that the nicotinamide samples a population of conformations while the adenosine region remains relatively immobile. Although the nicotinamide possesses extensive conformational heterogeneity, the catalyzed reaction leads to the stereospecific transfer of hydride to the coenzyme. Mobility allows the nicotinamide to move into position to be reduced by the enzyme-substrate adduct. Although the reduced nicotinamide ring retains mobility after NADH formation, the extent of the motion is less than that of NAD. It appears that after reduction the population of favored nicotinamide conformations shifts toward those that do not interfere with the ability of the enzyme to release the reaction product. In the case of the mitochondrial, but not the cytosolic, enzyme this change in conformational preference is promoted by the presence of Mg2+ ions. Coenzyme conformational mobility appears to be beneficial to catalysis by ALDH throughout the catalytic cycle.

Published

2002

16. Basis for half-of-the-site reactivity and the dominance of the K487 oriental subunit over the E487 subunit in heterotetrameric human liver mitochondrial aldehyde dehydrogenase.

Author

Zhou J and Weiner H

Subjects

Aldehyde Dehydrogenase metabolism, Amino Acid Substitution genetics, Asian People genetics, Binding Sites genetics, Dimerization, Enzyme Activation genetics, Glutamic Acid genetics, Glutamic Acid metabolism, Humans, Kinetics, Lysine genetics, Lysine metabolism, Mutagenesis, Site-Directed, NAD chemistry, NAD metabolism, Peptide Fragments genetics, Peptide Fragments isolation & purification, Peptide Fragments metabolism, Aldehyde Dehydrogenase chemistry, Glutamic Acid chemistry, Lysine chemistry, Mitochondria, Liver enzymology, Peptide Fragments chemistry

Abstract

Human liver mitochondrial aldehyde dehydrogenase is a tetrameric enzyme composed of 4 identical 500 amino acid containing subunits arranged such that the protein is a dimer of dimers. No kinetic evidence for subunit interactions has been reported. However, the enzyme exhibits half-of-the-site reactivity in that there is a pre-steady-state burst of 2 mol of NADH per mole of enzyme. A variant of the enzyme, found in Asian people, contains a lysine rather than a glutamate at position 487. This enzyme has a high K(M) for NAD(+) and a low specific activity. In heterotetramers composed of both subunit types, it appeared that the lysine-containing subunit was dominant over the glutamate-containing subunits. To allow for the separation of various heterotetrameric forms of the enzyme, surface residues were changed. Each of the five possible tetrameric forms of the modified enzyme was isolated and characterized with respect to steady-state kinetics and pre-steady-state burst magnitudes. The data best fit a model where in each dimer pair there is one functioning and one nonfunctioning subunit. Further, the lysine subunit affects the properties only of its dimer partner. Residue 487 is located at the dimer interface, and the glutamate forms salt bonds with two arginine residues. One is to Arg(264) in the same subunit; the other is to Arg(475) located in the other subunit. Most likely the presence of a lysine affects these salt bonds so the lysine subunit can cause the other subunit to become essentially nonfunctional.

Published

2000

17. Cooperativity in nicotinamide adenine dinucleotide binding induced by mutations of arginine 475 located at the subunit interface in the human liver mitochondrial class 2 aldehyde dehydrogenase.

Author

Wei B, Ni L, Hurley TD, and Weiner H

Subjects

Aldehyde Dehydrogenase genetics, Enzyme Stability, Esterases metabolism, Humans, Hydrogen Bonding, Kinetics, Models, Molecular, Mutation, Protein Binding, Recombinant Proteins chemistry, Static Electricity, Aldehyde Dehydrogenase chemistry, Arginine genetics, Mitochondria, Liver enzymology, NAD metabolism

Abstract

The low-activity Oriental variant of human mitochondrial aldehyde dehydrogenase possesses a lysine rather than a glutamate at residue 487 in the 500 amino acid homotetrameric enzyme. The glutamate at position 487 formed two salt bonds, one to an arginine at position 264 in the same subunit and the other to arginine 475 in a different subunit [Steinmetz, C. G., Xie, P.-G.,Weiner, H., and Hurley, T. D. (1997) Structure 5, 2487-2505]. Mutating arginine 264 to glutamine produced a recombinantly expressed enzyme with nativelike properties; in contrast, mutating arginine 475 to glutamine produced an enzyme that exhibited positive cooperativity in NAD binding. The K(M) for NAD increased 23-fold with a Hill coefficient of 1.8. The binding of both NAD and NADH was affected by the mutation at position 475. Restoring the salt bonds between residues 487 and either or both 264 and 475 did not restore nativelike properties to the Oriental variant. Further, the R475Q mutant was thermally less stable than the native enzyme, Oriental variant, or other mutants. The presence of NAD restored nativelike stability to the mutant. It is concluded that movement of arginine 475 disrupted salt bonds between it and residues other than the one at 487, which caused the apo-R475Q mutant to have properties typical of an enzyme that exhibits positive cooperativity in substrate binding. Breaking the salt bond between glutamate 487 in the Oriental variant and the two arginine residues cannot be the only reason that this enzyme has altered catalytic properties.

Published

2000

18. Molybdopterin radical in bacterial aldehyde dehydrogenases.

Author

Luykx DM, Duine JA, and de Vries S

Subjects

Actinobacteria enzymology, Aldehyde Dehydrogenase chemistry, Bacterial Proteins chemistry, Catalysis, Electron Spin Resonance Spectroscopy, Electron Transport, Gram-Negative Aerobic Rods and Cocci enzymology, Iron metabolism, Metalloproteins chemistry, Molybdenum Cofactors, Oxidation-Reduction, Pteridines chemistry, Sulfur metabolism, Aldehyde Dehydrogenase metabolism, Bacterial Proteins metabolism, Coenzymes, Metalloproteins metabolism, Pteridines metabolism

Abstract

The EPR spectra of three different molybdoprotein aldehyde dehydrogenases, one purified from Comamonas testosteroni and two purified from Amycolatopsis methanolica, showed in their oxidized state a novel type of signal. These three enzymes contain two different [2Fe-2S] centers, one flavin and one molybdopterin cytosine dinucleotide, as cofactors all of which are expected to be EPR silent in the oxidized state. The new EPR signal is isotropic with g = 2.004 both at X-band and Q-band frequencies, consists of six partially resolved lines, and shows Curie temperature behavior suggesting that the signal is due to an organic radical with S = 1/2. The EPR spectra of Comamonas testosteroni aldehyde dehydrogenase obtained after cultivation in media containing 15NH4Cl and/or after substitution of H2O for D2O show the presence of both nitrogen and proton hyperfine interactions. Simulations of the spectra of the four possible isotope combinations yield a single set of hyperfine coupling constants. The electron spin shows hyperfine interaction with a single I = 1 (0.9 mT) ascribed to a N nucleus, with a single I = 1/2 (1.5 mT) ascribed to one nonexchangeable H nucleus, and with two, exchangeable, identical I = 1/2 spins (0.6 mT) ascribed to two identical exchangeable protons. Taken together, the observations and simulations rule out amino acid residues or flavin as the origin of the radical. The values of the various hyperfine coupling constants are consistent with the properties expected for a molybdenum(VI)-trihydropterin radical in which the N5 atom is engaged in two hydrogen-bonding interactions with the protein. The majority of the electron (spin) density of the radical is located at and around the N5 atom and at the proton bound to the C6 atom of the pterin ring. The EPR spectrum of the molybdopterin radical broadens above 65 K and is no longer detectable above 168 K, indicating that it is not magnetically isolated. The line broadening is ascribed to cross-relaxation with a nearby, rapidly relaxing, oxidized [2Fe-2S] center involving its magnetic S = 1 excited state in this process. The amount of radical was apparently not changed by addition of aldehydes or oxidants, but it disappeared upon reduction by sodium dithionite. Therefore, whether the molybdenum(VI) trihydropterin radical as detected here is a functional intermediate in catalysis remains to be investigated further.

Published

1998

19. Amphiphilicity determines binding properties of three mitochondrial presequences to lipid surfaces.

Author

Hammen PK, Gorenstein DG, and Weiner H

Subjects

Acetyl-CoA C-Acyltransferase chemistry, Aldehyde Dehydrogenase chemistry, Amino Acid Sequence, Biological Transport, Circular Dichroism, Kinetics, Liposomes metabolism, Magnetic Resonance Spectroscopy, Micelles, Molecular Sequence Data, Peptide Fragments chemistry, Peptide Fragments metabolism, Protein Sorting Signals metabolism, Protein Structure, Secondary, Spectrometry, Fluorescence, Thiosulfate Sulfurtransferase chemistry, Lipid Metabolism, Mitochondria, Liver metabolism, Protein Sorting Signals chemistry

Abstract

The interactions of three peptides, which correspond to presequences that direct mitochondrial protein import, with model membrane systems were characterized using NMR, fluorescence, and circular dichroism spectroscopies. The positively charged peptides adopted an ordered secondary structure only when the negatively charged phospholipid, cardiolipin, was present in small unilamellar vesicles. Conversely, the peptides adopted an ordered secondary structure in the presence of micelles formed from both formally neutral and negatively charged detergents. The peptides had the same relative affinity for micelles and small unilamellar vesicles containing 20% cardiolipin. Amide proton exchange rates showed that the region of the helical structure which had the greatest hydrophobic moment interacted most readily with micelles. Therefore, it appears that a major determinant of binding to lipid surfaces is the ability of the peptide to attain the correct orientation of hydrophobic and hydrophilic groups. For the three peptides studied, affinity also correlated with the length of the helix, but not with hydrophobic surface area. In each case, the interacting segment of the peptide was toward the C-terminal end of the helix. Previous work has allowed us to postulate that the N-terminus of the presequence is vital for import [Wang, Y., & Weiner, H. (1993) J. Biol. Chem. 268, 4759-4765] and the C-terminal end is essential for membrane interaction [Karslake, C., Piotto, M., Pak, Y. K., Weiner, H., & Gorenstein, D. G. (1990) Biochemistry 29, 9872-9878]. On the basis of the data that are now available, it appears that the interaction with membrane surfaces may depend on the location of an amphiphilic region of the sequence that is near but not necessarily at the C-terminus.

Published

1996

20. Investigation of the active site cysteine residue of rat liver mitochondrial aldehyde dehydrogenase by site-directed mutagenesis.

Author

Farrés J, Wang TT, Cunningham SJ, and Weiner H

Subjects

Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase metabolism, Amino Acid Sequence, Animals, Base Sequence, Binding Sites genetics, Cloning, Molecular, Cysteine chemistry, DNA genetics, Escherichia coli genetics, Gene Expression, Humans, Kinetics, Mitochondria, Liver enzymology, Models, Chemical, Molecular Sequence Data, Molecular Weight, Mutagenesis, Site-Directed, NAD metabolism, Rats, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Aldehyde Dehydrogenase chemistry

Abstract

To determine the active site cysteine residue in aldehyde dehydrogenase, we mutated amino acid residues 49, 162, and 302 of recombinantly expressed rat liver mitochondrial (class 2) aldehyde dehydrogenase. The C49A and C162A mutants were fully active tetrameric enzymes, although the C162A mutant was found to be highly unstable. The C302A mutant was also a tetramer and bound coenzyme, but lacked both dehydrogenase and esterase activities. To test for the role of cysteine 302 as a nucleophile, the residue was mutated to a serine, a poor nucleophile. this C302S mutant was active but was a much poorer catalyst, with a kcat/Km value 7 x 10(5) times lower than that of the recombinant native enzyme. Unlike with native enzyme where deacylation is rate limiting, formation of the serine hemiacetal intermediate appeared to be the rate-limiting step. Cysteine 302 is the only strictly conserved cysteine residue among all the available sequences of the aldehyde dehydrogenase superfamily, supporting the role of this residue as the active site nucleophile of aldehyde dehydrogenase.

Published

1995

21. Involvement of glutamate 268 in the active site of human liver mitochondrial (class 2) aldehyde dehydrogenase as probed by site-directed mutagenesis.

Author

Wang X and Weiner H

Subjects

Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase isolation & purification, Aldehyde Dehydrogenase metabolism, Binding Sites, Catalysis, DNA, Complementary, Glutamic Acid, Humans, Models, Chemical, Mutagenesis, Site-Directed, NAD metabolism, Recombinant Proteins isolation & purification, Structure-Activity Relationship, Aldehyde Dehydrogenase chemistry, Mitochondria, Liver enzymology

Abstract

On the basis of chemical modification studies, it was postulated that glutamate 268 was a component of the active site of liver aldehyde dehydrogenase [Abriola, D. P., Fields, R., MacKerell, A. D., Jr., & Pietruszko, R. (1987) Biochemistry 26, 5679-5684]. To study its role, the residue in human liver mitochondrial (class 2) aldehyde dehydrogenase was mutated to an aspartate, a glutamine, or a lysine, and the enzyme was expressed in Escherichia coli. The mutations did not affect the Km values for NAD or propionaldehyde, but grossly affected the catalytic activity of the enzymes when compared to recombinantly expressed native enzyme; the mutant enzymes had less that 0.4% of the specific activity of the recombinantly expressed native aldehyde dehydrogenase. The mutations also caused a long lag phase to occur prior to the steady state phase of the reaction. The activity of the mutant enzymes could not be restored by the addition of general bases such as sodium acetate, sodium formate, or imidazole. The Kd for NADH was essentially identical for the E268Q mutant and native enzyme. The three mutant forms of the enzyme possessed less than 0.8% of the esterolytic activity of the recombinantly expressed native enzyme. Pre-steady state analysis showed that there was no burst of NADH formation in the dehydrogenase reaction or of p-nitrophenol formation in the esterase reaction. This can be interpreted as implying that glutamate 268 may function as a general base necessary for the initial activation of the essential cysteine residue (302), rather than being involved in only the deacylation or hydride transfer step.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1995

22. Evaluation of electrostatic and hydrophobic effects on the interaction of mitochondrial signal sequences with phospholipid bilayers.

Author

Wang Y and Weiner H

Subjects

Amino Acid Sequence, Cardiolipins metabolism, Chemical Phenomena, Chemistry, Physical, Electrochemistry, Kinetics, Lipid Bilayers metabolism, Liposomes metabolism, Mitochondria metabolism, Molecular Sequence Data, Protein Sorting Signals metabolism, Protein Structure, Secondary, Spectrometry, Fluorescence, Structure-Activity Relationship, Aldehyde Dehydrogenase chemistry, Lipid Bilayers chemistry, Liposomes chemistry, Mitochondria chemistry, Phospholipids metabolism, Protein Sorting Signals chemistry

Abstract

The information that directs a nuclear-coded protein to be imported into mitochondria resides in an N-terminal extension, called a signal sequence. The primary sequences of all known ones differ. The only common feature is their ability to theoretically form an amphiphilic, positively charged, alpha-helix. We previously showed that a short stable helical segment was required for a peptide to be functional in import [Wang, Y., & Weiner, H. (1993) J. Biol. Chem. 268, 4759-4765]. Here we investigate the interaction of three altered signal sequences with phospholipid membranes containing cardiolipin to ascertain the importance of electrostatic and hydrophobic interactions with the membrane. The three already described peptides were derivatives of the signal sequence from aldehyde dehydrogenase, which is composed of three segments, two helices separated by a linker. ANCN had the C-helix replaced by the N-helix of the signal sequence of cytochrome c oxidase subunit IV, ANCC had the C-terminal helix replaced by the C-terminal random coil of cytochrome oxidase subunit IV, and linker deleted had the linker region deleted. ANCC, which functioned poorly as a signal sequence, had a very low affinity for binding to the negatively charged membranes. In contrast, both ANCN and linker deleted showed a relatively high affinity for the membranes and were capable of functioning as a good leader sequence. It appears that linker deleted possessed a stronger hydrophobic effect with membranes while ANCN had a higher electrostatic interaction. On the basic of these studies, a model was proposed to describe the interaction of mitochondrial signal sequences with negatively charged phospholipid membranes involving electrostatic interaction for initial binding and hydrophobic interaction for insertion.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

23. Involvement of serine 74 in the enzyme-coenzyme interaction of rat liver mitochondrial aldehyde dehydrogenase.

Author

Rout UK and Weiner H

Subjects

Adenosine Diphosphate Ribose metabolism, Aldehyde Dehydrogenase chemistry, Aldehyde Dehydrogenase genetics, Aldehyde Dehydrogenase isolation & purification, Animals, Enzyme Stability, Esterases metabolism, Kinetics, Mutation, NAD biosynthesis, Rats, Recombinant Proteins isolation & purification, Sepharose analogs & derivatives, Sepharose metabolism, Substrate Specificity, Aldehyde Dehydrogenase metabolism, Coenzymes metabolism, Mitochondria, Liver enzymology, Serine metabolism

Abstract

It has been suggested that the active site nucleophile in sheep liver aldehyde dehydrogenase was not a cysteine residue but was a serine located at position 74 [Loomes, K. M., Midwinter, G. G., Blackwell, L. F., & Buckley, P. D. (1990) Biochemistry 29, 2070-2080]. This enzyme form has not yet been cloned and expressed, but since the rat liver mitochondrial enzyme has been and shares 70% sequence homology with other cytosolic aldehyde dehydrogenases, the residue in the rat enzyme was converted into an alanine to test for the necessity of a hydroxyl group at that position. The recombinantly expressed mutant enzyme possessed 10% catalytic activity, but the Km for NAD increased from 10 to 1900 microM while the Kms for various aldehydes were unchanged. Kinetic analysis revealed that the dissociation constant for NAD also increased in the mutant as did k1, the on velocity for NAD binding. The mutant enzyme bound poorly to an AMP-Sepharose column and did not interact as well with NADH, as determined by fluorescence enhancement binding studies, or with ADP-ribose, a competitive inhibitor. Pulse-chase analysis showed that the mutant was as stable as was the recombinantly expressed native enzyme. It was less stable to heat denaturation at 50 degrees C (half-life of 1 min compared to 4). Converting the alanine to a cysteine or a threonine did not restore native-like properties of the enzyme. These mutants had kinetic properties very similar to those of the alanine mutant.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1994

24. Structural organization of aldehyde dehydrogenases probed by limited proteolysis.

Author

Loomes K and Jörnvall H

Subjects

Amino Acid Sequence, Chymotrypsin, Enzyme Activation, Humans, Hydrolysis, Mitochondria, Liver enzymology, Molecular Sequence Data, Peptide Fragments chemistry, Protein Conformation, Trypsin, Aldehyde Dehydrogenase chemistry, Endopeptidases

Abstract

Incubation of cytosolic and mitochondrial aldehyde dehydrogenases with trypsin or Glu-C protease under native conditions causes a time-dependent loss of dehydrogenase activity and the production of protein fragments. For evaluation of the results, termination of the reactions with a specific protease inhibitor is especially important in the case of the Glu-C protease. Cleavage site determination by SDS/polyacrylamide gel electrophoresis and sequence analysis identified protease-sensitive amino acid residues at two internal regions spanning positions 248-268 (region 1) and 397-399 (region 2) and at positions in the N-terminal segment (region 3). Region 1 encompasses several cleavages and is sensitive to both proteases in both aldehyde dehydrogenases. Further, it is in a conserved segment and correlates with reactive residues and regions ascribed functional roles. It also correlates with exon borders in the corresponding genes. Combined, the results define region 1 as an important and highly accessible segment of the protein. Region 2 is also adjacent to a conserved segment but lacks further correlation with special properties and appears just to represent an accessible region. The internally cleaved subunits retain a tetrameric configuration as calculated from exclusion chromatography and polyacrylamide gel electrophoresis under native conditions, suggesting that the quaternary structure is not dependent on covalently linked domains within the subunits. Furthermore, the fragments can bind to AMP-Sepharose, suggesting that some functional properties are retained within the cleaved tetramers. However, cleavage at position 35 appears to cause a large fragment (36-263) to be released from the tetramer, suggesting a role of an N-terminal segment or arm (at or before region 3) in subunit interactions.

Published

1991