Heterologous Expression and Partial Characterization of a New Alanine Dehydrogenase from Amycolatopsis sulphurea.

A novel alanine dehydrogenase (AlaDH; EC.1.4.1.1) was isolated from Amycolatopsis sulphurea and the AlaDH gene was cloned into a pET28a(+) plasmid and expressed in E. coli BL21 (DE3). The molecular mass of this enzyme was calculated as 41.09 kDa and the amino acid residues of the pure protein indicated the presence of N terminus polyhistidine tags. Its enzyme kinetic values were Km 2.03 mM, kcat 13.24 (s-1), and kcat/Km 6.53 (s-1 mM-1). AlaDH catalyzes the reversible conversion of L-alanine and pyruvate, which has an important role in the TCA energy cycle. Maximum AlaDH activity occurred at about pH 10.5 and 25 °C for the oxidative deamination of L-alanine. AlaDH retained about 10% of its relative activity at 55 °C and it remained about 90% active at 50 °C. These findings show that the AsAlaDH from A. sulphurea has the ability to produce valuable molecules for various industrial purposes and could represent a new potential biocatalyst for biotechnological applications after further characterization and improvement of its catalytic properties.

Biochemical characterization of specific Alanine Decarboxylase (AlaDC) and its ancestral enzyme Serine Decarboxylase (SDC) in tea plants (Camellia sinensis).

BACKGROUND: Alanine decarboxylase (AlaDC), specifically present in tea plants, is crucial for theanine biosynthesis. Serine decarboxylase (SDC), found in many plants, is a protein most closely related to AlaDC. To investigate whether the new gene AlaDC originate from gene SDC and to determine the biochemical properties of the two proteins from Camellia sinensis, the sequences of CsAlaDC and CsSDC were analyzed and the two proteins were over-expressed, purified, and characterized. RESULTS: The results showed that exon-intron structures of AlaDC and SDC were quite similar and the protein sequences, encoded by the two genes, shared a high similarity of 85.1%, revealing that new gene AlaDC originated from SDC by gene duplication. CsAlaDC and CsSDC catalyzed the decarboxylation of alanine and serine, respectively. CsAlaDC and CsSDC exhibited the optimal activities at 45 °C (pH 8.0) and 40 °C (pH 7.0), respectively. CsAlaDC was stable under 30 °C (pH 7.0) and CsSDC was stable under 40 °C (pH 6.0-8.0). The activities of the two enzymes were greatly enhanced by the presence of pyridoxal-5'-phosphate. The specific activity of CsSDC (30,488 IU/mg) was 8.8-fold higher than that of CsAlaDC (3467 IU/mg). CONCLUSIONS: Comparing to CsAlaDC, its ancestral enzyme CsSDC exhibited a higher specific activity and a better thermal and pH stability, indicating that CsSDC acquired the optimized function after a longer evolutionary period. The biochemical properties of CsAlaDC might offer reference for theanine industrial production.

A novel type alanine dehydrogenase from Helicobacter aurati: Molecular characterization and application.

A novel alanine dehydrogenase (ADH; EC.1.4.1.1) with high pyruvate reduced activity was isolated from Helicobacter aurati and expressed in Escherichia coli BL21 (DE3). The optimum pH of the reduction and oxidation reaction were 8.0 and 9.0, respectively, and the optimum temperature was 55 °C. With pyruvate and alanine as substrates, the specific activity of HAADH1 were 268 U·mg-1 and 26 U·mg-1, respectively. HAADH1 had a prominent substrate specificity for alanine (Km = 2.23 mM, kcat/Km = 8.1 s-1·mM-1). In the reduction reaction, HAADH1 showed the highest substrate affinity for pyruvate (Km = 0.56 mM, kcat/Km = 364 s-1·mM-1). Compared to pyruvate, oxaloacetic acid, 2-ketobutyric acid, 3-fluoropyruvate, α-ketoglutaric acids, glyoxylic acid showed a residual activity of 93.30%, 8.93%, 5.62%, 2.57%, 2.51%, respectively. Phylogenetic tree analysis showed that this is a new type of ADH which have a low sequence similarity to available ADH reported in references. 3-Fluoropyruvate was effectively reduced to 3-fluoro-L-alanine by whole-cell catalysis.

Alanine dehydrogenase and its applications - A review.

Alanine dehydrogenase (AlaDH) (E.C.1.4.1.1) is a microbial enzyme that catalyzes a reversible conversion of L-alanine to pyruvate. Inter-conversion of alanine and pyruvate by AlaDH is central to metabolism in microorganisms. Its oxidative deamination reaction produces pyruvate which plays a pivotal role in the generation of energy through the tricarboxylic acid cycle for sporulation in the microorganisms. Its reductive amination reaction provides a route for the incorporation of ammonia and produces L-alanine which is required for synthesis of the peptidoglycan layer, proteins, and other amino acids. Also, AlaDH helps in redox balancing as its deamination/amination reaction is linked to the reduction/oxidation of NAD+/NADH in microorganisms. AlaDH from a few microorganisms can also reduce glyoxylate into glycine (aminoacetate) in a nonreversible reaction. Both its oxidative and reductive reactions exhibit remarkable applications in the pharmaceutical, environmental, and food industries. The literature addressing the characteristics and applications of AlaDH from a wide range of microorganisms is summarized in the current review.

Computer-Guided Surface Engineering for Enzyme Improvement.

Protein engineering strategies are often guided by our understanding of how the structure of a protein determines its function. However, our understanding is generally restricted to small regions of a protein, namely the active site and its immediate vicinity, while the remainder of the protein is something of an enigma. Studying highly homologous transaminases with strictly conserved active sites, but different substrate preferences and activities, we predict and experimentally validate that the surface of the protein far from the active site carries out a decisive role in substrate selectivity and catalytic efficiency. Using a unique molecular dynamics approach and novel trajectory analysis, we demonstrate the phenomenon of surface-directed ligand diffusion in this well-known protein family for the first time. Further, we identify the residues involved in directing substrate, design surface channel variants endowed for improved kinetic properties and establish a broadly applicable new approach for protein engineering.

Bifunctional alanine dehydrogenase from the halotolerant cyanobacterium Aphanothece halophytica: characterization and molecular properties.

A link between carbon and nitrogen metabolism is important for serving as metabolic ancillary reactions. Here, we identified and characterized the alanine dehydrogenase gene in Aphanothece halophytica (ApalaDH) that is involved in alanine assimilation/dissimilation. Functional analysis revealed that ApalaDH encodes a bifunctional protein catalyzing the reversible reaction of pyruvate to L-alanine via its pyruvate reductive aminase (PvRA) activity, the reaction of L-alanine to pyruvate via its alanine oxidative dehydrogenase activity, and the non-reversible reaction of glyoxylate to glycine via its glyoxylate reductive aminase (GxRA) activity. Kinetic analysis showed the lowest affinity for pyruvate followed by L-alanine and glyoxylate with a Km of 0.22 ± 0.02, 0.72 ± 0.04, and 1.91 ± 0.43 mM, respectively. ApalaDH expression was upregulated by salt. Only PvRA and GxRA activities were detected in vivo and both activities increased about 1.2- and 2.7-fold upon salt stress. These features implicate that the assimilatory/dissimilatory roles of ApAlaDH are not only selective for L-alanine and pyruvate, but also, upon salt stress, can catabolize glyoxylate to generate glycine.

Efficient Enzymatic Preparation of (13) N-Labelled Amino Acids: Towards Multipurpose Synthetic Systems.

Nitrogen-13 can be efficiently produced in biomedical cyclotrons in different chemical forms, and its stable isotopes are present in the majority of biologically active molecules. Hence, it may constitute a convenient alternative to Fluorine-18 and Carbon-11 for the preparation of positron-emitter-labelled radiotracers; however, its short half-life demands for the development of simple, fast, and efficient synthetic processes. Herein, we report the one-pot, enzymatic and non-carrier-added synthesis of the (13) N-labelled amino acids l-[(13) N]alanine, [(13) N]glycine, and l-[(13) N]serine by using l-alanine dehydrogenase from Bacillus subtilis, an enzyme that catalyses the reductive amination of α-keto acids by using nicotinamide adenine dinucleotide (NADH) as the redox cofactor and ammonia as the amine source. The integration of both l-alanine dehydrogenase and formate dehydrogenase from Candida boidinii in the same reaction vessel to facilitate the in situ regeneration of NADH during the radiochemical synthesis of the amino acids allowed a 50-fold decrease in the concentration of the cofactor without compromising reaction yields. After optimization of the experimental conditions, radiochemical yields were sufficient to carry out in vivo imaging studies in small rodents.

Crystal Structure of Mycobacterium tuberculosis H37Rv AldR (Rv2779c), a Regulator of the ald Gene: DNA BINDING AND IDENTIFICATION OF SMALL MOLECULE INHIBITORS.

Here we report the crystal structure of M. tuberculosis AldR (Rv2779c) showing that the N-terminal DNA-binding domains are swapped, forming a dimer, and four dimers are assembled into an octamer through crystal symmetry. The C-terminal domain is involved in oligomeric interactions that stabilize the oligomer, and it contains the effector-binding sites. The latter sites are 30-60% larger compared with homologs like MtbFFRP (Rv3291c) and can consequently accommodate larger molecules. MtbAldR binds to the region upstream to the ald gene that is highly up-regulated in nutrient-starved tuberculosis models and codes for l-alanine dehydrogenase (MtbAld; Rv2780). Further, the MtbAldR-DNA complex is inhibited upon binding of Ala, Tyr, Trp and Asp to the protein. Studies involving a ligand-binding site G131T mutant show that the mutant forms a DNA complex that cannot be inhibited by adding the amino acids. Comparative studies suggest that binding of the amino acids changes the relative spatial disposition of the DNA-binding domains and thereby disrupt the protein-DNA complex. Finally, we identified small molecules, including a tetrahydroquinoline carbonitrile derivative (S010-0261), that inhibit the MtbAldR-DNA complex. The latter molecules represent the very first inhibitors of a feast/famine regulatory protein from any source and set the stage for exploring MtbAldR as a potential anti-tuberculosis target.

Synthesis of deuterium-labelled halogen derivatives of L-tryptophan catalysed by tryptophanase.

The isotopomers of halogen derivatives of l-tryptophan (l-Trp) (4'-F-, 7'-F-, 5'-Cl- and 7'-Br-l-Trp), specifically labelled with deuterium in α-position of the side chain, were obtained by enzymatic coupling of the corresponding halogenated derivatives of indole with S-methyl-l-cysteine in (2)H2O, catalysed by enzyme tryptophanase (EC 4.1.99.1). The positional deuterium enrichment of the resulting tryptophan derivatives was controlled using (1)H NMR. In accordance with the mechanism of the lyase reaction, a 100% deuterium labelling was observed in the α-position; the chemical yields were between 23 and 51%. Furthermore, ß-F-l-alanine, synthesized from ß-F-pyruvic acid by the l-alanine dehydrogenase reaction, has been tested as a coupling agent to obtain the halogenated deuterium-labelled derivatives of l-Trp. The chemical yield (∼30%) corresponded to that as observed with S-methyl-l-cysteine but the deuterium label was only 63%, probably due to the use of a not completely deuterated incubation medium.

Engineering of alanine dehydrogenase from Bacillus subtilis for novel cofactor specificity.

The l-alanine dehydrogenase of Bacillus subtilis (BasAlaDH), which is strictly dependent on NADH as redox cofactor, efficiently catalyzes the reductive amination of pyruvate to l-alanine using ammonia as amino group donor. To enable application of BasAlaDH as regenerating enzyme in coupled reactions with NADPH-dependent alcohol dehydrogenases, we alterated its cofactor specificity from NADH to NADPH via protein engineering. By introducing two amino acid exchanges, D196A and L197R, high catalytic efficiency for NADPH was achieved, with kcat /KM  = 54.1 µM-1  Min-1 (KM  = 32 ± 3 µM; kcat  = 1,730 ± 39 Min-1 ), almost the same as the wild-type enzyme for NADH (kcat /KM  = 59.9 µM-1  Min-1 ; KM  = 14 ± 2 µM; kcat  = 838 ± 21 Min-1 ). Conversely, recognition of NADH was much diminished in the mutated enzyme (kcat /KM  = 3 µM-1  Min-1 ). BasAlaDH(D196A/L197R) was applied in a coupled oxidation/transamination reaction of the chiral dicyclic dialcohol isosorbide to its diamines, catalyzed by Ralstonia sp. alcohol dehydrogenase and Paracoccus denitrificans ω-aminotransferase, thus allowing recycling of the two cosubstrates NADP+ and l-Ala. An excellent cofactor regeneration with recycling factors of 33 for NADP+ and 13 for l-Ala was observed with the engineered BasAlaDH in a small-scale biocatalysis experiment. This opens a biocatalytic route to novel building blocks for industrial high-performance polymers.

Domain Motions and Functionally-Key Residues of L-Alanine Dehydrogenase Revealed by an Elastic Network Model.

Mycobacterium tuberculosis L-alanine dehydrogenase (L-MtAlaDH) plays an important role in catalyzing L-alanine to ammonia and pyruvate, which has been considered to be a potential target for tuberculosis treatment. In the present work, the functional domain motions encoded in the structure of L-MtAlaDH were investigated by using the Gaussian network model (GNM) and the anisotropy network model (ANM). The slowest modes for the open-apo and closed-holo structures of the enzyme show that the domain motions have a common hinge axis centered in residues Met133 and Met301. Accompanying the conformational transition, both the 1,4-dihydronicotinamide adenine dinucleotide (NAD)-binding domain (NBD) and the substrate-binding domain (SBD) move in a highly coupled way. The first three slowest modes of ANM exhibit the open-closed, rotation and twist motions of L-MtAlaDH, respectively. The calculation of the fast modes reveals the residues responsible for the stability of the protein, and some of them are involved in the interaction with the ligand. Then, the functionally-important residues relevant to the binding of the ligand were identified by using a thermodynamic method. Our computational results are consistent with the experimental data, which will help us to understand the physical mechanism for the function of L-MtAlaDH.

Alteration of substrate specificity of alanine dehydrogenase.

The l-alanine dehydrogenase (AlaDH) has a natural history that suggests it would not be a promising candidate for expansion of substrate specificity by protein engineering: it is the only amino acid dehydrogenase in its fold family, it has no sequence or structural similarity to any known amino acid dehydrogenase, and it has a strong preference for l-alanine over all other substrates. By contrast, engineering of the amino acid dehydrogenase superfamily members has produced catalysts with expanded substrate specificity; yet, this enzyme family already contains members that accept a broad range of substrates. To test whether the natural history of an enzyme is a predictor of its innate evolvability, directed evolution was carried out on AlaDH. A single mutation identified through molecular modeling, F94S, introduced into the AlaDH from Mycobacterium tuberculosis (MtAlaDH) completely alters its substrate specificity pattern, enabling activity toward a range of larger amino acids. Saturation mutagenesis libraries in this mutant background additionally identified a double mutant (F94S/Y117L) showing improved activity toward hydrophobic amino acids. The catalytic efficiencies achieved in AlaDH are comparable with those that resulted from similar efforts in the amino acid dehydrogenase superfamily and demonstrate the evolvability of MtAlaDH specificity toward other amino acid substrates.

Molecular dynamics simulations of mutated Mycobacterium tuberculosis L-alanine dehydrogenase to illuminate the role of key residues.

L-Alanine dehydrogenase from Mycobacterium tuberculosis (L-MtAlaDH) catalyzes the NADH-dependent interconversion of l-alanine and pyruvate, and it is considered to be a potential target for the treatment of tuberculosis. The experiment has verified that amino acid replacement of the conserved active-site residues which have strong stability and no great changes in biological evolutionary process, such as His96 and Asp270, could lead to inactive mutants [Ågren et al., J. Mol. Biol. 377 (2008) 1161-1173]. However, the role of these conserved residues in catalytic reaction still remains unclear. Based on the crystal structures, a series of mutant structures were constructed to investigate the role of the conserved residues in enzymatic reaction by using molecular dynamics simulations. The results show that whatever the conserved residues were mutated, the protein can still convert its conformation from open state to closed state as long as NADH is present in active site. Asp270 maintains the stability of nicotinamide ring and ribose of NADH through hydrogen bond interactions, and His96 is helpful to convert the protein conformation by interactions with Gln271, whereas, they would lead to the structural rearrangement in active site and lose the catalytic activity when they were mutated. Additionally, we deduce that Met301 plays a major role in catalytic reaction due to fixing the nicotinamide ring of NADH to prevent its rotation, and we propose that Met301 would be mutated to the hydrophobic residue with large steric hindrance in side chain to test the activity of the protein in future experiment.

Identification of novel inhibitors against Mycobacterium tuberculosis L-alanine dehydrogenase (MTB-AlaDH) through structure-based virtual screening.

Mycobacterium tuberculosis (MTB) the etiological agent of tuberculosis (TB) survives in the human host for decades evading the immune system in a latent or persistent state. The Rv2780 (ald) gene that codes for L-alanine dehydrogenase (L-AlaDH) enzyme catalyzes reversible oxidative deamination of L-alanine to pyruvate and is overexpressed under hypoxic and nutrient starvation conditions in MTB. At present, as there is no suitable drug available to treat dormant tuberculosis; it is essential to identify drug candidates that could potentially treat dormant TB. Availability of crystal structure of MTB L-AlaDH bound with co-factor NAD+ facilitated us to employ structure-based virtual screening approach to obtain new hits from a commercial library of Asinex database using energy-optimized pharmacophore modeling. The resulting pharmacophore consisted of three hydrogen bond donor sites (D) and two hydrogen bond acceptor sites (A). The database compounds with a fitness score more than 1.0 were further subjected to Glide high-throughput virtual screening and docking. Thus, we report the identification of best five hits based on structure-based design and their in vitro enzymatic inhibition studies revealed IC50 values in the range of 35-80 µM.

Crystallization and preliminary X-ray study of alanine dehydrogenase from Bacillus pseudofirmus OF4.

Alanine dehydrogenase (OF4Ald) from the alkaliphilic Bacillus pseudofirmus OF4 was expressed and purified with a His6 tag in a form suitable for X-ray crystallographic analysis. Crystals were grown by the hanging-drop vapour-diffusion method at 289 K using a solution consisting of 0.1 M Tris-HCl pH 8.0, 0.2 M LiSO4, 22%(w/v) PEG 3350. X-ray diffraction data were collected to 2.8 Šresolution. The crystal belonged to the triclinic space group P1, with unit-cell parameters a = 88.04, b = 105.59, c = 120.53 Å, α = 88.37, ß = 78.77, γ = 82.65°.

Crystallization and preliminary X-ray analysis of an alanine dehydrogenase from Bacillus megaterium WSH-002.

Alanine dehydrogenase (L-AlaDH) from Bacillus megaterium WSH-002 catalyses the NAD⁺-dependent interconversion of L-alanine and pyruvate. The enzyme was expressed in Escherichia coli BL21 (DE3) cells and purified with a His6 tag by Ni²âº-chelating affinity chromatography for X-ray crystallographic analysis. Crystals were grown in a solution consisting of 0.1 M HEPES pH 8.0, 12%(w/v) polyethylene glycol 8000, 8%(v/v) ethylene glycol at a concentration of 15 mg ml⁻¹ purified protein. The crystal diffracted to 2.35 Å resolution and belonged to the trigonal space group R32, with unit-cell parameters a = b = 125.918, c = 144.698 Å.

Molecular dynamics simulations of the coenzyme induced conformational changes of Mycobacterium tuberculosis L-alanine dehydrogenase.

Mycobacterium tuberculosis L-alanine dehydrogenase (L-MtAlaDH) catalyzes the NADH-dependent reversible oxidative deamination of L-alanine to pyruvate and ammonia. L-MtAlaDH has been proposed to be a potential target in the treatment of tuberculosis. Based on the crystal structures of this enzyme, molecular dynamics simulations were performed to investigate the conformational changes of L-MtAlaDH induced by coenzyme NADH. The results show that the presence of NADH in the binding domain restricts the motions and conformational distributions of L-MtAlaDH. There are two loops (residues 94-99 and 238-251) playing important roles for the binding of NADH, while another loop (residues 267-293) is responsible for the binding of substrate. The opening/closing and twisting motions of two domains are closely related to the conformational changes of L-MtAlaDH induced by NADH.

Overexpression, purification, crystallization and preliminary X-ray analysis of Rv2780 from Mycobacterium tuberculosis H37Rv.

Rv2780, an alanine dehydrogenase from Mycobacterium tuberculosis (MtAlaDH), catalyzes the NAD-dependent interconversion of alanine and pyruvate. Alanine dehydrogenase is released into the culture medium in substantial amounts by virulent strains of mycobacteria and is not found in the vaccine strain of tuberculosis. Crystals of recombinant MtAlaDH were grown from 2 M ammonium sulfate solution at approximately 12 mg ml(-1) protein concentration in two crystal forms which occur in the presence and absence of NAD/pyruvate, respectively. Diffraction data extending to 2.6 A were collected at room temperature from both apo and ternary complex crystals. Crystals of the apoenzyme have unit-cell parameters a = 173.89, b = 127.07, c = 135.95 A. They are rod-like in shape and belong to space group C2. They contain a hexamer in the asymmetric unit. Crystals of the ternary complex belong to space group P4(3)2(1)2 and have unit-cell parameters a = b = 88.99, c = 373.85 A. There are three subunits in the asymmetric unit of the holoenzyme crystals.

Three-dimensional structures of apo- and holo-L-alanine dehydrogenase from Mycobacterium tuberculosis reveal conformational changes upon coenzyme binding.

L-alanine dehydrogenase from Mycobacterium tuberculosis catalyzes the NADH-dependent reversible conversion of pyruvate and ammonia to L-alanine. Expression of the gene coding for this enzyme is up-regulated in the persistent phase of the organism, and alanine dehydrogenase is therefore a potential target for pathogen control by antibacterial compounds. We have determined the crystal structures of the apo- and holo-forms of the enzyme to 2.3 and 2.0 A resolution, respectively. The enzyme forms a hexamer of identical subunits, with the NAD-binding domains building up the core of the molecule and the substrate-binding domains located at the apical positions of the hexamer. Coenzyme binding stabilizes a closed conformation where the substrate-binding domains are rotated by about 16 degrees toward the dinucleotide-binding domains, compared to the open structure of the apo-enzyme. In the structure of the abortive ternary complex with NAD+ and pyruvate, the substrates are suitably positioned for hydride transfer between the nicotinamide ring and the C2 carbon atom of the substrate. The approach of the nucleophiles water and ammonia to pyruvate or the reaction intermediate iminopyruvate, respectively, is, however, only possible through conformational changes that make the substrate binding site more accessible. The crystal structures identified the conserved active-site residues His96 and Asp270 as potential acid/base catalysts in the reaction. Amino acid replacements of these residues by site-directed mutagenesis led to inactive mutants, further emphasizing their essential roles in the enzymatic reaction mechanism.