Structure of an active soluble mutant of the membrane-associated (S)-mandelate dehydrogenase

The structure of an active mutant of (S)-mandelate dehydrogenase (MDH-GOX2) from Pseudomonas putida has been determined at 2.15 A resolution. The membrane-associated flavoenzyme (S)-mandelate dehydrogenase (MDH) catalyzes the oxidation of (S)-mandelate to give a flavin hydroquinone intermediate which is subsequently reoxidized by an organic oxidant residing in the membrane. The enzyme was rendered soluble by replacing its 39-residue membrane-binding peptide segment with a corresponding 20-residue segment from its soluble homologue, glycolate oxidase (GOX). Because of their amphipathic nature and peculiar solubilization properties, membrane proteins are notoriously difficult to crystallize, yet represent a large fraction of the proteins encoded by genomes currently being deciphered. Here we present the first report of such a structure in which an internal membrane-binding segment has been replaced, leading to successful crystallization of the fully active enzyme in the absence of detergents. This approach may have general application to other membrane-bound proteins. The overall fold of the molecule is that of a TIM barrel, and it forms a tight tetramer within the crystal lattice that has circular 4-fold symmetry. The structure of MDH-GOX2 reveals how this molecule can interact with a membrane, although it is limited by the absence of a membrane-binding segment. MDH-GOX2 and GOX adopt similar conformations, yet they retain features characteristic of membrane and globular proteins, respectively. MDH-GOX2 has a distinctly electropositive surface capable of interacting with the membrane, while the opposite surface is largely electronegative. GOX shows no such pattern. MDH appears to form a new class of monotopic integral membrane protein that interacts with the membrane through coplanar electrostatic binding surfaces and hydrophobic interactions, thus combining features of both the prostaglandin synthase/squaline-hopine cyclase and the C-2 coagulation factor domain classes of membrane proteins.     

High resolution structures of an oxidized and reduced flavoprotein. The water switch in a soluble form of (S)-mandelate dehydrogenase

The crystal structures of a soluble mutant of the flavoenzyme mandelate dehydrogenase (MDH) from Pseudomonas putida and of the substrate-reduced enzyme have been analyzed at 1.35-A resolution. The mutant (MDH-GOX2) is a fully active chimeric enzyme in which residues 177-215 of the membrane-bound MDH are replaced by residues 176-195 of glycolate oxidase from spinach. Both structures permit full tracing of the polypeptide backbone chain from residues 4-356, including a 4-residue segment that was disordered in an earlier study of the oxidized protein at 2.15 A resolution. The structures of MDH-GOX2 in the oxidized and reduced states are virtually identical with only a slight increase in the bending angle of the flavin ring upon reduction. The only other structural changes within the protein interior are a 10 degrees rotation of an active site tyrosine side chain, the loss of an active site water, and a significant movement of six other water molecules in the active site by 0.45 to 0.78 A. Consistent with solution studies, there is no apparent binding of either the substrate, mandelate, or the oxidation product, benzoylformate, to the reduced enzyme. The observed structural changes upon enzyme reduction have been interpreted as a rearrangement of the hydrogen bonding pattern within the active site that results from binding of a proton to the N-5 position of the anionic hydroquinone form of the reduced flavin prosthetic group. Implications for the low oxidase activity of the reduced enzyme are also discussed.     

Crystal structure analysis of recombinant rat kidney long chain hydroxy acid oxidase

Long chain hydroxy acid oxidase (LCHAO) is a member of an FMN-dependent enzyme family that oxidizes L-2-hydroxy acids to ketoacids. LCHAO is a peroxisomal enzyme, and the identity of its physiological substrate is unclear. Mandelate is the most efficient substrate known and is commonly used in the test tube. LCHAO differs from most family members in that one of the otherwise invariant active site residues is a phenylalanine (Phe23) instead of a tyrosine. We now report the crystal structure of LCHAO. It shows the same beta8alpha8 TIM barrel structure as other structurally characterized family members, e.g., spinach glycolate oxidase (GOX) and the electron transferases yeast flavocytochrome b2 (FCB2) and Pseudomonas putida mandelate dehydrogenase (MDH). Loop 4, which is mobile in other family members, is visible in part. An acetate ion is present in the active site. The flavin interacts with the protein in the same way as in the electron transferases, and not as in GOX, an unexpected observation. An interpretation is proposed to explain this difference between GOX on one hand and FCB2 and LCHAO on the other hand, which had been proposed to arise from the differences between family members in their reactivity with oxygen. A comparison of models of the substrate bound to various published structures suggests that the very different reactivity with mandelate of LCHAO, GOX, FCB2, and MDH cannot be rationalized by a hydride transfer mechanism.     

Malate dehydrogenase from the thermophilic green bacterium Chloroflexus aurantiacus: purification, molecular weight, amino acid composition, and partial amino acid sequence.

Malate dehydrogenase (MDH; EC 1.1.1.37) from the thermophilic green nonsulfur bacterium Chloroflexus aurantiacus was purified by a two-step procedure involving affinity chromatography and gel filtration. The enzyme consists of identical subunits which had molecular weights of approximately 35,000. In its active form at 55 degrees C, it formed tetramers. At lower temperatures, inactive dimers and trimers existed. Antibodies against the purified enzyme were produced, and immunotitration and enzyme-linked immunosorbent assays showed that there was an immunochemical homology between the MDH from C. aurantiacus and MDHs from several other bacteria. The amino acid composition of C. aurantiacus MDH was similar to those of other MDHs. The N-terminal amino acid sequence was enriched with hydrophobic amino acids, which showed a high degree of functional similarity to amino acids at the N-terminal ends of both Escherichia coli and Thermus flavus MDHs. The activity of the native enzyme was inhibited by high concentrations of substrate and had temperature and pH optima consistent with the optimal growth conditions for the organism.     

Construction of Engineered Water-soluble PQQ Glucose Dehydrogenase with Improved Substrate Specificity

This was the first study that achieved a narrowing of the substrate specificity of water soluble glucose dehydrogenase harboring pyrroloquinoline quinone as their prosthetic group, PQQGDH-B. We conducted the introduction of amino acid substitutions into the loop 6BC region of the enzyme, which made up the active site cleft without directly interacting with the substrate, and constructed a series of site directed mutants. Among these mutants, Asn452Thr showed the least narrowed substrate specificity while retaining a similar catalytic efficiency, thermal stability and EDTA tolerance as the wild-type enzyme. The relative activities of mutant enzyme with lactose were lower than that of the wild-type enzyme. The altered substrate specificity profile of the mutant enzyme was found to be mainly due to increase in Km value for substrate than glucose. The predicted 3D structures of Asn452Thr and the wild-type enzyme indicated that the most significant impact of the amino acid substitution was observed in the interaction between the 6BC loop region with lactose.     

Maximization of production of his-tagged glycine oxidase and its M261 mutant proteins

Glycine oxidase (GOX) from Bacillus subtilis is a new flavoprotein of great potential biotechnological use that catalizes the oxidative deamination of various amines (glycine, sarcosine, and N-ethyl-glycine) and D-amino acids (D-alanine and D-proline). However, its commercial application is hindered by its low heterologous expression in Escherichia coli due to its codon bias and the sensitivity of its N-terminus to proteases. The first problem has been solved by cloning the GOX gene from B. subtilis ATCC 6633 into the Rosetta E. coli strain, which contains the pRARE plasmid. The second problem was overcome by inserting the gene in the pET28a expression vector, which not only has a 6 x His tag but also increases the N-terminus in 36 amino acids without impairing either the enzymatic activity or the ribosome binding region. After induction with 0.5 mM isopropyl thio-beta-D-galactoside for 5 h in TB-medium, the soluble and active chimeric GOX was expressed up to 15.81 U x g(-1) cell, with a fermentation yield of 399 U x L(-1). The latter value represents about 16% of the total soluble protein content of the cell. The three latter values are higher than the best found in the literature by 16-, 28- and 4-fold, respectively. The enzyme was purified with a nickel HiTrap chelating-affinity column in 96% yield to apparent homogeneity. It was fully active and was stable for months at -80 degrees C in the presence of 10% glycerol. Its substrate specificity was similar to that previously described, but the constructed M261 mutants unexpectedly decreased in K(M) compared with the wild-type, especially in the M261Y mutant. Noteworthy, there was decrease in the K(M) for N-ethyl-glycine of up to 0.7 mM, similar to that found with N-alkyl-glycine oxidase. Such mutants open up new possible uses of this enzyme not only in the pharmacological industry but also in the clinical field for diabetic complications.     

Construction of Engineered Water-soluble PQQ Glucose Dehydrogenase with Improved Substrate Specificity

This was the first study that achieved a narrowing of the substrate specificity of water soluble glucose dehydrogenase harboring pyrroloquinoline quinone as their prosthetic group, PQQGDH-B. We conducted the introduction of amino acid substitutions into the loop 6BC region of the enzyme, which made up the active site cleft without directly interacting with the substrate, and constructed a series of site directed mutants. Among these mutants, Asn452Thr showed the least narrowed substrate specificity while retaining a similar catalytic efficiency, thermal stability and EDTA tolerance as the wild-type enzyme. The relative activities of mutant enzyme with lactose were lower than that of the wild-type enzyme. The altered substrate specificity profile of the mutant enzyme was found to be mainly due to increase in Km value for substrate than glucose. The predicted 3D structures of Asn452Thr and the wild-type enzyme indicated that the most significant impact of the amino acid substitution was observed in the interaction between the 6BC loop region with lactose.     

From malate dehydrogenase to phenyllactate dehydrogenase. Incorporation of unnatural amino acids to generate an improved enzyme-catalyzed activity

Malate dehydrogenase (MDH) from Escherichia coli is highly specific for its keto acid substrate. The placement of the active site-binding groups in MDH effectively discriminates against both the shorter and the longer keto dicarboxylic acids that could potentially serve as alternative substrates. A notable exception to this specificity is the alternative substrate phenylpyruvate. This aromatic keto acid can be reduced by MDH, albeit at a somewhat slower rate and with greatly diminished affinity, despite the presence of several substrate-binding arginyl residues and the absence of a hydrophobic pocket in the active site. The specificity of MDH for phenylpyruvate has now been enhanced, and that for the physiological substrate oxaloacetate has been diminished, through the replacement of one of the binding arginyl residues with several unnatural alkyl and aryl amino acid analogs. This approach, called site-specific modulation, incorporates systematic structural variations at a site of interest. Molecular modeling studies have suggested a structural basis for the affinity of native MDH for phenylpyruvate and a rationale for the improved catalytic activity that is observed with these new, modified phenyllactate dehydrogenases.     

Aromatic amino acid catabolism in trypanosomatids

Trypanosomatids cause important human diseases, like sleeping sickness, Chagas disease, and the leishmaniases. Unlike in the mammalian host, the metabolism of aromatic amino acids is a very simple pathway in these parasites. Trypanosoma brucei and Trypanosoma cruzi transaminate the three aromatic amino acids, the resulting 2-oxo acids being reduced to the corresponding lactate derivatives and excreted. In T. cruzi, two enzymes are involved in this process: a tyrosine aminotransferase (TAT), which despite a high sequence similarity with the mammalian enzyme, has a different substrate specificity; and an aromatic L-2-hydroxyacid dehydrogenase (AHADH), which belongs to the subfamily of the cytosolic malate dehydrogenases (MDHs), yet has no MDH activity. In T. cruzi AHADH the substitution of Ala102 for Arg enables AHADH to reduce oxaloacetate. In the members of the 2-hydroxyacid dehydrogenases family, the residue at this position is known to be responsible for substrate specificity. T. cruzi does not possess a cytosolic MDH but contains a mitochondrial and a glycosomal MDH; by contrast T. brucei and Leishmania spp. possess a cytosolic MDH in addition to glycosomal and mitochondrial isozymes. Although Leishmania mexicana also transaminates aromatic amino acids through a broad specificity aminotransferase, the latter presents low sequence similarity with TATs, and this parasite does not seem to have an enzyme equivalent to T. cruzi AHADH. Therefore, these closely related primitive eukaryotes have developed aromatic amino acid catabolism systems using different enzymes and probably for different metabolic purposes.     

Cloning and overexpression of Lactobacillus helveticus D-lactate dehydrogenase gene in Escherichia coli.

NAD(+)-dependent D-lactate dehydrogenase from Lactobacillus helveticus was purified to apparent homogeneity, and the sequence of the first 36 amino acid residues determined. Using forward and reverse oligonucleotide primers, based on the N-terminal sequence and amino acid residues 220-215 of the Lactobacillus bulgaricus enzyme [Kochhar, S., Hunziker, P. E., Leong-Morgenthaler, P. & Hottinger, H. (1992) J. Biol. Chem. 267, 8499-8513], a 0.6-kbp DNA fragment was amplified from L. helveticus genomic DNA by the polymerase chain reaction. This amplified DNA fragment was used as a probe to identify two recombinant clones containing the D-lactate dehydrogenase gene. Both plasmids overexpressed D-lactate dehydrogenase (greater than 60% total soluble cell protein) and were stable in Escherichia coli, compared to plasmids carrying the L. bulgaricus and Lactobacillus plantarum genes. The entire nucleotide sequence of the L. helveticus D-lactate dehydrogenase gene was determined. The deduced amino acid sequence indicated a polypeptide consisting of 336 amino acid residues, which showed significant amino acid sequence similarity to the recently identified family of D-2-hydroxy-acid dehydrogenases [Kochhar, S., Hunziker, P. E., Leong-Morgenthaler, P. & Hottinger, H. (1992) Biochem. Biophys. Res. Commun. 184, 60-66]. The physicochemical and catalytic properties of recombinant D-lactate dehydrogenase were identical to those of the wild-type enzyme, e.g. alpha 2 dimeric subunit structure, isoelectric pH, Km and Kcat for pyruvate and other 2-oxo-acid substrates. The kinetic profiles of 2-oxo-acid substrates showed some marked differences from that of L-lactate dehydrogenase, suggesting different mechanisms for substrate binding and specificity.     

Preparation of a very stable immobilized biocatalyst of glucose oxidase from Aspergillus niger

Glucose oxidase (GOX) has been immobilized on different activated supports, including glyoxyl agarose, epoxy sepabeads and glutaraldehyde-activated supports. Immobilization onto supports pre-activated with glutaraldehyde rendered the most thermo-stable preparation of GOX. Therefore, as the glutaraldehyde chemistry gave a high stabilization of the enzyme, we proposed another technique for improving the multipoint attachment through glutaraldehyde: the enzyme was ionically adsorbed on cationic supports with primary amino groups and then the immobilized preparation was treated with a glutaraldehyde solution. The decrease on enzyme activity was <20%. Following this methodology, we achieved the highest stability of all the immobilization systems analyzed, showing a half-life 100 times higher than the soluble enzyme. Moreover, this derivative showed a higher stability in the presence of organic solvents (for instance methanol) or hydrogen epoxide than the ionically adsorbed enzyme or the soluble one. Therefore, the adsorption of GOX on aminated cationic support and subsequent treatment with glutaraldehyde was presented as a very successful methodology for achieving a very stable biocatalyst.     

High-level production of bacillus subtilis glycine oxidase by fed-batch cultivation of recombinant Escherichia coli Rosetta (DE3)

A fed-batch process for the high cell density cultivation of Escherichia coli Rosetta (DE3) and the production of the recombinant protein glycine oxidase (GOX) from Bacillus subtilis was developed. GOX is a deaminating enzyme that shares substrate specificity with d-amino acid oxidase and sarcosine oxidase and has great biotechnological potential. The B. subtilis gene coding for GOX was expressed in E. coli Rosetta under the strong inducible T7 promotor of the pET28a vector. Exponential feeding based on the specific growth rate and a starvation period for acetate utilization was used to control cell growth, acetate production, and reconsumption and glucose consumption during fed-batch cultivation. Expression of GOX was induced at three different cell densities (20, 40, and 60 g . L(-1)). When cells were induced at intermediate cell density, the amount of GOX produced was 20 U . g(-1) cell dry weight and 1154 U . L(-1) with a final intracellular protein concentration corresponding to approximately 37% of the total cell protein concentration. These values were higher than those previously published for GOX expression and also represent a drastic decrease of 26-fold in the cost of the culture medium.     

Characterization and sequence of the Escherichia coli panBCD gene cluster

Abstract A metabolic key enzyme malate dehydrogenase (MDH) was purified from a deep-sea psychrophilic bacterium, Vibrio sp. strain no. 5710. The enzyme displayed an optimal activity shifted toward lower temperature and a pronounced heat lability. A gene encoding this enzyme was isolated and cloned. Recombinant Escherichia coli cells harboring the isolated clone expressed MDH activity with temperature stability identical to that of the parental psychrophile. Nucleotide sequencing of the gene revealed that its primary sequence was similar to that of a mesophile E. coli MDH (78% amino acid identity), for which the three-dimensional structure is known. The enzyme is thus suitable for the analysis of molecular adaptations to low temperatures.     

Characterization of a novel soluble c-type cytochrome in a moxD mutant of Methylobacterium extorquens AM1

Methylobacterium extorquens AM1 contains a novel c-type cytochrome, called cytochrome c-553, previously thought to be a precursor of the electron acceptor (cytochrome cL) for methanol dehydrogenase. Its amino acid composition and serological characteristics show that it has no structural relationship to cytochrome cL. It usually comprises less than 5% of the total c-type cytochromes. In a moxD mutant, which contains neither methanol dehydrogenase nor cytochrome cL, it comprises 30% of the soluble cytochrome and it has been purified and characterized from that mutant. Cytochrome c-553 is large (Mr 23,000), acidic and monohaem, with a redox potential of 194 mV. It reacts rapidly and completely with CO but is not autoxidizable. It is not autoreducible, and it is not an electron acceptor from methanol dehydrogenase or methylamine dehydrogenase, nor an important electron donor to the oxidase. It is able to accept electrons from cytochrome cL and to donate electrons to cytochrome cH. It is present in the soluble fraction (presumably periplasmic) and membrane fraction of wild-type bacteria during growth on a wide range of growth substrates, but its function in these bacteria or in the moxD mutant has not been determined.     

Expression and function of heterologous forms of malate dehydrogenase in yeast.

The structure of the tricarboxylic acid cycle enzyme malate dehydrogenase is highly conserved in various organisms. To test the extent of functional conservation, the rat mitochondrial enzyme and the enzyme from Escherichia coli were expressed in a strain of Saccharomyces cerevisiae containing a disruption of the chromosomal MDH1 gene encoding yeast mitochondrial malate dehydrogenase. The authentic precursor form of the rat enzyme, expressed using a yeast promoter and a multicopy plasmid, was found to be efficiently targeted to yeast mitochondria and processed to a mature active form in vivo. Mitochondrial levels of the polypeptide and malate dehydrogenase activity were found to be similar to those for MDH1 in wild-type yeast cells. Efficient expression of the E. coli mdh gene was obtained with multicopy plasmids carrying gene fusions encoding either a mature form of the procaryotic enzyme or a precursor form with the amino terminal mitochondrial targeting sequence from yeast MDH1. Very low levels of mitochondrial import and processing of the precursor form were obtained in vivo and activity could be demonstrated for only the expressed precursor fusion protein. Results of in vitro import experiments suggest that the percursor form of the E. coli protein associates with yeast mitochondria but is not efficiently internalized. Respiratory rates measured for isolated yeast mitochondria containing the mammalian or procaryotic enzyme were, respectively, 83 and 62% of normal, suggesting efficient delivery of NADH to the respiratory chain. However, expression of the heterologous enzymes did not result in full complementation of growth phenotypes associated with disruption of the yeast MDH1 gene.     

荧光假单胞菌TM5-2中D-型氨基酸脱氢酶的鉴定和表达

从荧光假单胞菌TM5-2中得到一个含丙氨酸消旋酶基因的DNA片段(8.8kb),相邻的一个开读框(ORF)与甘氨酸/D-型氨基酸氧化酶基因相似。该ORF经过克隆、表达,并没有检测到甘氨酸/D-型氨基酸氧化酶的活性,推导而得的氨基酸序列与D-型氨基酸脱氢酶序列比较发现,ORF含有D-型氨基酸脱氢酶的所有重要的保守序列。经TTC培养基鉴定,其具有D-型氨基酸脱氢酶的活性,并对一系列D-型氨基酸有作用,最佳作用底物是D-组氨酸。     

Binding of pyruvate oxidase alpha-peptide to phospholipid vesicles

The alpha-peptide of pyruvate oxidase is a 23 residue peptide which is cleaved from the carboxy terminus of the enzyme during proteolytic activation by chymotrypsin (M. Recny et al. (1985) J. Biol. Chem. 260, 14287-14291). Cleavage of alpha-peptide results in the loss of the high affinity lipid-binding site in the enzyme. The beta-peptide of pyruvate oxidase is a 101 residue peptide which also is cleaved from the carboxy terminus of pyruvate oxidase. Cleavage of the beta-peptide from pyruvate oxidase results in the inactivation of the enzyme. The beta-peptide includes the alpha-peptide amino acid sequences at its carboxyl terminus. We now report on the binding of the alpha- and beta-peptides to phospholipid vesicles. Both peptides bind with equal and high affinity to phosphatidylcholine vesicles. We conclude from these results that the alpha-peptide furnishes the membrane-binding site which plays the physiologically important role in the activation of this peripheral membrane enzyme.     

Cyanobacterial lactate oxidases serve as essential partners in N2 fixation and evolved into photorespiratory glycolate oxidases in plants

Glycolate oxidase (GOX) is an essential enzyme involved in photorespiratory metabolism in plants. In cyanobacteria and green algae, the corresponding reaction is catalyzed by glycolate dehydrogenases (GlcD). The genomes of N(2)-fixing cyanobacteria, such as Nostoc PCC 7120 and green algae, appear to harbor genes for both GlcD and GOX proteins. The GOX-like proteins from Nostoc (No-LOX) and from Chlamydomonas reinhardtii showed high L-lactate oxidase (LOX) and low GOX activities, whereas glycolate was the preferred substrate of the phylogenetically related At-GOX2 from Arabidopsis thaliana. Changing the active site of No-LOX to that of At-GOX2 by site-specific mutagenesis reversed the LOX/GOX activity ratio of No-LOX. Despite its low GOX activity, No-LOX overexpression decreased the accumulation of toxic glycolate in a cyanobacterial photorespiratory mutant and restored its ability to grow in air. A LOX-deficient Nostoc mutant grew normally in nitrate-containing medium but died under N(2)-fixing conditions. Cultivation under low oxygen rescued this lethal phenotype, indicating that N(2) fixation was more sensitive to O(2) in the Δlox Nostoc mutant than in the wild type. We propose that LOX primarily serves as an O(2)-scavenging enzyme to protect nitrogenase in extant N(2)-fixing cyanobacteria, whereas in plants it has evolved into GOX, responsible for glycolate oxidation during photorespiration.