Solvent isotope and viscosity effects on the steady-state kinetics of the flavoprotein nitroalkane oxidase

The flavoprotein nitroalkane oxidase catalyzes the oxidative denitrification of a broad range of primary and secondary nitroalkanes to yield the respective aldehydes or ketones, hydrogen peroxide and nitrite. With nitroethane as substrate the ^D2O(k_cat/K_M) value is 0.6 and the ^D2Ok_cat value is 2.4. The k_cat proton inventory is consistent with a single exchangeable proton in flight, while the k_cat/K_M is consistent with either a single proton in flight in the transition state or a medium effect. Increasing the solvent viscosity did not affect the k_cat or k_cat/K_M value significantly, establishing that nitroethane binding is at equilibrium and that product release does not limit k_cat.     

Role of amine oxidase expression to maintain putrescine homeostasis in Rhodococcus opacus

While applications of amine oxidases are increasing, few have been characterised and our understanding of their biological role and strategies for bacteria exploitation are limited. By altering the nitrogen source (NH₄Cl, putrescine and cadaverine (diamines) and butylamine (monoamine)) and concentration, we have identified a constitutive flavin dependent oxidase (EC 1.4.3.10) within Rhodococcus opacus. The activity of this oxidase can be increased by over two orders of magnitude in the presence of aliphatic diamines. In addition, the expression of a copper dependent diamine oxidase (EC 1.4.3.22) was observed at diamine concentrations > 1 mM or when cells were grown with butylamine, which acts to inhibit the flavin oxidase. A Michaelis–Menten kinetic treatment of the flavin oxidase delivered a Michaelis constant (K_M) = 190 μM and maximum rate (k_cat) = 21.8 s^?1 for the oxidative deamination of putrescine with a lower K_M (=60 μM) and comparable k_cat (=18.2 s^?1) for the copper oxidase. MALDI–TOF and genomic analyses have indicated a metabolic clustering of functionally related genes. From a consideration of amine oxidase specificity and sequence homology, we propose a putrescine degradation pathway within Rhodococcus that utilises oxidases in tandem with subsequent dehydrogenase and transaminase enzymes. The implications of PUT homeostasis through the action of the two oxidases are discussed with respect to stressors, evolution and application in microbe-assisted phytoremediation or bio-augmentation.     

An evolutionally conserved Lys122 is essential for function in Rhodospirillum rubrum bona fide RuBisCO and Bacillus subtilis RuBisCO-like protein

Ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) and RuBisCO-like protein (RLP) catalyze similar enolase-type reactions. Both enzymes have a conserved non-catalytic Lys122 or Arg122 on the β-strand E lying in the interface between the N- and C-terminal domains. We used site-directed mutagenesis to analyze the function of Lys122 in the form II Rhodospirillum rubrum RuBisCO (RrRuBisCO) and Bacillus subtilis RLP (BsRLP). The K122R mutant of RrRuBisCO had a 40% decrease in k_cat for carboxylase activity, a 2-fold increase in K_m for CO₂, and a 1.9-fold increase in K_m for ribulose-1,5-bisphosphate. K122M and K122E mutants of RrRuBisCO were almost inactive. None of the substitutions affected the thermal stability of RrRuBisCO. The K122R mutant of BsRLP had a 32% decrease in k_cat and lower thermal stability than the wild-type enzyme. The K122M and K122E mutants of BsRLP failed to form a catalytic dimer. Our results suggest that the lysine residue is essential for function in both enzymes, although in each case, its role is likely distinct.     

FAD-binding site and NADP reactivity in human renalase: a new enzyme involved in blood pressure regulation

Renalase is a recently discovered flavoprotein that regulates blood pressure, regulates sodium and phosphate excretion, and displays cardioprotectant action through a mechanism that is barely understood to date. It has been proposed to act as a catecholamine-degrading enzyme, via either O₂-dependent or NADH-dependent mechanisms. Here we report the renalase crystal structure at 2.5 Å resolution together with new data on its interaction with nicotinamide dinucleotides. Renalase adopts the p-hydroxybenzoate hydroxylase fold topology, comprising a Rossmann-fold-based flavin adenine dinucleotide (FAD)-binding domain and a putative substrate-binding domain, the latter of which contains a five-stranded anti-parallel β-sheet. A large cavity (228 Å³), facing the flavin ring, presumably represents the active site. Compared to monoamine oxidase or polyamine oxidase, the renalase active site is fully solvent exposed and lacks an ‘aromatic cage’ for binding the substrate amino group. Renalase has an extremely low diaphorase activity, displaying lower k_cat but higher k_cat/K_m for NADH compared to NADPH. Moreover, its FAD prosthetic group becomes slowly reduced when it is incubated with NADPH under anaerobiosis, and binds NAD⁺ or NADP⁺ with K_d values of ca 2 mM. The absence of a recognizable NADP-binding site in the protein structure and its poor affinity for, and poor reactivity towards, NADH and NADPH suggest that these are not physiological ligands of renalase. Although our study does not answer the question on the catalytic activity of renalase, it provides a firm framework for testing hypotheses on the molecular mechanism of its action.     

Intramolecular electron transfer rate between active-site copper and TPQ in Arthrobacter globiformis amine oxidase

Copper amine oxidases catalyze the oxidative deamination of primary amines operating through a ping-pong bi bi mechanism, divided into reductive and oxidative half-reactions. Considerable debate still exists regarding the role of copper in the oxidative half-reaction, where O₂ is reduced to H₂O₂. Substrate-reduced amine oxidases display an equilibrium between a Cu(II) aminoquinol and a Cu(I) semiquinone, with the magnitude of the equilibrium constant being dependent upon the enzyme source. The initial electron transfer to dioxygen has been proposed to occur from either the reduced Cu(I) center or the reduced aminoquinol cofactor. In order for Cu(I) to be involved, it must be shown that the rate of electron transfer (k _ET) between the aminoquinol and Cu(II) is sufficiently rapid to place the Cu(I) semiquinone moiety on the mechanistic pathway. To further explore this issue, we measured the intramolecular electron transfer rate for the Cu(II) aminoquinol ⇆ Cu(I) semiquinone equilibrium in Arthrobacter globiformis amine oxidase (AGAO) by temperature-jump relaxation techniques. The results presented herein establish that k _ET is greater than the rate of catalysis (k _cat) for the preferred amine substrate β-phenylethylamine at three pH values, thereby permitting the Cu(I) semiquinone to be a viable catalytic intermediate during enzymatic reoxidation in this enzyme. The data show that k _ET is approximately equivalent at pH 6.2 and 7.2, being 2.5 times k _cat for these pH values. At pH 8.2, however, k _ET decreases, becoming comparable to k _cat. Potential reasons for the decreased k _ET at basic pH are presented. The implications of these results in light of a previously published study measuring reoxidation rates of substrate-reduced AGAO are also addressed.     

A thermostable triple mutant of pyranose 2-oxidase from Trametes multicolor with improved properties for biotechnological applications

In order to increase the thermal stability and the catalytic properties of pyranose oxidase (P2Ox) from Trametes multicolor toward its poor substrate D-galactose and the alternative electron acceptor 1,4-benzoquinone (1,4-BQ), we designed the triple-mutant T169G/E542K/V546C. Whereas the wild-type enzyme clearly favors D-glucose as its substrate over D-galactose [substrate selectivity (k_cat/K_M)_Glc/(k_cat/K_M)_Gal = 172], the variant oxidizes both sugars equally well [(k_cat/K_M)_Glc/(k_cat/K_M)_Gal = 0.69], which is of interest for food biotechnology. Furthermore, the variant showed lower K_M values and approximately ten-fold higher k_cat values for 1,4-BQ when D-galactose was used as the saturating sugar substrate, which makes this enzyme particularly attractive for use in biofuel cells and enzyme-based biosensors. In addition to the altered substrate specificity and reactivity, this mutant also shows significantly improved thermal stability. The half life time at 60°C was approximately 10 h, compared to 7.6 min for the wild-type enzyme. We performed successfully small-scale bioreactor pilot conversion experiments of D -glucose/D -galactose mixtures at both 30 and 50°C, showing the usefulness of this P2Ox variant in biocatalysis as well as the enhanced thermal stability of the enzyme. Moreover, we determined the crystal structure of the mutant in its unligated form at 1.55 Å resolution. Modeling D-galactose in position for oxidation at C2 into the mutant active site shows that substituting Thr for Gly at position 169 favorably accommodates the axial C4 hydroxyl group that would otherwise clash with Thr169 in the wild-type.     

Histidine as an essential residue in the active site of the copper enzyme galactose oxidase.

The pH dependence of the oxidation of β-methyl-d-galactopyranoside by galactose oxidase at 1.33 mm O₂ has been determined. The k_cat exhibits a bell-shaped dependence on the ionization of at least two groups in the enzyme-substrate complex, pK_b' = 6.3 and pK_a' = 7.1, respectively. The pH-independent value for k_cat at 1.33 mm O₂ (nonsaturating) and saturating glycoside is 1435 s^?; the pH optimum is 6.7. Galactose oxidase is inactivated rapidly by iodoacetamide. Although the reaction is much slower, iodoacetate also inactivates the enzyme. The inactivation by iodoacetamide obeys saturation kinetics; at pH 7.0 k₃ = 2.19 min^?1 and K_i = 5.1 mM; k₃ but not K_i exhibits a bell-shaped pH dependence, with pK_a values of 6.3 and 7.6, respectively. Labeling with [¹⁴C]iodoacetamide establishes that one carboxamidomethyl group is incorporated per enzyme molecule. This incorporation parallels the loss of enzymatic activity. Only N-3-carboxymethylhistidine is detected in chromatograms following hydrolysis of the labeled protein. The protein-bound copper is not lost as a consequence of alkylation. Apogalactose oxidase does not react with iodoacetamide. The alkylation is inhibited by the oxidation of an active center tryptophan residue (s) by N-bromosuccinimide. The fraction of residual enzyme activity remaining after tryptophan oxidation corresponds to the extent of labeling by [¹⁴C]iodoacetamide. Although alkylation causes little change in the spin Hamiltonian parameters of the Cu(II) atom, it nearly abolishes both the optical activity and optical absorbance of the metal. The native tryptophan fluorescence of the enzyme, which is a sensitive probe of its active site, is also markedly affected. Since binding of a substrate, β-methyl-d-galactopyranoside, reduces fluorescence as it does in the active enzyme and binding of CN^? at the Cu(II) site as detected by electron spin resonance appears unaffected by the alkylation, the effect of alkylation is on catalysis, per se. Both a catalytic and a subtle conformational role for the active site histidine are inferred from the results.     

Steady-state kinetic mechanism of LodA,a novel cysteine tryptophylquinone-dependent oxidase

LodA is a novel lysine-ε-oxidase which possesses a cysteine tryptophylquinone cofactor. It is the first tryptophylquinone enzyme known to function as an oxidase. A steady-state kinetic analysis shows that LodA obeys a ping-pong kinetic mechanism with values of k_cat of 0.22 ± 0.04 s⁻¹, K_lysine of 3.2 ± 0.5 μM and K_O2 of 37.2 ± 6.1 μM. The k_cat exhibited a pH optimum at 7.5 while k_cat/K_lysine peaked at 7.0 and remained constant to pH 8.5. Alternative electron acceptors could not effectively substitute for O₂ in the reaction. A mechanism for the reductive half reaction of LodA is proposed that is consistent with the ping-pong kinetics.     

Continuous colorimetric screening assay for detection of d-amino acid aminotransferase mutants displaying altered substrate specificity

d-Amino acid aminotransferase (DAAT) catalyzes the synthesis of numerous d-amino acids, making it an attractive biocatalyst for the production of enantiopure d-amino acids. To bolster its biocatalytic applicability, improved variants displaying increased activity toward non-native substrates are desired. Here, we report the development of a high-throughput, colorimetric, continuous coupled enzyme assay for the screening of DAAT mutant libraries that is based on the use of d-amino acid oxidase (DAAO). In this assay, the d-amino acid product of DAAT is oxidized by DAAO with concomitant release of hydrogen peroxide, which is detected colorimetrically by the addition of horseradish peroxidase and o-dianisidine. Using this assay, we measured apparent K_M and k_cat values for DAAT and identified mutants displaying altered substrate specificity via the screening of cell lysates in 96-well plates. The DAAO coupled assay is sensitive in that it allowed the detection of a DAAT mutant displaying an approximately 2000-fold decrease in k_cat/K_M relative to wild type. In addition, the DAAO assay enabled the identification of two DAAT mutants (V33Y and V33G) that are more efficient than wild type at transaminating the non-native acceptor phenylpyruvate. We expect that this assay will be useful for the engineering of additional mutants displaying increased activity toward non-native substrates.     

Lys300 plays a major role in the catalytic mechanism of maize polyamine oxidase

Maize polyamine oxidase (MPAO) is a flavin adenine dinucleotide (FAD)-dependent enzyme that catalyses the oxidation of spermine and spermidine at the secondary amino groups. The structure of MPAO indicates a 30-A long U-shaped tunnel that forms the catalytic site, with residues Glu62 and Glu170 located close to the enzyme-bound FAD and residue Tyr298 in close proximity to Lys300, which in turn is hydrogen-bonded to the flavin N(5) atom via a water molecule (HOH309). To provide insight into the role of these residues in the catalytic mechanism of FAD reduction, we have performed steady-state and stopped-flow studies with wild-type, Glu62Gln, Glu170Gln, Tyr298Phe, and Lys300Met MPAO enzymes. We show that the steady-state enzyme activity is governed by an ionisable group with a macroscopic pK(a) of approximately 5.8. Kinetic analysis of the Glu62Gln, Glu170Gln, and Tyr298Phe MPAO enzymes have indicated (i) only small perturbations in catalytic activity as a result of mutation and (ii) steady-state pH profiles essentially unaltered when compared to the wild-type enzyme, suggesting that these residues do not play a critical role in the reaction mechanism. These kinetic observations are consistent with computational calculations that suggest that Glu62 and Glu170 are protonated over the pH range accessible to kinetic studies. Substitution of Lys300 with Met in MPAO resulted in a 1400-fold decrease in the rate of flavin reduction and a 160-fold decrease in the equilibrium dissociation constant for the Lys300Met-spermidine complex, consistent with a major role for this residue in the mechanism of substrate oxidation. A sizable solvent isotope effect (SIE = 5) accompanies FAD reduction in the wild-type enzyme and steady-state turnover (SIE = 2.3) of MPAO, consistent with the reductive half-reaction of MPAO making a major contribution to rate limitation in steady-state turnover. Studies using the enzyme-monitored turnover method indicate that oxidized FAD is the prominent form during steady-state turnover, consistent with the reductive half-reaction being rate-limiting. Our studies indicate the importance of Lys300 and probable importance of HOH309 to the mechanism of flavin reduction in MPAO. Possible roles for Lys300 and water in the mechanism of flavin reduction are discussed.     

Structural and kinetic studies on the Ser101Ala variant of choline oxidase: Catalysis by compromise

The oxidation of choline catalyzed by choline oxidase includes two reductive half-reactions where FAD is reduced by the alcohol substrate and by an aldehyde intermediate transiently formed in the reaction. Each reductive half-reaction is followed by an oxidative half-reaction where the reduced flavin is oxidized by oxygen. Here, we have used mutagenesis to prepare the Ser101Ala mutant of choline oxidase and have investigated the impact of this mutation on the structural and kinetic properties of the enzyme. The crystallographic structure of the Ser101Ala enzyme indicates that the only differences between the mutant and wild-type enzymes are the lack of a hydroxyl group on residue 101 and a more planar configuration of the flavin in the mutant enzyme. Kinetics established that replacement of Ser101 with alanine yields a mutant enzyme with increased efficiencies in the oxidative half-reactions and decreased efficiencies in the reductive half-reactions. This is accompanied by a significant decrease in the overall rate of turnover with choline. Thus, this mutation has revealed the importance of a specific residue for the optimization of the overall turnover of choline oxidase, which requires fine-tuning of four consecutive half-reactions for the conversion of an alcohol to a carboxylic acid.     

The effects of reversible freezing inactivation and inhibitor binding on redox properties of l-amino-acid oxidase

We measured the redox potentials of frozen inactivated l-amino-acid oxidase (l-amino-acid:oxygen oxidoreductase (deaminating), EC 1.4.3.2) and inhibitor-bound (anthranilic acid) enzyme, and compared these redox properties to those of active l-amino-acid oxidase and benzoate-bound d-amino-acid oxidase (EC 1.4.3.3), respectively. The redox properties of the inactive enzyme are similar to the properties of free flavin; the potential is within 0.015 V of free flavin and no radical stabilization is seen. This corresponds to the loss of most interactions between apoprotein and flavin. In contrast, the anthranilic acid lowers the amount of radical stabilized from 85% to 35%. The potentials are still 0.150 V positive of free flavin, indicating that in the presence of inhibitor, many flavin-protein interactions remain intact. The difference between this behavior and that of d-amino-acid oxidase bound to benzoate, where the amount of radical declined from 95% to 5%, is explained on the basis of the relative tightness of binding of apoprotein to FAD. d-Amino-acid oxidase apoprotein has a relatively low K_a (10⁶) for FAD, and benzoate has a relatively high K_a (10⁵) for the enzyme. Therefore, the binding of benzoate increases the tightness of FAD binding to apo-d-amino-acid oxidase (10¹¹), indicating significant changes in flavin-protein interactions. In contrast, apo-l-amino-acid oxidase binds flavin tightly (the K_a is greater than 10⁷) and the enzyme binds to anthranilate much less tightly, with a K_a of 10³. The l-amino-acid oxidase apoprotein binding to FAD is tight initially, and the binding of anthranilate changes it only slightly. Therefore, redox studies indicate that the ability of a flavoprotein to be regulated may be influenced by the strength of the interaction of flavin with the apoprotein, as well as the strength of interaction of the substrate or activator.     

Arginine 49 is a bifunctional residue important in catalysis and biosynthesis of monomeric sarcosine oxidase: a context-sensitive model for the electrostatic impact of arginine to lysine mutations

Monomeric sarcosine oxidase (MSOX) contains covalently bound FAD and catalyzes the oxidative demethylation of sarcosine ( N-methylglycine). The side chain of Arg49 is in van der Waals contact with the si face of the flavin ring; sarcosine binds just above the re face. Covalent flavin attachment requires a basic residue (Arg or Lys) at position 49. Although flavinylation is scarcely affected, mutation of Arg49 to Lys causes a 40-fold decrease in k cat and a 150-fold decrease in k cat/ K m sarcosine. The overall structure of the Arg49Lys mutant is very similar to wild-type MSOX; the side chain of Lys49 in the mutant is nearly congruent to that of Arg49 in the wild-type enzyme. The Arg49Lys mutant exhibits several features consistent with a less electropositive active site: (1) Charge transfer bands observed for mutant enzyme complexes with competitive inhibitors absorb at higher energy than the corresponding wild-type complexes. (2) The p K a for ionization at N(3)H of FAD is more than two pH units higher in the mutant than in wild-type MSOX. (3) The reduction potential of the oxidized/radical couple in the mutant is 100 mV lower than in the wild-type enzyme. The lower reduction potential is likely to be a major cause of the reduced catalytic activity of the mutant. Electrostatic interactions with Arg49 play an important role in catalysis and covalent flavinylation. A context-sensitive model for the electrostatic impact of an arginine to lysine mutation can account for the dramatically different consequences of the Arg49Lys mutation on MSOX catalysis and holoenzyme biosysnthesis.     

Expression of the NAD-dependent FDH1 β-subunit from Methylobacterium extorquens AM1 in Escherichia coli and its characterization

The efficient regeneration of nicotinamide cofactors is an important process for industrial applications because of their high cost and stoichiometric requirements. In this study, the FDH1 β-subunit of NAD-dependent formate dehydrogenase from Methylobacterium extorquens AM1 was heterologously expressed in Escherichia coli. It showed water-forming NADH oxidase (NOX-2) activity in the absence of its α-subunit. The β-subunit oxidized NADH and generated NAD⁺. The enzyme showed a low NADH oxidation activity (0.28 U/mg enzyme). To accelerate electron transfer from the enzyme to oxygen, four electron mediators were tested; flavin mononucleotide, flavin adenine dinucleotide, benzyl viologen (BV), and methyl viologen. All tested electron mediators increased enzyme activity; addition of 250 μM BV resulted in the largest increase in enzyme activity (9.98 U/mg enzyme; a 35.6-fold increase compared with that in the absence of an electron mediator). Without the aid of an electron mediator, the enzyme had a substrate-binding affinity for NADH (K _m) of 5.87 μM, a turnover rate (k _cat) of 0.24/sec, and a catalytic efficiency (k _cat/K _m) of 41.31/mM/sec. The addition of 50 μM BV resulted in a 22.75-fold higher turnover rate (k _cat, 5.46/sec) and a 2.64-fold higher catalytic efficiency (k _cat/K _m, 107.75/mM/sec).     

Evaluation of kinetic data: What the numbers tell us about PRMTs

Protein arginine N-methyltransferase (PRMT) kinetic parameters have been catalogued over the past fifteen years for eight of the nine mammalian enzyme family members. Like the majority of methyltransferases, these enzymes employ the highly ubiquitous cofactor S-adenosyl-l-methionine as a co-substrate to methylate arginine residues in peptidic substrates with an approximately 4-μM median K_M. The median values for PRMT turnover number (k_cat) and catalytic efficiency (k_cat/K_M) are 0.0051 s⁻¹ and 708 M⁻¹ s⁻¹, respectively. When comparing PRMT metrics to entries found in the BRENDA database, we find that while PRMTs exhibit high substrate affinity relative to other enzyme-substrate pairs, PRMTs display largely lower k_cat and k_cat/K_M values. We observe that kinetic parameters for PRMTs and arginine demethylase activity from dual-functioning lysine demethylases are statistically similar, paralleling what the broader enzyme families in which they belong reveal, and adding to the evidence in support of arginine methylation reversibility.     

Key aromatic residues at subsites + 2 and + 3 of glycoside hydrolase family 31 α-glucosidase contribute to recognition of long-chain substrates

Glycoside hydrolase family 31 α-glucosidases (31AGs) show various specificities for maltooligosaccharides according to chain length. Aspergillus niger α-glucosidase (ANG) is specific for short-chain substrates with the highest k_cat/K_m for maltotriose, while sugar beet α-glucosidase (SBG) prefers long-chain substrates and soluble starch. Multiple sequence alignment of 31AGs indicated a high degree of diversity at the long loop (N-loop), which forms one wall of the active pocket. Mutations of Phe236 in the N-loop of SBG (F236A/S) decreased k_cat/K_m values for substrates longer than maltose. Providing a phenylalanine residue at a similar position in ANG (T228F) altered the k_cat/K_m values for maltooligosaccharides compared with wild-type ANG, i.e., the mutant enzyme showed the highest k_cat/K_m value for maltotetraose. Subsite affinity analysis indicated that modification of subsite affinities at + 2 and + 3 caused alterations of substrate specificity in the mutant enzymes. These results indicated that the aromatic residue in the N-loop contributes to determining the chain-length specificity of 31AGs.     

Characterisation of the DNA-dependent ATPase activity of human DNA topoisomerase IIbeta: mutation of Ser165 in the ATPase domain reduces the ATPase activity and abolishes the in vivo complementation ability

We report for the first time an analysis of the ATPase activity of human DNA topoisomerase (topo) IIβ. We show that topo IIβ is a DNA-dependent ATPase that appears to fit Michaelis–Menten kinetics. The ATPase activity is stimulated 44-fold by DNA. The k_cat for ATP hydrolysis by human DNA topo IIβ in the presence of DNA is 2.25 s^–1. We have characterised a topo IIβ derivative which carries a mutation in the ATPase domain (S165R). S165R reduced the k_cat for ATP hydrolysis by 7-fold, to 0.32 s^–1, while not significantly altering the apparent K_m. The specificity constant for the interaction between ATP and topo IIβ (k_cat/K_mapp) showed a 90% reduction for βS165R. The DNA binding affinity and ATP-independent DNA cleavage activity of the enzyme are unaffected by this mutation. However, the strand passage activity is reduced by 80%, presumably due to reduced ATP hydrolysis. The mutant enzyme is unable to complement ts yeast topo II in vivo. We have used computer modelling to predict the arrangement of key residues at the ATPase active site of topo IIβ. Ser165 is predicted to lie very close to the bound nucleotide, and the S165R mutation could thus influence both ATP binding and ADP dissociation.     

Long-range interaction between the enzyme active site and a distant allosteric site in the human mitochondrial NAD(P)-dependent malic enzyme

Our previous study has suggested that mutation of the amino acid residue Asp102 has a significant effect on the fumarate-mediated activation of human mitochondrial NAD(P)⁺-dependent malic enzyme (m-NAD(P)-ME). In this paper, we examine the cationic amino acid residue Arg98, which is adjacent to Asp102 and is highly conserved in most m-NAD(P)-MEs. A series of R98/D102 mutants were created to examine the possible interactions between Arg98 and Asp102 using the double-mutant cycle analysis. Kinetic analysis revealed that the catalytic efficiency of the enzyme was severely affected by mutating both Arg98 and Asp102 residues. However, the binding energy of these mutant enzymes to fumarate as determined by analysis of the K_A,Fum values, show insignificant differences, indicating that the mutation of Arg98 and Asp102 did not cause a significant decrease in the binding affinity of fumarate. The overall coupling energies for R98K/D102N as determined by analysis of the k_cat/K_m and K_A,Fum values were −2.95 and −0.32 kcal/mol, respectively. According to these results, we conclude that substitution of both Arg98 and Asp102 residues has a synergistic effect on the catalytic ability of the enzyme.     

Kinetic studies of Gly28:Ser mutant form of Bacillus pumilus lipase: Changes in kcat and thermal dependence

Lipases are useful catalysts for a wide variety of industrial purposes. Herein we report the stability and thermal dependence of the activity of wild-type Bacillus pumilus lipase (BplA) and four site-directed mutants designed to improve its thermal stability. The Gly28:Ser mutation produces a dramatic four-fold increase in its k_cat and a remarkable increase in its stability. While the increase in k_cat is temperature-independent, the increase in stability shows that the resultant interactions of this mutation have a strong enthalpic component. Thermal dependence of stability, k_cat, K_M and k_cat/K_M were analysed to gain insight on the structural effects of mutations on BplA. Our results are consistent with a gain in enzyme mobility for those mutants displaying enhanced catalytic properties; the analysis of thermal dependence of kinetic parameters indicates that the mutations did not change either the catalytic mechanism or the rate-limiting step of catalysis.     

Molecular Engineering of Fungal GH5 and GH26 Beta-(1,4)-Mannanases toward Improvement of Enzyme Activity

Microbial mannanases are biotechnologically important enzymes since they target the hydrolysis of hemicellulosic polysaccharides of softwood biomass into simple molecules like manno-oligosaccharides and mannose. In this study, we have implemented a strategy of molecular engineering in the yeast Yarrowia lipolytica to improve the specific activity of two fungal endo-mannanases, PaMan5A and PaMan26A, which belong to the glycoside hydrolase (GH) families GH5 and GH26, respectively. Following random mutagenesis and two steps of high-throughput enzymatic screening, we identified several PaMan5A and PaMan26A mutants that displayed improved kinetic constants for the hydrolysis of galactomannan. Examination of the three-dimensional structures of PaMan5A and PaMan26A revealed which of the mutated residues are potentially important for enzyme function. Among them, the PaMan5A-G311S single mutant, which displayed an impressive 8.2-fold increase in k_cat/K_M due to a significant decrease of K_M, is located within the core of the enzyme. The PaMan5A-K139R/Y223H double mutant revealed modification of hydrolysis products probably in relation to an amino-acid substitution located nearby one of the positive subsites. The PaMan26A-P140L/D416G double mutant yielded a 30% increase in k_cat/K_M compared to the parental enzyme. It displayed a mutation in the linker region (P140L) that may confer more flexibility to the linker and another mutation (D416G) located at the entrance of the catalytic cleft that may promote the entrance of the substrate into the active site. Taken together, these results show that the directed evolution strategy implemented in this study was very pertinent since a straightforward round of random mutagenesis yielded significantly improved variants, in terms of catalytic efiiciency (k_cat/K_M).