Formulation of a Universal First-Order Rate Constant for Enzymatic Reactions

It is a common practice to employ k _cat[E]₀/K _m as a first-order rate constant for the analysis of an enzymatic reaction, where [E]₀ is the total enzyme concentration. I describe in this report a serious shortcoming in analyzing enzymatic reactions when k _cat[E]₀/K _m is employed and show that k _cat[E]₀/K _m can only be applied under very limited conditions. I consequently propose the use of a more universal first-order rate constant, k _cat[ES]_K/[S]₀, where [ES]_K is the initial equilibrium concentration of the ES-complex derived from [E]₀, [S]₀ and K _m. Employing k _cat[ES]_K/[S]₀ as the first-order rate constant enables all enzymatic reactions to be reasonably simulated under a wide range of conditions, and the catalytic and binding contributions to the rate constant of any enzyme can be determined under any and all conditions.     

Rational design of a SHP-2 targeted,fluorogenic peptide substrate

Protein tyrosine phosphatase (PTP) targeted, peptide based chemical probes are valuable tools for studying this important family of enzymes, despite the inherent difficulty of developing peptides targeted towards an individual PTP. Here, we have taken a rational approach to designing a SHP-2 targeted, fluorogenic peptide substrate based on information about the potential biological substrates of SHP-2. The fluorogenic, phosphotyrosine mimetic phosphocoumaryl aminopropionic acid (pCAP) provides a facile readout for monitoring PTP activity. By optimizing the amino acids surrounding the pCAP residue, we obtained a substrate with the sequence Ac-DDPI-pCAP-DVLD-NH₂ and optimized kinetic parameters (k_cat = 0.059 ± 0.008 s⁻¹, K_m = 220 ± 50 µM, k_cat/K_m of 270 M⁻¹s⁻¹). In comparison, the phosphorylated coumarin moiety alone is an exceedingly poor substrate for SHP-2, with a k_cat value of 0.0038 ± 0.0003 s⁻¹, a K_m value of 1100 ± 100 µM and a k_cat/K_m of 3 M⁻¹s⁻¹. Furthermore, this optimized peptide has selectivity for SHP-2 over HePTP, MEG1 and PTPµ. The data presented here demonstrate that PTP-targeted peptide substrates can be obtained by optimizing the sequence of a pCAP containing peptide.     

Contributions of binding and catalytic rate constants to evolutionary modifications inKm of NADH for muscle-type (M4) lactate dehydrogenases

Summary The apparent Michaelis constant (K _m) of NADH for muscle-type (M₄ isozyme) lactate dehydrogenases (LDHs) is highest, at any given temperature of measurement, for LDHs of cold-adapted vertebrates (Table 1). However, these interspecific differences in theK _m of NADH are not due to variations in LDH-NADH binding affinity. Rather, theK _m differences result entirely from interspecific variation in the substrate turnover constant (k _cat) (Fig. 1; Table 2). This follows from the fact that theK _m of NADH is equal tok _cat divided by the on constant for NADH binding to LDH,k ₁, so that interspecific differences ink _cat, combined with identical values fork ₁ among different LDH reactions, make the magnitude of theK _m of NADH a function of substrate turnover number. The temperature dependence of theK _m of NADH for a single LDH homologue is the net result of temperature dependence of bothk _cat andk ₁ (Figs. 3 and 4). Temperature independentK _m values can result from simultaneous, and algebraically offsetting, increases ink _cat andk ₁ with rising temperature. Salt-induced changes in theK _m of NADH also may be due to simultaneous perturbation of bothk _cat andk ₁ (Table 3). These findings are discussed from the standpoint of the evolution of LDH kinetic properties, particularly the interspecific conservation of catalytic and regulatory functions, in differently-adapted species.     

STUDIES ON THE KINETICS OF ACETYLCHOLINESTERASE IN THE RESISIANT AND SUSCEPTIBLE STRAINS OF HOUSEFLY (MUSCA DOMESTICA)

Abstract Acetylcholinesterase (AChE) in the susceptible (S) and the resistant (R) strains of housefly (Musca domestica) was investigated using kinetic analysis. The V_max values of AChE for hydrolyzing acetylthiocholine (ATCh) and butyrylthiocholine (BTCh) were 4578.50 and 1716.08nmol/min/mg* protein in the R strain, and were 1884.75 and 864.72 nmol/min/mg. protein in the Sstrain, respectively. The V_max ratios of R to S enzyme were 2.43 for ATCh and 1.98 for BTCh. The K_m values of AChE for ATCh and BTCh were 0.069 and 0.034 mmol/L in the S strain, and 0.156, 0.059 mmol/L in the R strain, respectively. The K_m ratios of R to S enzyme were 2.26 for ATCh and 1.74 for BTCh. The k_i ratios of S to R enzyme for three insecticides propoxur, methomyl and paraoxon were 46.04, 4.17 and 2. 86, respectively. In addition, k_cat and k_cat/K_m for measuring turnover and catalytic efficiency of AChE were determined using eserine as titrant. The k_cat values of AChE from the R strain for both ATCh and BTCh were higher than those values from the S strain. But the values of k_cat/K_m were in contrary to the k_cat values with R enzyme compared to S enzyme. The AChE catalytic properties and sensitivity to the inhibition by three insecticides in the R and S strains of housefly were discussed based on contribution of V_max, K_m, k_i, k_cat and k_cat/K_m. All these data implied that AChE from the R strain might be qualitatively altered. We also observed an intriguing phenomenon that inhibitors could enhance the activity of AChE from the resistant strain. This “flight reaction” of the powerful enzyme might be correlated with the developing resistance of housefly to organophosphate or carbamate insecticides.     

Effect of C-terminal truncation on enzyme properties of recombinant amylopullulanase from <Emphasis Type="Italic">Thermoanaerobacter pseudoethanolicus</Emphasis>

The smallest and enzymatically active molecule, TetApuQ818, was localized within the C-terminal Q818 amino acid residue after serial C-terminal truncation analysis of the recombinant amylopullulanase molecule (TetApuM955) from Thermoanaerobacter pseudoethanolicus. Kinetic analyses indicated that the overall catalytic efficiency, k _cat/K _m, of TetApuQ818 was 8–32% decreased for the pullulan and the soluble starch substrate, respectively. Changes to the substrate affinity, K _m, and the turnover rate, k _cat, were decreased significantly in both enzymatic activities of TetApuQ818. TetApuQ818 exhibited less thermostability than TetApuM955 when the temperature was raised above 85°C, but it had similar substrate-binding ability and hydrolysis products toward various substrates as TetApuM955 did. Both enzymes showed similar spectroscopies of fluorescence and circular dichroism, suggesting the active folding conformation was maintained after this C-terminal Q818 deletion. This study suggested that the binding ability of insoluble starch by TetApuM955 did not rely on the putative C-terminal carbohydrate binding module family 20 (CBM20) and two FnIII regions of TetApu, though the integrity of the AamyC module of TetApuQ818 was required for the enzyme activity.     

Identification of Residues Surrounding the Active Site of Type A Botulinum Neurotoxin Important for Substrate Recognition and Catalytic Activity

Type A botulinum neurotoxin is one of the most lethal of the seven serotypes and is increasingly used as a therapeutic agent in neuromuscular dysfunctions. Its toxic function is related to zinc-endopeptidase activity of the N-terminal light chain (LC) on synaptosome-associated protein-25 kDa (SNAP-25) of the SNARE complex. To understand the determinants of substrate specificity and assist the development of strategies for effective inhibitors, we used site-directed mutagenesis to investigate the effects of 13 polar residues of the LC on substrate binding and catalysis. Selection of the residues for mutation was based on a computational analysis of the three-dimensional structure of the LC modeled with a 17-residue substrate fragment of SNAP-25. Steady-state kinetic parameters for proteolysis of the substrate fragment were determined for a set of 16 single mutants. Of the mutated residues non-conserved among the serotypes, replacement of Arg-230 and Asp-369 by polar or apolar residues resulted in drastic lowering of the catalytic rate constant (k _cat), but had less effect on substrate affinity (K _m). Substitution of Arg-230 with Lys decreased the catalytic efficiency (k _cat/K _m) by 50-fold, whereas replacement by Leu yielded an inactive protein. Removal of the electrostatic charge at Asp-369 by mutation to Asn resulted in 140-fold decrease in k _cat/K _m. Replacement of other variable residues surrounding the catalytic cleft (Glu-54, Glu-63, Asn-66, Asp-130, Asn-161, Glu-163, Glu-170, Glu-256), had only marginal effect on decreasing the catalytic efficiency, but unexpectedly the substitution of Lys-165 with Leu resulted in fourfold increase in k _cat/K _m. For comparison purposes, two conserved residues Arg-362 and Tyr-365 were investigated with substitutions of Leu and Phe, respectively, and their catalytic efficiency decreased 140- and 10-fold, respectively, whereas substitution of the tyrosine ring with Asn abolished activity. The altered catalytic efficiencies of the mutants were not due to any significant changes in secondary or tertiary structures, or in zinc content and thermal stability. We suggest that, despite the large minimal substrate size for catalysis, only a few non-conserved residues surrounding the active site are important to render the LC competent for catalysis or provide conformational selection of the substrate.     

Kinetic characterization of the double mutant R148A/E182S of glycogen phosphorylase kinase catalytic subunit: the role of the activation loop

Many protein kinases are activated by phosphorylation in a highly conserved region of their catalytic subunit, termed activation loop. Phosphorylase kinase is constitutively active without the requirement for phosphorylation of residues in the activation loop. The residue which plays an analogous role to the phosphorylatable residues in other protein kinases is Glu182, which makes contacts to a highly conserved Arg148. In turn, Arg148 adjacent to the catalytic Asp149, enabling information to be transmitted from the activation loop to the catalytic machinery. The double mutant R148A/E182S has been kinetically characterized. The mutation resulted in an approximate 16- to 22-fold decrease in the k _cat/K _m value of the enzyme. The kinetic data, discussed in the light of the structural data from previously determined complexes of the enzyme, lead to the suggestion that the activation loop has a major role in substrate binding but also in correct orientation of the groups participating in catalysis.     

Role of Phe-114 in substrate specificity of Candida tenuis xylose reductase (AKR2B5)

The 2.2 Å X-ray crystal structure of Candida tenuis xylose reductase (AKR2B5) bound with NADP⁺ reveals that Phe-114 contributes to the substrate binding pocket of the enzyme. In the related human aldose reductase (AKR1B1), this phenylalanine is replaced by a tryptophan. The side chain of Trp was previously implicated in forming a hydrogen bond with bound substrate or inhibitor. The apparent Michaelis constant of AKR2B5 for xylose (K_m≈90 mM) is 60 times that of AKR1B1, perhaps because critical enzyme–substrate interactions of Trp are not available to Phe-114. We, therefore, prepared a Phe-114→Trp mutant (F114W) of AKR2B5, to mimic the aldose reductase relationship in xylose reductase. Detailed analysis of the kinetic consequences in purified F114W revealed that the K_m values for xylose and xylitol at pH 7.0 and 25°C were increased 5.1- and 4.4-fold, respectively, in the mutant compared with the wild-type. Turnover numbers (k_cat) of F114W for xylose reduction and xylitol oxidation were half those of the wild-type. Apparent dissociation constants of NADH (K_iNADH=44 µM) and NAD⁺ (K_iNAD⁺=177 µM) were increased 1.6- and 1.4-fold in comparison with values of K_iNADH and K_iNAD⁺ for the wild-type, respectively. Catalytic efficiencies (k_cat/K_m) for NADH-dependent reduction of different aldehydes were between 3.1- and 31.5-fold lower than the corresponding k_cat/K_m values of the wild-type. Therefore, replacement of Phe-114 with Trp weakens rather than strengthens apparent substrate binding by AKR2B5, suggesting that xylose reductase exploits residue 114 in a different manner from aldose reductase.     

Purification and Characterization of Aspartic Protease Derived from Sf9 Insect Cells

An aspartic protease that is significantly produced by baculovirus-infected Spodoptera frugiperda Sf9 insect cells was purified to homogeneity from a growth medium. To monitor aspartic protease activity, an internally quenched fluoresce (IQF) substrate specific to cathepsin D was used. The purified aspartic protease showed a single protein band on SDS–PAGE with an apparent molecular mass of 40 kDa. The N-terminal amino acid sequence of the enzyme had a high homology to a Bombyx mori aspartic protease. The enzyme showed greatest affinity for the IQF substrate at pH 3.0 with a K _m of 0.85 μM. The k _cat and k _cat?K _m values were 13 s^?1 and 15 s^?1 μM^?1 respectively. Pepstatin A proved to be a potent competitive inhibitor with inhibitor constant, K _i, of 25 pM.     

Structural Advantage of Sugar Beet α-Glucosidase to Stabilize the Michaelis Complex with Long-chain Substrate

The α-glucosidase from sugar beet (SBG) is an exo-type glycosidase. The enzyme has a pocket-shaped active site, but efficiently hydrolyzes longer maltooligosaccharides and soluble starch due to lower K_m and higher k_cat/K_m for such substrates. To obtain structural insights into the mechanism governing its unique substrate specificity, a series of acarviosyl-maltooligosaccharides was employed for steady-state kinetic and structural analyses. The acarviosyl-maltooligosaccharides have a longer maltooligosaccharide moiety compared with the maltose moiety of acarbose, which is known to be the transition state analog of α-glycosidases. The clear correlation obtained between log K_i of the acarviosyl-maltooligosaccharides and log(K_m/k_cat) for hydrolysis of maltooligosaccharides suggests that the acarviosyl-maltooligosaccharides are transition state mimics. The crystal structure of the enzyme bound with acarviosyl-maltohexaose reveals that substrate binding at a distance from the active site is maintained largely by van der Waals interactions, with the four glucose residues at the reducing terminus of acarviosyl-maltohexaose retaining a left-handed single-helical conformation, as also observed in cycloamyloses and single helical V-amyloses. The kinetic behavior and structural features suggest that the subsite structure suitable for the stable conformation of amylose lowers the K_m for long-chain substrates, which in turn is responsible for higher specificity of the longer substrates.     

Bifunctional activity of fused Plasmodium falciparum orotate phosphoribosyltransferase and orotidine 5′-monophosphate decarboxylase

Fusion of the last two enzymes in the pyrimidine biosynthetic pathway in the inversed order by having a COOH-terminal orotate phosphoribosyltransferase (OPRT) and an NH₂-terminal orotidine 5′-monophosphate decarboxylase (OMPDC), as OMPDC-OPRT, are described in many organisms. Here, we produced gene fusions of Plasmodium falciparum OMPDC-OPRT and expressed the bifunctional protein in Escherichia coli. The enzyme was purified to homogeneity using affinity and anion-exchange chromatography, exhibited enzymatic activities and functioned as a dimer. The activities, although unstable, were stabilized by its substrate and product during purification and long-term storage. Furthermore, the enzyme expressed a perfect catalytic efficiency (k_cat/K_m). The k_cat was selectively enhanced up to three orders of magnitude, while the K_m was not much affected and remained at low μM levels when compared to the monofunctional enzymes. The fusion of the two enzymes, creating a “super-enzyme” with perfect catalytic power and more flexibility, reflects cryptic relationship of enzymatic reactivities and metabolic functions on molecular evolution.     

A comparative study of activity and apparent inhibition of fungal β‐glucosidases

β‐Glucosidases (BGs) from Aspergillus fumigates, Aspergillus niger, Aspergillus oryzae, Chaetomium globosum, Emericella nidulans, Magnaporthe grisea, Neurospora crassa, and Penicillium brasilianum were purified to homogeneity, and analyzed by isothermal titration calorimetry with respect to their hydrolytic activity and its sensitivity to glucose (product) using cellobiose as substrate. Global non‐linear regression of several reactions, with or without added glucose, to a product inhibition equation enabled the concurrent derivation of the kinetic parameters k_cat, K_m, and the apparent product inhibition constant _appK_i for each of the enzymes. A more simple fit is not advisable to use as the determined _appK_i are in the same range as their K_m for some of the tested BGs and produced glucose would in these cases interfere. The highest value for k_cat was determined for A. fumigatus (768 s^?1) and the lowest was a factor 9 less. K_m varied by a factor of 3 with the lowest value determined for C. globosum (0.95 mM). The measured _appK_i varied a factor of 15; the hydrolytic activity of N. crassa being the most resistant to glucose with an apparent product inhibition constant of 10.1 mM. Determination of _appK_i using cellobiose as substrate is important as it reflects to what extent the different BGs are hydrolytically active under industrial conditions where natural substrates are hydrolyzed and the final glucose concentrations are high. Biotechnol. Bioeng. 2010;107: 943–952. © 2010 Wiley Periodicals, Inc.     

Substrate binding modes and anomer selectivity of chitinase A from Vibrio harveyi

High-performance liquid chromatography mass spectrometry (HPLC MS) was employed to assess the binding behaviors of various substrates to Vibrio harveyi chitinase A. Quantitative analysis revealed that hexaNAG preferred subsites −2 to +2 over subsites −3 to +2 and pentaNAG only required subsites −2 to +2, while subsites −4 to +2 were not used at all by both substrates. The results suggested that binding of the chitooligosaccharides to the enzyme essentially occurred in compulsory fashion. The symmetrical binding mode (−2 to +2) was favored presumably to allow the natural form of sugars to be utilized effectively. Crystalline α chitin was initially hydrolyzed into a diverse ensemble of chitin oligomers, providing a clear sign of random attacks that took place within chitin chains. However, the progressive degradation was shown to occur in greater extent at later time to complete hydrolysis. The effect of the reducing-end residues were also investigated by means of HPLC MS. Substitutions of Trp275 to Gly and Trp397 to Phe significantly shifted the anomer selectivity of the enzyme toward β substrates. The Trp275 mutation modulated the kinetic property of the enzyme by decreasing the catalytic constant (k _cat) and the substrate specificity (k _cat/K _m) toward all substrates by five- to tenfold. In contrast, the Trp397 mutation weakened the binding strength at subsite (+2), thereby speeding up the rate of the enzymatic cleavage toward soluble substrates but slowing down the rate of the progressive degradation toward insoluble chitin.     

Hydrolysis of soy isoflavone glycosides by recombinant β-glucosidase from hyperthermophile <Emphasis Type="Italic">Thermotoga maritima</Emphasis>

A recombinant Thermotoga maritima β-glucosidase A (BglA) was purified to homogeneity for performing enzymatic hydrolysis of isoflavone glycosides from soy flour. The kinetic properties K _m, k _cat, and k _cat/K _m of BglA towards isoflavone glycosides, determined using high-performance liquid chromatography, confirmed the higher efficiency of BglA in hydrolyzing malonylglycosides than non-conjugated glycosides (daidzin and genistin). During hydrolysis of soy flour by BglA at 80°C, the isoflavone glycosides (soluble form) were extracted from soy flour (solid state) into the solution (liquid state) in thermal condition and converted to their aglycones (insoluble form), which mostly existed in the pellet to be separated from BglA in the reaction solution. The enzymatic hydrolysis in one-step and two-step approaches yielded 0.38 and 0.35 mg genistein and daidzein per gram of soy flour, respectively. The optimum conditions for conversion of isoflavone aglycones were 100 U per gram of soy flour, substrate concentration 25% (w/v), and incubation time 3 h for 80°C.     

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.     

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.     

Competitive substrate inhibition of amyloglucosidase from Rhizopus sp. by vanillin and curcumin

Kinetic studies of two glucosylation reactions catalyzed by an amyloglucosidase from Rhizopus sp. leading to the synthesis of vanillin-α/β-D-glucoside from D-glucose and vanillin and curcumin-bis-α-D-glucoside from D-glucose and curcumin were investigated in detail. Initial reaction rates were determined from kinetic runs involving different concentrations of D-glucose and vanillin (5?mM to 0.1?M) or D-glucose and curcumin (5?mM to 0.1?M). Graphical double reciprocal plots showed that the kinetics of the two enzyme catalyzed reactions exhibited Ping-Pong Bi-Bi mechanism where competitive substrate inhibition by vanillin/curcumin led to dead-end amyloglucosidase–vanillin/curcumin complexes at higher concentrations of vanillin/curcumin. An attempt to obtain the best fit of this kinetic model through computer simulation yielded in good approximation, the values of four important kinetic parameters, vanillin-α/β-D-glucoside: k_cat=35.0±3.2 10^?5M?h^?1·mg, K_i=10.5±1.1?mM, K_mD-glucose=60.0±6.2?mM, K_mvanillin=50.0±4.8?mM; curcumin-bis-α-D-glucoside: k_cat=6.07±0.58 10^?5M?h^?1·mg, K_i=3.0±0.28?mM, K_mD-glucose=10.0±0.9?mM, K_mcurcumin=4.6±0.5?mM.     

Investigation of the Role of a Conserved Glycine Motif in the Saccharomyces cerevisiae Xylose Reductase

All yeast xylose reductases, with the exception of that from Schizosaccharomyces pombe, possess the catalytic and coenzyme-binding elements from both the aldo–keto reductase and short-chain dehydrogenase–reductase (SDR) enzyme families in their primary sequences. In the Saccharomyces cerevisiae xylose reductase (XR), the SDR-like coenzyme-binding GXXXGXG motif (Gly motif) is located between residues 128 and 134, with the third Gly residue being replaced by an Asp. We used site-directed mutagenesis to study the role of this SDR-like Gly motif in the S. cerevisiae xylose reductase. Site-directed mutagenesis of the individual conserved Gly residue positions (G128A, G132A, D134G, and D134A) did not significantly affect the specific activity, kinetic constants (K_m, K_cat, and K_cat/K_m), or dissociation constants (K_d) in any of the variants compared with the wild type. Deletion of the entire Gly motif produced an unstable protein that could not be purified. These results indicate that the SDR-like Gly motif likely provides support to the overall structure of the enzyme, but it does not contribute directly to coenzyme binding in this XR.     

Catalytic properties of β-d-xylosidase XylBH43 from Bacillus halodurans C-125 and mutant XylBH43-W147G

Recombinant glycoside hydrolase family 43 member β-d-xylosidase XylBH43 from Bacillus halodurans C-125 was expressed in Escherichia coli with C-terminal His-tag. Compared to structurally homologous β-xylosidase SXA, another GH43 member and the most active xylosidase known to date, the k_cat value for xylobiose hydrolysis was 2-fold lower, xylotriose and xylotetraose k_cat values were similar, and binding affinities for inhibitors xylose and glucose were 10-fold lower and 1.5-fold higher, respectively. Mutant SXA-W145G had previously been shown to exhibit reduced monosaccharide binding. Characterization of the corresponding mutant XylBH43-W147G shows a similar 2.6-fold K_i(d-xylose) increase. In addition, the Trp mutant displayed lowered substrate inhibition for both natural and artificial substrates, while K_m of substrates increased and thermal stability at 50 °C decreased ～100-fold. The superior xylooligosaccharide k_cat values for XylBH43 make this enzyme valuable both as a saccharification enzyme, and as a source of genetic diversity in on-going protein engineering efforts targeted at optimizing GH43 enzymes for biomass saccharification.     

Modulation of Substrate Preference of Thermus Maltogenic Amylase by Mutation of the Residues at the Interface of a Dimer

To elucidate the relationship between the substrate size and geometric shape of the catalytic site of Thermus maltogenic amylase, Gly50, Asp109, and Val431, located at the interface of the dimer, were replaced with bulky amino acids. The k _cat/K _m value of the mutant for amylose increased significantly, whereas that for amylopectin decreased as compared to that of the wild-type enzyme. Thus, the substituted bulky amino acid residues modified the shape of the catalytic site, such that the ability of the enzyme to distinguish between small and large molecules like amylose and amylopectin was enhanced.