Pre-steady-state kinetics of Escherichia coli aspartate aminotransferase catalyzed reactions and thermodynamic aspects of its substrate specificity

The four half-transamination reactions [the pyridoxal form of Escherichia coli aspartate aminotransferase (AspAT) with aspartate or glutamate and the pyridoxamine form of the enzyme with oxalacetate or 2-oxoglutarate] were followed in a stopped-flow spectrometer by monitoring the absorbance change at either 333 or 358 nm. The reaction progress curves in all cases gave fits to a monophasic exponential process. Kinetic analyses of these reactions showed that each half-reaction is composed of the following three processes: (1) the rapid binding of an amino acid substrate to the pyridoxal form of the enzyme; (2) the rapid binding of the corresponding keto acid to the pyridoxamine form of the enzyme; (3) the rate-determining interconversion between the two complexes. This mechanism was supported by the findings that the equilibrium constants for half- and overall-transamination reactions and the steady-state kinetic constants (Km and kcat) agreed well with the predicted values on the basis of the above mechanism using pre-steady-state kinetic parameters. The significant primary kinetic isotope effect observed in the reaction with deuterated amino acid suggests that the withdrawal of the alpha-proton of the substrates is rate determining. The pyridoxal form of E. coli AspAT reacted with a variety of amino acids as substrates. The Gibbs free energy difference between the transition state and the unbound state (unbound enzyme plus free substrate), as calculated from the pre-steady-state kinetic parameters, showed a linear relationship with the accessible surface area of amino acid substrate bearing an uncharged side chain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Development of a fluorescence polarization assay for peptidyl-tRNA hydrolase

Peptidyl-tRNA hydrolase (Pth) activity ensures the rapid recycling of peptidyl-tRNAs that result from premature termination of translation. Historically, the hydrolyzing activity of Pth has been assayed with radiolabeled N-blocked aminoacyl-tRNAs in assay systems that require the separation of radiolabeled amino acid from the N-blocked aminoacyl-tRNA complex. In the present study, we describe the development of a kinetic fluorescence polarization (FP) assay that enables measurements of Pth activity without the need to separate bound and free tracer. The hydrolyzing activity of Pth was determined by measuring the change in polarization values that resulted from the cleavage of a fluorescently labeled substrate (BODIPY-Lys-tRNA(Lys)). The data were analyzed using an equation describing first-order dissociation and the results showed that the experimental data correlated well with the theoretical curve. A runs test of the residuals showed that the experimental data did not significantly differ from the first-order model. The assay is adaptable to a multiwell format and is sensitive enough to detect Pth-like activity in bacterial cell lysate. The Pth FP assay provides a homogeneous and kinetic format for measuring Pth activity in vitro.     

Substrate ground state binding energy concentration is realized as transition state stabilization in physiological enzyme catalysis

Previously published kinetic data on the interactions of seventeen different enzymes with their physiological substrates are re-examined in order to understand the connection between ground state binding energy and transition state stabilization of the enzyme-catalyzed reactions. When the substrate ground state binding energies are normalized by the substrate molar volumes, binding of the substrate to the enzyme active site may be thought of as an energy concentration interaction; that is, binding of the substrate ground state brings in a certain concentration of energy. When kinetic data of the enzyme/substrate interactions are analyzed from this point of view, the following relationships are discovered: 1) smaller substrates possess more binding energy concentrations than do larger substrates with the effect dropping off exponentially, 2) larger enzymes (relative to substrate size) bind both the ground and transition states more tightly than smaller enzymes, and 3) high substrate ground state binding energy concentration is associated with greater reaction transition state stabilization. It is proposed that these observations are inconsistent with the conventional (Haldane) view of enzyme catalysis and are better reconciled with the shifting specificity model for enzyme catalysis.     

Extensive comparison of the substrate preferences of two subtilisins as determined with peptide substrates which are based on the principle of intramolecular quenching.

Subtilisins are serine endopeptidases with an extended binding cleft comprising at least eight binding subsites. Interestingly, subsites distant from the scissile bond play a dominant role in determining the specificity of the enzymes. The development of internally quenched fluorogenic substrates, which allow polypeptides of more than 11 amino acids to be inserted between the donor and the acceptor, has rendered it possible to perform a highly systematic mapping of the individual subsites of the active sites of subtilisin BPN' from Bacillus amyloliquefaciens and Savinase from Bacillus lentus. For each enzyme, the eight positions S5-S'3 were characterized by determination of kcat/KM values for the hydrolysis of substrates in which the amino acids were systematically varied. The results emphasize that in both subtilisin BPN' and Savinase interactions between substrate and S4 and S1 are very important. However, it is apparent that interactions between other subsites and the substrate exert a significant influence on the substrate preference. The results are rationalized on the basis of the structural data available for the two enzymes.     

Yeast dipeptidase: active site mapping by kinetic studies with substrates and substrate analogs.

In order to characterize the active site of yeast dipeptidase in more detail, kinetic studies with a variety of dipeptide substrates and substrate analogs were performed. To analyze kinetic data, computer programs were developed which first calculate initial velocities from progress curves and then evaluate the kinetic parameters by nonlinear regression analysis. A free carboxyl group is a prerequisite for binding of dipeptidase substrates; its position relative to the peptide bond must not deviate from the normal L-dipeptide conformation. The spatial arrangement of the terminal ammonium ion seems to be less crucial. The enzyme's substrate specificity clearly reflects the interactions of the substrate amino acid side chains with complementary dipeptidase subsites. The domain of the enzyme in contact with the C-terminal substrate side chain seems to be an open structure of moderately hydrophobic character. In contrast, the binding site for the amino-terminal side chain is a more strongly hydrophobic "pocket" of limited dimensions. The kinetics of inhibition by free amino acids points to an ordered release of products from the enzyme.     

A method for designing peptide substrates for proteases. Tripeptidyl-p-nitroanilide substrates for subtilisin Carlsberg.

1. The kinetic parameters of 25 peptidyl-p-nitroanilide substrates were investigated with subtilisin Carlsberg as model enzyme. 2. For a series of 12 substrates, the contribution of various side chains to the affinity constant was computed by regression analysis. From these contributions the sequence of a new and better substrate, N-benzyloxycarbonyl-arginyl-norleucyl-norleucyl-p-nitroanilide (Z-Arg-Nle-Nle-Nan) was predicted. The compound was synthesized and assayed. Its calculated 1/Km value, 43.5 mM-1, was in a good agreement with the value of 40.0 mM-1 that was determined experimentally. 3. On expanding the series to 19 substrates, it was found that the productivity of enzyme-substrate binding is influenced primarily by those subsites which have a significantly greater contribution to the affinity constants than others. 4. The additivity principle applied reasonably well for the contribution of individual side chains to the kinetic parameters. This fact suggests that regression analysis can be used for the prediction of the amino acid sequence of better substrates than those already tested, probably not only for subtilisin but also for other proteolytic enzymes.     

RNA-binding site of Escherichia coli peptidyl-tRNA hydrolase

In a cell, peptidyl-tRNA molecules that have prematurely dissociated from ribosomes need to be recycled. This work is achieved by an enzyme called peptidyl-tRNA hydrolase. To characterize the RNA-binding site of Escherichia coli peptidyl-tRNA hydrolase, minimalist substrates inspired from tRNA(His) have been designed and produced. Two minisubstrates consist of an N-blocked histidylated RNA minihelix or a small RNA duplex mimicking the acceptor and TψC stem regions of tRNA(His). Catalytic efficiency of the hydrolase toward these two substrates is reduced by factors of 2 and 6, respectively, if compared with N-acetyl-histidyl-tRNA(His). In contrast, with an N-blocked histidylated microhelix or a tetraloop missing the TψC arm, efficiency of the hydrolase is reduced 20-fold. NMR mapping of complex formation between the hydrolase and the small RNA duplex indicates amino acid residues sensitive to RNA binding in the following: (i) the enzyme active site region; (ii) the helix-loop covering the active site; (iii) the region including Leu-95 and the bordering residues 111-117, supposed to form the boundary between the tRNA core and the peptidyl-CCA moiety-binding sites; (iv) the region including Lys-105 and Arg-133, two residues that are considered able to clamp the 5'-phosphate of tRNA, and (v) the positively charged C-terminal helix (residues 180-193). Functional value of these interactions is assessed taking into account the catalytic properties of various engineered protein variants, including one in which the C-terminal helix was simply subtracted. A strong role of Lys-182 in helix binding to the substrate is indicated.     

Structural basis for substrate specificity differences of horse liver alcohol dehydrogenase isozymes

A structure determination in combination with a kinetic study of the steroid converting isozyme of horse liver alcohol dehydrogenase, SS-ADH, is presented. Kinetic parameters for the substrates, 5beta-androstane-3beta,17beta-ol, 5beta-androstane-17beta-ol-3-one, ethanol, and various secondary alcohols and the corresponding ketones are compared for the SS- and EE-isozymes which differ by nine amino acid substitutions and one deletion. Differences in substrate specificity and stereoselectivity are explained on the basis of individual kinetic rate constants for the underlying ordered bi-bi mechanism. SS-ADH was crystallized in complex with 3alpha,7alpha,12alpha-trihydroxy-5beta-cholan -24-acid (cholic acid) and NAD(+), but microspectrophotometric analysis of single crystals proved it to be a mixed complex containing 60-70% NAD(+) and 30-40% NADH. The crystals belong to the space group P2(1) with cell dimensions a = 55.0 A, b = 73.2 A, c = 92.5 A, and beta = 102.5 degrees. A 98% complete data set to 1.54-A resolution was collected at 100 K using synchrotron radiation. The structure was solved by the molecular replacement method utilizing EE-ADH as the search model. The major structural difference between the isozymes is a widening of the substrate channel. The largest shifts in C(alpha) carbon positions (about 5 A) are observed in the loop region, in which a deletion of Asp115 is found in the SS isozyme. SS-ADH easily accommodates cholic acid, whereas steroid substrates of similar bulkiness would not fit into the EE-ADH substrate site. In the ternary complex with NAD(+)/NADH, we find that the carboxyl group of cholic acid ligates to the active site zinc ion, which probably contributes to the strong binding in the ternary NAD(+) complex.     

A Structure-Activity Relationship for the Hydrolysis of Acetylamino Acids by Porcine Aminoacylase

A structure-activity relationship is presented that satisfactorily predicts the rates of hydrolysis of a series of acetylglycine derivatives by porcine aminoacylase. It is apparent that the substrate specificity of aminoacylase is mainly kinetic in origin, the observed correlation with Taft's E(s) parameter supporting the notion that enzymolysis proceeds through a mechanism that is analogous to chemical hydrolysis. It is suggested that the alpha-CH(2)CH group of those substrates that possess this moiety is conformationally immobile upon binding. This lock facilitates rapid hydrolysis and results from steric interactions between the enzyme and substrate. The incorporation of alpha-methyl amino acid derivatives in the structure-activity relationship is consistent with a flexible active site model and it is concluded that the alpha-methyl effect in this system is a binding phenomenon. It is evident that the active center of porcine aminoacylase can comfortably accommodate amino acid derivatives with side chains containing less than six carbon atoms, contrary to previous assertions. It is suggested that the binding of bulkier derivatives necessitates the distortion of the active site. Derivatives possessing beta-hydroxyl groups are found to deviate from expected behavior and a nonproductive binding model is presented. Copyright 2000 Academic Press.     

Strategies to extend the lifetime of bioelectrochemical enzyme electrodes for biosensing and biofuel cell applications

Enzymes are powerful catalysts for biosensor and biofuel cell electrodes due to their unique substrate specificity. This specificity is defined by the amino acid chain's complex three-dimensional structure based on non-covalent forces, being also responsible for the very limited enzyme lifetime of days to weeks. Many electrochemical applications, however, would benefit from lifetimes over months to years. This mini-review provides a critical overview of strategies and ideas dealing with the problem of short enzyme lifetime, which limits the overall lifetime of bioelectrochemical electrodes. The most common approaches aim to stabilize the enzyme itself. Various immobilization techniques have been used to reduce flexibility of the amino acid chain by introducing covalent or non-covalent binding forces to external molecules. The enzyme can also be stabilized using genetic engineering methods to increase the binding forces within the protein or by optimizing the environment in order to reduce destabilizing interactions. In contrast, renewing the inactivated catalyst decouples overall system lifetime from the limited enzyme lifetime and thereby promises theoretically unlimited electrode lifetimes. Active catalyst can be supplied by exchanging the electrolyte repeatedly. Alternatively, integrated microorganisms can display the enzymes on their surface or secrete them to the electrolyte, allowing unattended power supply for long-term applications.     

Site-directed mutagenesis of Escherichia coli acetylglutamate kinase and aspartokinase III probes the catalytic and substrate-binding mechanisms of these amino acid kinase family enzymes and allows three-dimensional modelling of aspartokinase

We test, using site-directed mutagenesis, predictions based on the X-ray structure of N-acetyl-L-glutamate kinase (NAGK), the paradigm of the amino acid kinase protein family, about the roles of specific residues on substrate binding and catalysis. The mutations K8R and D162E decreased V([sustrate]= infinity ) 100-fold and 1000-fold, respectively, in agreement with the predictions that K8 catalyzes phosphoryl transfer and D162 organizes the catalytic groups. R66K and N158Q increased selectively K(m)(Asp) three to four orders of magnitude, in agreement with the binding of R66 and N158 to the C(alpha) substituents of NAG. Mutagenesis in parallel of aspartokinase III (AKIII phosphorylates aspartate instead of acetylglutamate), another important amino acid kinase family member of unknown 3-D structure, identified in AKIII two residues, K8 and D202, that appear to play roles similar to those of K8 and D162 of NAGK, and supports the involvement of E119 and R198, similarly to R66 and N158 of NAGK, in the binding of the amino acid substrate, apparently interacting, respectively, with the alpha-NH(3)(+) and alpha-COO(-) of aspartate. These results and an improved alignment of the NAGK and AKIII sequences have guided us into 3-D modelling of the amino acid kinase domain of AKIII using NAGK as template. The model has good stereochemistry and validation parameters. It provides insight into substrate binding and catalysis, agreeing with mutagenesis results with another aspartokinase that were not considered when building the model.AKIII is homodimeric and is inhibited by lysine. Lysine may bind to a regulatory region that is C-terminal to the amino acid kinase domain. We make a C-terminally truncated AKIII (AKIIIt) and show that the C-region is involved in intersubunit interactions, since AKIIIt is found to be monomeric. Further, it is inactive, as demanded if dimer formation is essential for activity. Models for AKIII architecture are proposed that account for these findings.     

Thiol and amino analogues as alternate substrates for glycerokinase from Candida mycoderma

The kinetic and catalytic mechanism of glycerokinase from Candida mycoderma was examined with thiol and amino analogues of glycerol and with MgAMPPCP, an analogue of MgATP. (S)-1-Aminopropanediol was phosphorylated on nitrogen (Vmax 0.4% that of glycerol) while the R enantiomer was phosphorylated on oxygen (Vmax 0.7% that of glycerol). (S)-1-Mercaptopropanediol was phosphorylated on oxygen (Vmax 3.5% that of glycerol), while the R enantiomer was phosphorylated on sulfur (Vmax 0.001% that of glycerol). The hydroxyl group at C-2 thus orients the substrate in the active site, while that at the carbon remote from phosphorylation enhances both catalysis and binding of the substrate, presumably because of hydrogen-bonding interactions. The kinetic mechanism is random with a high degree of synergistic binding between the substrates, so that the mechanism appears ordered with glycerol adding first but equilibrium ordered with MgATP binding first with the amino analogues.     

Molecular basis of substrate specificity in family 1 glycoside hydrolases

ss-glycosidases are active upon a large range of substrates. Besides this, subtle changes in the substrate structure may result in large modifications on the ss-glycosidase activity. The characterization of the molecular basis of ss-glycosidases substrate preference may contribute to the comprehension of the enzymatic specificity, a fundamental property of biological systems. ss-glycosidases specificity for the monosaccharide of the substrate nonreducing end (glycone) is controlled by a hydrogen bond network involving at least 5 active site amino acid residues and 4 substrate hydroxyls. From these residues, a glutamate, which interacts with hydroxyls 4 and 6, seems to be a key element in the determination of the preference for fucosides, glucosides and galactosides. Apart from this, interactions with the hydroxyl 2 are essential to the ss-glycosidase activity. The active site residues forming these interactions and the pattern of the hydrogen bond network are conserved among all ss-glycosidases. The region of the ss-glycosidase active site that interacts with the moiety (called aglycone) which is bound to the glycone is formed by several subsites (1 to 3). However, the majority of the non-covalent interactions with the aglycone is concentrated in the first one, which presents a variable spatial structure and amino acid composition. This structural variability is in accordance with the high diversity of aglycones recognized by ss-glycosidases. Hydrophobic interactions and hydrogen bonds are formed with the aglycone, but the manner in which they control the ss-glycosidase specificity still remains to be determined.     

Kinetic and crystallographic analysis of mutant Escherichia coli aminopeptidase P: insights into substrate recognition and the mechanism of catalysis

Aminopeptidase P (APPro) is a manganese-dependent enzyme that cleaves the N-terminal amino acid from polypeptides where the second residue is proline. APPro shares a similar fold, substrate specificity, and catalytic mechanism with methionine aminopeptidase and prolidase. To investigate the roles of conserved residues at the active site, seven mutant forms of APPro were characterized kinetically and structurally. Mutation of individual metal ligands selectively abolished binding of either or both Mn(II) atoms at the active site, and none of these metal-ligand mutants had detectable catalytic activity. Mutation of the conserved active site residues His243 and His361 revealed that both are required for catalysis. We propose that His243 stabilizes substrate binding through an interaction with the carbonyl oxygen of the requisite proline residue of a substrate and that His361 stabilizes substrate binding and the gem-diol catalytic intermediate. Sequence, structural, and kinetic analyses reveal that His350, conserved in APPro and prolidase but not in methionine aminopeptidase, forms part of a hydrophobic binding pocket that gives APPro its proline specificity. Further, peptides in which the required proline residue is replaced by N-methylalanine or alanine are cleaved by APPro, but they are extremely poor substrates due to a loss of interactions between the prolidyl ring of the substrate and the hydrophobic proline-binding pocket.     

Kinetic characterization of phenol and aniline derivates as substrates of peroxidase

The kinetic characterization of horseradish peroxidase (HRPC) substrates is difficult because the reaction products are free radicals. The application of a spectrophotometrical method, which is based on determining the time necessary for a given quantity of L-ascorbic acid to be consumed (lag period) during its reaction with the free radicals generated by the enzyme acting on the reducing substrate, makes it possible to obtain the initial steady-state rates (v0). From the kinetic study of a series of derivates of phenol and aniline, the following parameters were determined for the first time: the global catalytic constant (kcat), the Michaelis constant of HRPC for H2O2 in the presence of each reducing substrate (K(M)H2O2), the Michaelis constant of HRPC for the reducing substrate (KMS), the binding constant of the reducing substrate with HRPC compound II (k5) and the rate constant of substrate oxidation by HRPC compound II (k6). The values obtained are disccussed.     

Dicarboxylic Amino Acid Influx across Brush Border of Rabbit Ileum : Effects of amino acid charge on the sodium-amino acid interaction

Glutamate and aspartate influxes across the brush border of rabbit intestine are saturable processes that are subject to competitive inhibition and are markedly influenced by the Na concentration in the mucosal solution. Lowering the Na concentration increases the amino acid concentration needed to elicit a half-maximal influx but does not significantly affect the maximal influx. The interaction between Na and anionic amino acid influx can be described by the same kinetic model that has been applied to the influxes of neutral amino acids and lysine. Comparison of the kinetic parameters for anionic, neutral, and cationic amino acids suggests that amino acid charge influences (a) the stability of the binary (amino acid-site) complex and (b) the affinity of this binary complex for the subsequent binding of Na. A mechanistic interpretation of these interactions is proposed.     

荧光光谱法定量测定纤维素酶活性架构中单个氨基酸突变对底物结合力的影响

纤维素酶活性架构是酶分子中多个氨基酸残基构成的可结合并催化底物的功能区,其中色氨酸等芳香族残基在该区域中起着重要作用.本研究利用荧光光谱法,定量分析了纤维素酶Ch Cel5A活性架构中色氨酸与底物的结合动力学过程,通过色氨酸荧光猝灭的定量分析,确定了色氨酸特异性结合时的底物浓度范围,并且测定了Ch Cel5A活性架构中单个氨基酸突变导致的底物结合常数的变化,与催化动力学参数比较发现,荧光光谱法可准确表征纤维素酶与底物的结合力及其单个残基突变引起动力学参数的变化.此外,由于p NP中含有强的吸电子基团,因而以p NPC等为配体时会高估与色氨酸的结合常数约20~100倍.荧光光谱法可以测定纤维素酶结合糖分子底物的动力学参数,该方法具有灵敏和快速的特点,这为蛋白质与底物之间相互作用的定量分析提供了新的视角.     

Enhanced activity of <Emphasis Type="Italic">Withania somnifera</Emphasis> family-1 glycosyltransferase (UGT73A16) via mutagenesis

This work used an approach of enzyme engineering towards the improved production of baicalin as well as alteration of acceptor and donor substrate preferences in UGT73A16. The 3D model of Withania somnifera family-1 glycosyltransferase (UGT73A16) was constructed based on the known crystal structures of plant UGTs. Structural and functional properties of UGT73A16 were investigated using docking and mutagenesis. The docking studies were performed to understand the key residues involved in substrate recognition. In the molecular model of UGT73A16, substrates binding pockets are located between N- and C-terminal domains. Modeled UGT73A16 was docked with UDP-glucose, UDP-glucuronic acid (UDPGA), kaempferol, isorhamnetin, 3-hydroxy flavones, naringenin, genistein and baicalein. The protein–ligand interactions showed that His 16, Asp 246, Lys 255, Ala 337, Gln 339, Val 340, Asn 358 and Glu 362 amino acid residues may be important for catalytic activity. The kinetic parameters indicated that mutants A337C and Q339A exhibited 2–3 fold and 6–7 fold more catalytic efficiency, respectively than wild type, and shifted the sugar donor specificity from UDP-glucose to UDPGA. The mutant Q379H displayed large loss of activity with UDP-glucose and UDPGA strongly suggested that last amino acid residue of PSPG box is important for glucuronosylation and glucosylation and highly specific to sugar binding sites. The information obtained from docking and mutational studies could be beneficial in future to engineer this biocatalyst for development of better ones.     

Probing Src homology 2 domain ligand interactions by differential line broadening

Few techniques for probing the role of individual amino acids in interactions of a protein with ligands are available. Chemical shift perturbations in NMR spectra provide qualitative information about the response of individual amino acids of a protein to its interactions with ligands. Line shapes derived from (15)N-HSQC spectra recorded for different steps of a ligand titration yield both kinetic constants and insight into mechanisms by which the ligand binds. Here we have analyzed line shapes for 37 signals of amino acids of the N-terminal src homology 2 domain (N-SH2) of the 85 kDa subunit of phosphatidylinositol 3-kinase (PI3-K) upon binding of phosphotyrosine (ptyr)-containing peptides. Kinetic rates at individual amino acids of the SH2 varied throughout the structure. For a subset of SH2 residues, the fine structure of the NMR line shapes indicated slow motions induced by the presence of small amounts of the ligand. These complex line shapes require one or more additional conformational states on the kinetic pathway. Modeling of the observed ligand interactions suggests a quasi-allosteric initial binding step. N-SH2 mutants with altered ligand affinity or specificity were also examined. Analysis of their line shapes revealed three distinct classes of mutants with different kinetic behaviors.     

Quantifying Escherichia coli glutaredoxin-3 substrate specificity using ligand-induced stability

Traditionally, quantification of protein-ligand affinity is performed using kinetic or equilibrium measurements. However, if the binding reaction proceeds via a stable covalent complex, these approaches are often limited. By exploiting the fact that the conformational stabilization of a protein is altered upon ligand binding due to specific interactions, and using an array of selectively chosen ligand analogs, one can quantify the contribution individual interactions have on specificity. We have used ligand-induced stability as a basis to dissect the interaction between glutaredoxin-3 (Grx3) and one of its native substrates, the tripeptide glutathione. Taking advantage of the fact that Grx3 can be trapped in a covalent mixed disulfide to glutathione or to selected synthetic glutathione analogs as part of the natural catalytic cycle, individual contributions to binding of specific molecular groups can be quantified by changes in ligand-induced stability. These changes in conformational stability are interpreted in terms of interaction energies (i.e. specificity) of the particular groups present on the ligand analog. Our results illustrate that although Grx3 recognizes glutathione predominantly through independent and additive ionic interactions at the N- and C-terminal of glutathione, van der Waals interactions from the unique gamma-glutamate moiety of glutathione also play an important role. This study places us closer to understanding the complex task of accommodating multiple substrate specificities in proteins of the thioredoxin superfamily and underscores the general applicability of ligand-induced stability to probe substrate specificity.