The kinetic basis of a general method for the investigation of active site content of enzymes and catalytic antibodies: first-order behaviour under single-turnover and cycling conditions

The theoretical foundation has been laid for the investigation of catalytic systems using first-order kinetics and for a general kinetic method of investigation of the active site content, E(a), of enzymes, catalytic antibodies, and other enzyme-like catalysts. The method involves a combination of steady-state and single-turnover kinetics to provide Vmax and Km and k(lim)(obs) and K(app)(m), respectively. The validity of the method is shown to remain valid for two extensions of the simple two-step enzyme catalysis model (a) when the catalyst preparation contains molecules (Eb) that bind substrate but fail to catalyse product formation and (b) when the catalyst itself binds substrate non-productively as well as productively. The former is a particularly serious complication for polyclonal catalytic antibodies and the latter a potential complication for all catalysts. For the simple model and for (b) Vmax/k(lim)(obs) provides the value of [Ea]T and for (a) its upper limit. This can be refined by consideration of the relative values of Km and the equilibrium dissociation constant of EbS. For the polyclonal catalytic antibody preparation investigated, the fact that K(app/m) > Km demonstrates for the first time the presence of a substrate-binding but non-catalytic component in a polyclonal preparation. First-order behaviour in catalytic systems occurs not only with a large excess of catalyst over substrate but also with lower catalyst/substrate ratios, including the equimolar condition, when K(app)(m) > [S]0, a phenomenon that is not widely appreciated.     

Catalytic and regulatory site composition of yeast AMP deaminase by comparative binding and rate studies. Resolution of the cooperative mechanism

Yeast AMP deaminase is allosterically activated by ATP and MgATP and inhibited by GTP and PO4. The tetrameric enzyme binds 2 mol each of ATP, GTP, and PO4/subunit with Kd values of 8.4 +/- 4.0, 4.1 +/- 0.6, and 169 +/- 12 microM, respectively. At 0.7 M KCl, ATP binds to the enzyme, but no longer activates. Titration with coformycin 5'-monophosphate, a slow, tight-binding inhibitor, indicates a single catalytic site/subunit. ATP and GTP bind at regulatory sites distinct from the catalytic site and their binding is mutually exclusive. Inorganic phosphate competes poorly with ATP for the ATP sites (Kd = 20.1 +/- 4.1 mM). However, near-saturating ATP reduces the moles of phosphate bound per subunit to 1 PO4, which binds with a Kd = 275 +/- 22 microM. In the presence of ATP, PO4 cannot effectively compete with ATP for the nucleotide triphosphate sites. The PO4 which binds in the presence of ATP is competitive with AMP at the catalytic site since the Kd equals the kinetic inhibition constant for PO4. Initial reaction rate curves are a cooperative function of AMP concentration and activation by ATP is also cooperative. However, no cooperativity is observed in the binding of any of the regulator ligands and ATP binding and kinetic activation by ATP is independent of substrate analog concentration. Cooperativity in initial rate curves results, therefore, from altered rate constants for product formation from each (enzyme.substrate)n species and not from cooperative substrate binding. The traditional cooperative binding models of allosteric regulation do not apply to yeast AMP deaminase, which regulates catalytic activity by kinetic control of product formation. The data are used to estimate the rates of AMP hydrolysis under reported metabolite concentrations in yeast.     

Identification of a Second Substrate-binding Site in Solute-Sodium Symporters

The structure of the sodium/galactose transporter (vSGLT), a solute-sodium symporter (SSS) from Vibrio parahaemolyticus, shares a common structural fold with LeuT of the neurotransmitter-sodium symporter family. Structural alignments between LeuT and vSGLT reveal that the crystallographically identified galactose-binding site in vSGLT is located in a more extracellular location relative to the central substrate-binding site (S1) in LeuT. Our computational analyses suggest the existence of an additional galactose-binding site in vSGLT that aligns to the S1 site of LeuT. Radiolabeled galactose saturation binding experiments indicate that, like LeuT, vSGLT can simultaneously bind two substrate molecules under equilibrium conditions. Mutating key residues in the individual substrate-binding sites reduced the molar substrate-to-protein binding stoichiometry to ∼1. In addition, the related and more experimentally tractable SSS member PutP (the Na⁺/proline transporter) also exhibits a binding stoichiometry of 2. Targeting residues in the proposed sites with mutations results in the reduction of the binding stoichiometry and is accompanied by severely impaired translocation of proline. Our data suggest that substrate transport by SSS members requires both substrate-binding sites, thereby implying that SSSs and neurotransmitter-sodium symporters share common mechanistic elements in substrate transport.     

Catalytic site occupancy during ATP hydrolysis by MF1-ATPase. Evidence for alternating high affinity sites during steady-state turnover

The mechanism of ATP hydrolysis by the solubilized mitochondrial ATPase (MF1) has been studied under conditions where catalytic turnover occurs at one site, uni-site catalysis (obtained when enzyme is in excess of substrate), or at two sites, bi-site catalysis (obtained when substrate is in excess of enzyme). Pulse-chase experiments support the conclusion that the sites which participate in bi-site catalysis are the same as those which participate in uni-site catalysis. Upon addition of ATP in molar excess to MF1, label that was bound under uni-site conditions dissociates at a rate equal to the rate of bi-site catalysis. Similarly, when medium ATP is removed, label that was bound under bi-site conditions dissociates at a rate equal to the rate of uni-site catalysis. Evidence that a high affinity catalytic site equivalent to the one observed under uni-site conditions participates as an intermediate in bi-site catalysis includes the demonstration of full occupancy of a catalytically competent site during steady-state turnover at nanomolar concentrations of ATP. Improved measurements of the interaction of ADP at a high affinity catalytic site have lead to the revision of several of the rate constants that define uni-site catalysis. The rate constant for unpromoted dissociation of ADP is equal to that for Pi (4 X 10(-3) s-1). The rate of binding ADP at a high affinity chaseable site (Kd = 1 nM) is equal to the rate of binding ATP (4 X 10(6) M-1 s-1). The rate of catalysis obtained when substrate binding at one site promotes product release from an adjacent site (bi-site catalysis) is up to 100,000-fold faster than unpromoted product release (uni-site catalysis).     

Two L-amino acid oxidase isoenzymes from Russell's viper (Daboia russelli russelli) venom with different mechanisms of inhibition by substrate analogs

Two isoforms, L(1) and L(2), of L-amino acid oxidase have been isolated from Russell's viper venom by Sephadex G-100 gel filtration followed by CM-Sephadex C-50 ion exchange chromatography. The enzymes, with different isoelectric points, are monomers of 60-63 kDa as observed from size exclusion HPLC and SDS/PAGE. Partial N-terminal amino acid sequencing of L(1) and L(2) showed significant homology with other snake venom L-amino acid oxidases. Both the enzymes exhibit marked substrate preference for hydrophobic amino acids, maximum catalytic efficiency being observed with L-Phe. Inhibition of L(1) and L(2) by the substrate analogs N-acetyltryptophan and N-acetyl-L-tryptophan amide has been followed. The initial uncompetitive inhibition of L(1) followed by mixed inhibition at higher concentrations suggested the existence of two different inhibitor-binding sites distinct from the substrate-binding site. In the case of L(2), initial linear competitive inhibition followed by mixed inhibition suggested the existence of two nonoverlapping inhibitor-binding sites, one of which is the substrate-binding site. An inhibition kinetic study with O-aminobenzoic acid, a mimicking substrate with amino, carboxylate and hydrophobic parts, indicated the presence of three and two binding sites in L(1) and L(2), respectively, including one at the substrate-binding site. An inhibitor cross-competition kinetic study indicated mutually excluding binding between N-acetyltryptophan, N-acetyl-L-tryptophan amide and O-aminobenzoic acid in both the isoforms, except at the substrate-binding site of L(1). Binding of substrate analogs with different electrostatic and hydrophobic properties provides useful insights into the environment of the catalytic sites. Furthermore, it predicts the minimum structural requirement for a ligand to enter and anchor at the respective functional sites of LAAO that may facilitate the design of suicidal inhibitors.     

Coupled Global and Local Changes Direct Substrate Translocation by Neurotransmitter-Sodium Symporter Ortholog LeuT

Significant advances have been made in recent years in characterizing neurotransmitter:sodium symporter (NSS) family structure and function. Yet, many time-resolved events and intermediates that control the various stages of transport cycle remain to be elucidated. Whether NSSs harbor one or two sites for binding their substrates (neurotransmitters or amino acids), and what the role of the secondary site S2 is, if any, are still unresolved. Using molecular modeling and simulations for LeuT, a bacterial NSS, we present a comprehensive account of substrate-binding and -stabilization events, and subsequently triggered interactions leading to substrate (alanine) release. LeuT instantaneous conformation as it reconfigures from substrate-receiving (outward-facing) to -releasing (inward-facing) state appears to be a determinant of its affinity to bind substrate at site S2. In the outward-facing state, S1 robustly binds alanine and regulates subsequent redistribution of interactions to trigger extracellular gate closure; whereas S2 is only a transient binding site. The substrate-binding affinity at S2 increases in an intermediate close to inward-facing state. LeuT harbors the two substrate-binding sites, and small displacements of second substrate near S2 are observed to induce concerted small translocations in the substrate bound to primary site S1, although complete release requires collective structural rearrangements that fully expose the intracellular vestibule to the cytoplasm.     

Coupled Global and Local Changes Direct Substrate Translocation by?Neurotransmitter-Sodium Symporter Ortholog LeuT

Significant advances have been made in recent years in characterizing neurotransmitter:sodium symporter (NSS) family structure and function. Yet, many time-resolved events and intermediates that control the various stages of transport cycle remain to be elucidated. Whether NSSs harbor one or two sites for binding their substrates (neurotransmitters or amino acids), and what the role of the secondary site S2 is, if any, are still unresolved. Using molecular modeling and simulations for LeuT, a bacterial NSS, we present a comprehensive account of substrate-binding and -stabilization events, and subsequently triggered interactions leading to substrate (alanine) release. LeuT instantaneous conformation as it reconfigures from substrate-receiving (outward-facing) to -releasing (inward-facing) state appears to be a determinant of its affinity to bind substrate at site S2. In the outward-facing state, S1 robustly binds alanine and regulates subsequent redistribution of interactions to trigger extracellular gate closure; whereas S2 is only a transient binding site. The substrate-binding affinity at S2 increases in an intermediate close to inward-facing state. LeuT harbors the two substrate-binding sites, and small displacements of second substrate near S2 are observed to induce concerted small translocations in the substrate bound to primary site S1, although complete release requires collective structural rearrangements that fully expose the intracellular vestibule to the cytoplasm.     

Investigating the structure of human RNase H1 by site-directed mutagenesis

In this study we examine for the first time the roles of the various domains of human RNase H1 by site-directed mutagenesis. The carboxyl terminus of human RNase H1 is highly conserved with Escherichia coli RNase H1 and contains the amino acid residues of the putative catalytic site and basic substrate-binding domain of the E. coli RNase enzyme. The amino terminus of human RNase H1 contains a structure consistent with a double-strand RNA (dsRNA) binding motif that is separated from the conserved E. coli RNase H1 region by a 62-amino acid sequence. These studies showed that although the conserved amino acid residues of the putative catalytic site and basic substrate-binding domain are required for RNase H activity, deletion of either the catalytic site or the basic substrate-binding domain did not ablate binding to the heteroduplex substrate. Deletion of the region between the dsRNA-binding domain and the conserved E. coli RNase H1 domain resulted in a significant loss in the RNase H activity. Furthermore, the binding affinity of this deletion mutant for the heteroduplex substrate was approximately 2-fold tighter than the wild-type enzyme suggesting that this central 62-amino acid region does not contribute to the binding affinity of the enzyme for the substrate. The dsRNA-binding domain was not required for RNase H activity, as the dsRNA-deletion mutants exhibited catalytic rates approximately 2-fold faster than the rate observed for wild-type enzyme. Comparison of the dissociation constant of human RNase H1 and the dsRNA-deletion mutant for the heteroduplex substrate indicates that the deletion of this region resulted in a 5-fold loss in binding affinity. Finally, comparison of the cleavage patterns exhibited by the mutant proteins with the cleavage pattern for the wild-type enzyme indicates that the dsRNA-binding domain is responsible for the observed strong positional preference for cleavage exhibited by human RNase H1.     

唾液乳杆菌BSH1及其突变体的底物特异性

为了解析胆盐水解酶催化中心中关键氨基酸位点与其底物特异性的关系,以大肠杆菌pET-20b(+)表达系统为分子改造平台,采用理性设计,结合氨基酸定点突变的方法,成功构建了唾液乳杆菌Lactobacillus salivarius胆盐水解酶BSH1的7种突变体。通过对比L.salivarius BSH1及其突变体对6种结合胆盐的底物特异性表明,7种突变体对不同的结合胆盐的水解活性有所改变。结果说明,Cys2和Thr264分别是BSH1催化TCA和GCA的关键残基,且对酶的催化活性的保持具有关键作用。其中,高保守性的氨基酸位点Cys2不是BSH1唯一的活性位点,而其他突变的氨基酸位点可能作为BSH1的结合位点参与了底物的结合,也可能影响了底物进入BSH1活性中心的通道或底物结合口袋的体积与形状,进而影响了BSH1对不同结合胆盐的水解活性。     

大肠杆菌碱性磷酸酶的体外定向进化研究

大肠杆菌碱性磷酸酶（E.coli alkaline phosphatase, EAP, EC 3.1.3.1）是一个非特异性二聚体磷酸单酯酶. 采用易错聚合酶链反应(error prone PCR)的方法,在原有高活力突变株的基础上,对EAP远离活性中心催化三联体的区域进行定向进化,经两轮error prone PCR,获得催化活力较亲本D101S突变株提高3倍、较野生型酶提高35倍的进化酶4-186,并对该酶的催化动力学特征进行了分析. 进化酶基因的DNA测序表明4-186含两个有义氨基酸置换：K167R和S374C,二者既不位于底物结合位点,也不位于酶的金属离子结合位点.     

Characterization of dual substrate binding sites in the homodimeric structure of Escherichia coli mRNA interferase MazF

MazF and MazE constitute a so-called addiction module that is critical for bacterial growth arrest and eventual cell death in response to stress. The MazF toxin was recently shown to possess mRNA interferase (MIase) activity, and acts as a protein synthesis inhibitor by cleaving cellular mRNA. As a cognate regulator, the short-lived antitoxin, MazE, inhibits MazF MIase activity and hence maintains the delicate homeostasis between these two components. In the present study, we have shown that the MazF homodimer contains two symmetric binding sites, each of which is capable of interacting with a MazE C-terminal peptide, MazEp(54-77). The slow exchange phenomenon between free and peptide-bound MazF on the NMR timescale indicates relatively high affinities for MazEp(54-77) at both sites (Kd,K'd < 10(-7) M). However, the observed sequential binding behavior suggests a negative cooperativity between the two sites (Kd < K'd). A 13 base single-stranded DNA, employed as an uncleavable RNA substrate analog, can also bind to both sites on the MazF homodimer with moderate affinity (Kd approximately 10(-5) -10(-6) M). Chemical shift perturbation data deduced from NMR experiments indicates that the two binding sites for the MazEp peptide coincided with those for the single-stranded DNA competitive inhibitor. These dual substrate-binding sites are located on the concave interface of the MazF homodimer, consisting of a highly basic region underneath the S1-S2 loop and two hydrophobic regions containing the H1 helix of one subunit and the S3-S4 loop of the opposing subunit. We show that the MazF homodimer is a bidentate endoribonuclease equipped with two identical binding sites for mRNA processing and that a single MazE molecule occupying one of the binding sites can affect the conformation of both sites, hence efficiently hindering the activity of MazF.     

Protein dynamics and motions in relation to their functions: several case studies and the underlying mechanisms

Proteins are dynamic entities in cellular solution with functions governed essentially by their dynamic personalities. We review several dynamics studies on serine protease proteinase K and HIV-1 gp120 envelope glycoprotein to demonstrate the importance of investigating the dynamic behaviors and molecular motions for a complete understanding of their structure–function relationships. Using computer simulations and essential dynamic (ED) analysis approaches, the dynamics data obtained revealed that: (i) proteinase K has highly flexible substrate-binding site, thus supporting the induced-fit or conformational selection mechanism of substrate binding; (ii) Ca²⁺ removal from proteinase K increases the global conformational flexibility, decreases the local flexibility of substrate-binding region, and does not influence the thermal motion of catalytic triad, thus explaining the experimentally determined decreased thermal stability, reduced substrate affinity, and almost unchanged catalytic activity upon Ca²⁺ removal; (iii) substrate binding affects the large concerted motions of proteinase K, and the resulting dynamic pocket can be connected to substrate binding, orientation, and product release; (iv) amino acid mutations 375 S/W and 423 I/P of HIV-1 gp120 have distinct effects on molecular motions of gp120, facilitating 375 S/W mutant to assume the CD4-bound conformation, while 423 I/P mutant to prefer for CD4-unliganded state. The mechanisms underlying protein dynamics and protein–ligand binding, including the concept of the free energy landscape (FEL) of the protein–solvent system, how the ruggedness and variability of FEL determine protein’s dynamics, and how the three ligand-binding models, the lock-and-key, induced-fit, and conformational selection are rationalized based on the FEL theory are discussed in depth.     

The crystal structure of polyhydroxybutyrate depolymerase from Penicillium funiculosum provides insights into the recognition and degradation of biopolyesters

Polyhydroxybutyrate is a microbial polyester that can be produced from renewable resources, and is degraded by the enzyme polyhydroxybutyrate depolymerase. The crystal structures of polyhydroxybutyrate depolymerase from Penicillium funiculosum and its S39 A mutant complexed with the methyl ester of a trimer substrate of (R)-3-hydroxybutyrate have been determined at resolutions of 1.71 A and 1.66 A, respectively. The enzyme is comprised of a single domain, which represents a circularly permuted variant of the alpha/beta hydrolase fold. The catalytic residues Ser39, Asp121, and His155 are located at topologically conserved positions. The main chain amide groups of Ser40 and Cys250 form an oxyanion hole. A crevice is formed on the surface of the enzyme, to which a single polymer chain can be bound by predominantly hydrophobic interactions with several hydrophobic residues. The structure of the S39A mutant-trimeric substrate complex reveals that Trp307 is responsible for the recognition of the ester group adjacent to the scissile group. It is also revealed that the substrate-binding site includes at least three, and possibly four, subsites for binding monomer units of polyester substrates. Thirteen hydrophobic residues, which are exposed to solvent, are aligned around the mouth of the crevice, forming a putative adsorption site for the polymer surface. These residues may contribute to the sufficient binding affinity of the enzyme for PHB granules without a distinct substrate-binding domain.     

Mechanism of gamma-secretase cleavage activation: is gamma-secretase regulated through autoinhibition involving the presenilin-1 exon 9 loop?

Maturation of gamma-secretase requires an endoproteolytic cleavage in presenilin-1 (PS1) within a peptide loop encoded by exon 9 of the corresponding gene. Deletion of the loop has been demonstrated to cause familial Alzheimer's disease. A synthetic peptide corresponding to the loop sequence was found to inhibit gamma-secretase in a cell-free enzymatic assay with an IC(50) of 2.1 microM, a value similar to the K(m) (3.5 microM) for the substrate C100. Truncation at either end, single amino acid substitutions at certain residues, sequence reversal, or randomization reduced its potency. Similar results were also observed in a cell-based assay using HEK293 cells expressing APP. In contrast to small-molecule gamma-secretase inhibitors, kinetic inhibition studies demonstrated competitive inhibition of gamma-secretase by the exon 9 peptide. Consistent with this finding, inhibitor cross-competition kinetics indicated noncompetitive binding between the exon 9 peptide and L685458, a transition-state analogue presumably binding at the catalytic site, and ligand competition binding experiments revealed no competition between L685458 and the exon 9 peptide. These data are consistent with the proposed gamma-secretase mechanism involving separate substrate-binding and catalytic sites and binding of the exon 9 peptide at the substrate-binding site, but not the catalytic site of gamma-secretase. NMR analyses demonstrated the presence of a loop structure with a beta-turn in the middle of the exon 9 peptide and a loose alpha-helical conformation for the rest of the peptide. Such a structure supports the hypothesis that this exon 9 peptide can adopt a distinct conformation, one that is compact enough to occupy the putative substrate-binding site without necessarily interfering with binding of small molecule inhibitors at other sites on gamma-secretase. We hypothesize that gamma-secretase cleavage activation may be a result of a cleavage-induced conformational change that relieves the inhibitory effect of the intact exon 9 loop occupying the substrate-binding site on the immature enzyme. It is possible that the DeltaE9 mutation causes Alzheimer's disease because cleavage activation of gamma-secretase is no longer necessary, alleviating constraints on Abeta formation.     

Potent anticoagulant aptamer directed against factor IXa blocks macromolecular substrate interaction

An aptamer targeting factor IXa has been evaluated in animal models and several clinical studies as a potential antithombotic therapy. We elucidate the molecular mechanism by which this aptamer acts as an anticoagulant. The aptamer binds tightly to factor IXa and prolongs the clotting time of human plasma. The aptamer completely blocks factor IXa activation of factor X regardless of the presence of factor VIIIa. However, the aptamer does not completely block small synthetic substrate cleavage, although it does slow the rate of cleavage. These data are consistent with the aptamer binding to the catalytic domain of factor IXa in such a way as to block an extended substrate-binding site. Therefore, unlike small molecule inhibitors, aptamers appear to be able to bind surfaces surrounding an active site and thereby sterically interfere with enzyme activity. Thus, aptamers may be useful agents to probe and block substrate-binding sites outside of the active site of an enzyme.     

Changes in zinc ligation promote remodeling of the active site in the zinc hydrolase superfamily.

The zinc hydrolase superfamily is a group of divergently related proteins that are predominantly enzymes with a zinc-based catalytic mechanism. The common structural scaffold of the superfamily consists of an eight-stranded beta-sheet flanked by six alpha-helices. Previous analyses, while acknowledging the likely divergent origins of leucine aminopeptidase, carboxypeptidase A and the co-catalytic enzymes of the metallopeptidase H clan based on their structural scaffolds, have failed to find any homology between the active sites in leucine aminopeptidase and the metallopeptidase H clan enzymes. Here we show that these two groups of co-catalytic enzymes have overlapping dizinc centers where one of the two zinc atoms is conserved in each group. Carboxypeptidase A and leucine aminopeptidase, on the other hand, no longer share any homologous zinc-binding sites. At least three catalytic zinc-binding sites have existed in the structural scaffold over the period of history defined by available structures. Comparison of enzyme-inhibitor complexes show that major remodeling of the substrate-binding site has occurred in association with each change in zinc ligation in the binding site. These changes involve re-registration and re-orientation of the substrate. Some residues important to the catalytic mechanism are not conserved amongst members. We discuss how molecules acting in trans may have facilitated the mutation of catalytically important residues in the active site in this group.     

Structural and mutational studies on the importance of oligosaccharide binding for the activity of yeast PNGase

Peptide:N-glycanase (PNGase) is an important component of the endoplasmic reticulum-associated protein degradation pathway in which it de-glycosylates misfolded glycoproteins, thus facilitating their proteasomal degradation. PNGase belongs to the transglutaminase superfamily and features a Cys, His, and Asp catalytic triad, which is essential for its enzymatic activity. An elongated substrate-binding groove centered on the active site Cys191 was visualized in the crystal structure of apo-PNGase, whereas its complex with Z-VAD-fmk, a peptide-based inhibitor of PNGase, revealed that the inhibitor occupied one end of the substrate-binding groove while being covalently linked to the active site Cys. Recently, haloacetamidyl-containing carbohydrate-based inhibitors of PNGase were developed and shown to specifically label the active site Cys. In this study, we describe the crystal structure of yeast PNGase in complex with N,N'-diacetylchitobiose (chitobiose). We found that the chitobiose binds on the side opposite to the peptide binding site with the active site Cys191 being located approximately midway between the carbohydrate and peptide binding sites. Mutagenesis studies confirm the critical role of the chitobiose-interacting residues in substrate binding and suggest that efficient oligosaccharide binding is required for PNGase activity. In addition, the N-terminus of a symmetry-related PNGase was found to bind to the proposed peptide-binding site of PNGase. Together with the bound chitobiose, this enables us to propose a model for glycoprotein binding to PNGase. Finally, deleting the C-terminal residues of yeast PNGase, which are disordered in all structures of this enzyme, results in a significant reduction in enzyme activity, indicating that these residues might be involved in binding of the mannose residues of the glycan chain.     

Effect of the epsilon-subunit on nucleotide binding to Escherichia coli F1-ATPase catalytic sites.

The influence of the epsilon-subunit on the nucleotide binding affinities of the three catalytic sites of Escherichia coli F1-ATPase was investigated, using a genetically engineered Trp probe in the adenine-binding subdomain (beta-Trp-331). The interaction between epsilon and F1 was not affected by the mutation. Kd for binding of epsilon to betaY331W mutant F1 was approximately 1 nM, and epsilon inhibited ATPase activity by 90%. The only nucleotide binding affinities that showed significant differences in the epsilon-depleted and epsilon-replete forms of the enzyme were those for MgATP and MgADP at the high-affinity catalytic site 1. Kd1(MgATP) and Kd1(MgADP) were an order of magnitude higher in the absence of epsilon than in its presence. In contrast, the binding affinities for MgATP and MgADP at sites 2 and 3 were similar in the epsilon-depleted and epsilon-replete enzymes, as were the affinities at all three sites for free ATP and ADP. Comparison of MgATP binding and hydrolysis parameters showed that in the presence as well as the absence of epsilon, Km equals Kd3. Thus, in both cases, all three catalytic binding sites have to be occupied to obtain rapid (Vmax) MgATP hydrolysis rates.     

Redesigning the substrate specificity of omega-aminotransferase for the kinetic resolution of aliphatic chiral amines

Substrate specificity of the omega-aminotransferase obtained from Vibrio fluvialis (omega-ATVf) was rationally redesigned for the kinetic resolution of aliphatic chiral amines. omega-ATVf showed unique substrate specificity toward aromatic amines with a high enantioselectivity (E > 100) for (S)-enantiomers. However, the substrate specificity of this enzyme was much narrower toward aliphatic amines. To overcome the narrow substrate specificity toward aliphatic amines, we redesigned the substrate specificity of omega-ATVf using homology modeling and the substrate structure- activity relationship. The homology model and the substrate structure-activity relationship showed that the active site of omega-ATVf consists of one large substrate-binding site and another small substrate-binding site. The key determinant in the small substrate-binding site was D25, whose role was expected to mask R415 and to generate the electrostatic repulsion with the substrate's alpha-carboxylate group. In the large substrate-binding site, R256 was predicted to recognize the alpha-carboxylate group of substrate thus obeying the dual substrate recognition mechanism of aminotransferase subgroup II enzymes. Among the several amino acid residues in the large substrate-binding site, W57 and W147, with their bulky side chains, were expected to restrict the recognition of aliphatic amines. Two mutant enzymes, W57G and W147G, showed significant changes in their substrate specificity such that they catalyzed transamination of a broad range of aliphatic amines without losing the original activities toward aromatic amines and enantioselectivity.