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.     

Exosite interactions determine the affinity of factor X for the extrinsic Xase complex

The initiation of coagulation results from the activation of factor X by an enzyme complex (Xase) composed of the trypsin-like serine proteinase, factor VIIa, bound to tissue factor (TF) on phospholipid membranes. We have investigated the basis for the protein substrate specificity of Xase using TF reconstituted into vesicles of phosphatidylcholine, phosphatidylserine, or pure phosphatidylcholine. We show that occupation of the active site of VIIa within Xase by a reversible inhibitor or an alternate peptidyl substrate is sufficient to exclude substrate interactions at the active site but does not alter the affinity of Xase for factor X. This is evident as classical competitive inhibition of peptidyl substrate cleavage but as classical noncompetitive inhibition of factor X activation by active site-directed ligands. This implies that the productive recognition of factor X by Xase arises from a multistep reaction requiring an initial interaction at sites on the enzyme complex distinct from the active site (exosites), followed by active site interactions and bond cleavage. Exosite interactions determine protein substrate affinity, whereas the second binding step influences the maximum catalytic rate for the reaction. We also show that competitive inhibition can be achieved by interfering with exosite binding using factor X derivatives that are expected to have limited or abrogated interactions with the active site of VIIa within Xase. Thus, substrate interactions at exosites, sites removed from the active site of VIIa within the enzyme complex, determine affinity and binding specificity in the productive recognition of factor X by the VIIa-TF complex. This may represent a prevalent strategy through which distinctive protein substrate specificities are achieved by the homologous enzymes of coagulation.     

Relationship between two types of mouse sperm surface sites that mediate binding of sperm to the zona pellucida

There are at least two binding sites for the mouse egg zona pellucida on the surface of mouse sperm: a site with galactosyltransferase (GT) activity inhibitable by uridine-5'-diphosphate-dialdehyde (UDPd) and alpha-lactalbumin, and a trypsin inhibitor-sensitive (TI) site that hydrolyzes guanidinobenzoate (GB) esters. Characterization of GT activity gave the Km for UDP galactose as 37 microM with N-acetylglucosamine as galactose acceptor, and Vmax as 0.37 pmol/min/10(6) sperm. UDP galactose from 12.5-100 microM inhibited sperm binding to zona-intact eggs in a concentration-dependent manner with close correlation to GT activity (r = 0.95). To assess the independence and spatial relationship of the two types of site, cross-perturbation studies were performed. p-Nitrophenyl-GB, a low molecular mass inhibitor specific for the TI site, had no effect on the enzyme activity of the GT site. Conversely, UDPd, a specific inhibitor of GT, had no effect on GB hydrolysis. Weak inhibitions were found when soybean trypsin inhibitor (SBTI) was included with the GT assay and when GB hydrolysis was assayed in the presence of alpha-lactalbumin or asialo-agalacto-(alpha 1-acid glycoprotein). Acid-solubilized zona protein (ASZP) weakly inhibited the GT reaction, while stronger inhibition was seen with chymotrypsin-solubilized zona protein (CSZP). ASZP inhibited sperm binding to zonae with the same concentration dependence associated with inhibition of GB hydrolysis, but the inhibition of GT enzyme activity was on the same order as that found with SBTI, indicating that ASZP was only binding to the TI site under enzyme assay conditions. The results support the hypothesis that the two types of site are independent in binding their specific zona ligands, but are close enough for steric perturbation of the enzyme activity of one site by macromolecules bound to the other. The different interactions of solubilized zona preparations with the GT site under enzyme assay conditions are an indication that conditions which favor the enzyme activity of the site may interfere with the physiological binding functions of the site.     

Exosite binding tethers the macromolecular substrate to the prothrombinase complex and directs cleavage at two spatially distinct sites

The prothrombinase complex, composed of the proteinase, factor Xa, bound to factor Va on membranes, catalyzes thrombin formation by the specific and ordered proteolysis of prothrombin at Arg(323)-Ile(324), followed by cleavage at Arg(274)-Thr(275). We have used a fluorescent derivative of meizothrombin des fragment 1 (mIIaDeltaF1) as a substrate analog to assess the mechanism of substrate recognition in the second half-reaction of bovine prothrombin activation. Cleavage of mIIaDeltaF1 exhibits pseudo-first order kinetics regardless of the substrate concentration relative to K(m). This phenomenon arises from competitive product inhibition by thrombin, which binds to prothrombinase with exactly the same affinity as mIIaDeltaF1. As thrombin is known to bind to an exosite on prothrombinase, initial interactions at an exosite likely play a role in the enzyme-substrate interaction. Occupation of the active site of prothrombinase by a reversible inhibitor does not exclude the binding of mIIaDeltaF1 to the enzyme. Specific recognition of mIIaDeltaF1 is achieved through an initial bimolecular reaction with an enzymic exosite, followed by an active site docking step in an intramolecular reaction prior to bond cleavage. By alternate substrate studies, we have resolved the contributions of the individual binding steps to substrate affinity and catalysis. This pathway for substrate binding is identical to that previously determined with a substrate analog for the first half-reaction of prothrombin activation. We show that differences in the observed kinetic constants for the two cleavage reactions arise entirely from differences in the inferred equilibrium constant for the intramolecular binding step that permits elements surrounding the scissile bond to dock at the active site of prothrombinase. Therefore, substrate specificity is achieved by binding interactions with an enzymic exosite that tethers the protein substrate to prothrombinase and directs cleavage at two spatially distinct scissile bonds.     

Mechanism of gold nanoparticles-induced trypsin inhibition: a multi-technique approach

The binding interactions of gold nanoparticles with trypsin were investigated using multi-spectra methods and molecular modeling. The experiment data showed that trypsin modified the surface of gold nanoparticles. The fluorescence intensity of trypsin was quenched by gold nanoparticles that strongly associated with protein and induced the inhibition of enzyme activity. The electrostatic and hydrophobic interactions were the primary contributors to the binding forces between trypsin and gold nanoparticles. The covalent interactions might be also involved in the binding process. The modeling calculated results indicated that the binding site was near to the primary substrate-binding pocket and the active site of the enzyme substrate. This work elucidated the interaction mechanism of trypsin with gold nanoparticles from the theoretical and experimental angle.     

On the catalytic and binding sites of porcine enteropeptidase.

The active site of porcine enteropeptidase (EC 3.4.21.9) was investigated in order to characterize better both catalytic and binding sites. The participation of a serine and a histidine residue in the catalytic process was fully confirmed and the two residues were located on the light chain of the enzyme. The binding site was found to be composed of at least 2 subsites S1 and S2. The subsite S1 (similar to the trypsin-binding site) is responsible for the interactions with the small substrates of trypsin and the lysine side chain of trypsinogen, while subsite S2 (probably a cluster of lysines) is responsible for the interactions with the polyanionic sequence found in all trypsinogens. Binding of substrate by subsite S2 led to an increased efficiency of the catalytic site which can be correlated to the known high specificity of enteropeptidase.     

Uncoupled Active Transport Mechanisms Accounting for Low Selectivity in Multidrug Carriers: P-Glycoprotein and SMR Antiporters

The extraordinarily low substrate specificity of P-glycoprotein conflicts with the notion that specific substrate interactions are required in the control of the reaction path in an active transport system. The difficulty is shown to be overcome by a half-coupled mechanism in which the ATP reaction is linked to carrier transformations, as in a fully coupled system, but in which the transported substrate plays a passive role. The mechanism, which requires no specific interaction with the substrate, brings about uphill transport. A half-coupled mechanism is directly supported by two observations: (i) almost completely uncoupled ATPase activity in purified P-glycoprotein, and (ii) a pattern of substrate specificity like that of passive systems, where maximum rates for different substrates vary little (unlike active systems, where maximum rates vary greatly). The mechanism accommodates other findings: partial inhibition of ATPase activity by an actively transported substrate; simultaneous binding and translocation of more than one substrate molecule; and stimulation or inhibition of the transport of one substrate molecule by another. A half-coupled system associated with an internal competitive inhibitor should behave as if tightly coupled, in agreement with the effects of the synthetic peptide, polytryptophan. The degree of coupling in the intact system is yet to be determined, however. A half-coupled ATPase mechanism could originally have evolved in a flippase, where immersion of the carrier in its substrate, the membrane lipid, precludes uncoupled ATP hydrolysis. These concepts may have wider application. An uncoupled antiport mechanism, driven by a proton gradient rather than ATP, can explain low selectivity in the SMR multidrug carriers of bacteria, and a half-coupled mechanism for the ion-driven cotransport of water (the substrate in which the carrier site is immersed) can explain a recently proposed uphill flow of water. Received: 23 April 1999/Revised: 29 July 1999     

Hydrophobic interaction of alpha-chymotrypsin with low molecular weight compounds

Data on alpha-chymotrypsin interactions with hydrophobic low-molecular compounds have been generalized. Existence of two sites of noncovalent interaction with hydrophobic nuclei of a ligand molecule is shown. When the substance to be bound contains only one hydrophobic nucleus, the interaction is mediated by a "hydrophobic pocket" of the enzyme--a binding site of amino acid residues which are, in the P1-position relative to the cleaved bond. Under these conditions substances with an asymmetric hydrophobic nucleus (of the tryptophan type) are better ligands for binding. In case of compounds containing several hydrophobic groups scattered in the space, interaction with the enzyme proceeds in two binding sites. New data are presented on the ligand specificity for binding sites of chymotrypsin in lower vertebrates. Relative position of hydrophobic groups of the ligand is shown as that of great importance for interaction with the enzyme. It is concluded that the binding sites of trypsin- and chymotrypsin-like proteinases of the lower vertebrates differ but less from each other as compared to binding sites of trypsin and chymotrypsin in mammals.     

Synthesis and characterization of a pancreatic trypsin inhibitor homologue and a model inhibitor.

The synthesis and characterization of protein proteinase inhibitor homologues with variations in the amino acid composition in the vicinity of the reactive site should aid the understanding of the mechanism by which inhibition of enzymatic activity occurs. A homologue inhibitor in which the reactive-site residue Ala-16 of basic pancreatic trypsin inhibitor (Kunitz) (BPTI) is replaced by Phe has been synthesized to study the effect of this replacement on the dissociation constants of the enzyme-inhibitor complexes. The replacement of Ala-16 by Phe causes a dramatic increase in the K1 value of the trypsin-BPTI complex while that of the chymotrypsin-BPTI complex remains essentially the same. This cannot be explained simply in terms of increased steric crowding. The Phe replacement probably causes a small change in the local conformation of the reactive site of the inhibitor which leads to a large decrease in the stability of the very tight trypsin-BPTI complex. This conformation change apparently can be tolerated in the less tightly bound chymotrypsin-BPTI complex. On the basis of the known structure of BPTI, a cyclic heptadecapeptide containing one disulfide bond was synthesized as a model inhibitor in order to determine if a smaller peptide can be designed to act as a highly efficient inhibitor for trypsin. This heptadecapeptide which contains all of the amino acid residues of BPTI taking part in the interaction of the proteinase inhibitor with trypsin binds 3 X 10(7) time more weakly to the enzyme than native BPTI does. It thus appears that even though only a small part of the inhibitor molecule enters directly into interaction with the enzyme, the remaining portions of the molecule which hold the structure of the inhibitor rigid are essential for the strong interaction.     

A new beta-naphthylamide substrate of p-guanidino-L-phenylalanine for trypsin and related enzymes

N alpha-Benzyloxycarbonyl-p-guanidino-L-phenylalanine beta-naphthylamide (Z-GPA-beta NA) was synthesized and the susceptibility of this compound to trypsin and related enzymes was compared with that of N alpha-benzyloxycarbonyl-L-arginine beta-naphthylamide (Z-Arg-beta NA). Both Z-GPA-beta NA and Z-Arg-beta NA were rapidly and almost completely hydrolyzed by trypsin and pronase. Z-Arg-beta NA was hydrolyzed slowly by thrombin, while Z-GPA-beta NA was not susceptible to this enzyme at all. The rate of hydrolysis of Z-GPA-beta NA by papain was slower than that of Z-Arg-beta NA. Neither beta-naphthylamide substrate was hydrolyzed by alpha-chymotrypsin. The specificity constant (kcat/Km) for the hydrolysis of Z-GPA-beta NA by trypsin was somewhat larger than that for the hydrolysis of Z-Arg-beta NA. Contributions of the benzene ring in the side chain of Z-GPA-beta NA to good binding of this substrate to the specificity site of this enzyme and to the poor fit of the scissile bond in the substrate molecule to the active serine residue are presumed from comparison of the individual kinetic parameters (Km and kcat) for the two beta-naphthylamide substrates. Z-GPA-beta NA was ascertained to be a useful substrate in the study of the binding and catalytic specificities of various trypsin-like enzymes.     

Inhibition of beta-glucosidase by imidazoles

Over 25 nitrogen-containing heterocycles were tested as inhibitors of sweet almond beta-glucosidase (EC 3.2.1.21). Among the most potent of these are some imidazole derivatives. The pH dependence indicates that the unprotonated inhibitor binds most tightly to the catalytically active species of the enzyme. This is analogous to the situation with 1-deoxynojirimycin where the permanently cationic species, N,N-dimethyl-1-deoxynojirimycin, binds at least two orders of magnitude less tightly to the enzyme than does the unprotonated 1-deoxynojirimycin. The binding of imidazole derivatives show a general tendency of increasing affinity with increasing basicity (beta approximately 0.4). One derivative which shows a significant positive deviation from this correlation (- log Ki vs. pKa) is 4-phenylimidazole. 4-Phenylimidazole is one of the most potent reversible inhibitors of beta-glucosidase with a pH-independent Ki = 0.8 microM. It is also fairly specific for beta-glucosidase, binding at least three orders of magnitude less tightly to any of the other exoglycosidases tested. This inhibitor combines, in a mono-molecular species, the binding affinities of benzene, which binds at the hydrophobic aglycone binding site, and imidazole, which binds at the sugar binding site of beta-glucosidase. The binding energy of 4-phenylimidazole can be attributed to the sum of the intrinsic binding energies of the phenyl and imidazole moieties. Thus, there is no significant entropic advantage of combining the component parts of phenylimidazole in a single species. This indicates that there is no significant uncompensated entropy loss upon binding of either benzene or imidazole to the enzyme. Nevertheless, the additivity of binding energy, even in the absence of an entropic advantage, results in the most powerful known inhibitor of the enzyme.     

Macromolecular chelation as an improved mechanism of protease inhibition: structure of the ecotin-trypsin complex.

The 2.4 A crystal structure (R = 0.180) of the serine protease inhibitor ecotin was determined in a complex with trypsin. Ecotin's dimer structure provides a second discrete and distal binding site for trypsin and, as shown by modelling experiments, other serine proteases. The second site is approximately 45 A from the reactive/active site of the complex and features 13 hydrogen bonds, including six that involve carbonyl oxygen atoms and four bridged by water molecules. Contacts ecotin makes with trypsin's active site are similar to, though more extensive than, those found between trypsin and basic pancreatic trypsin inhibitor. The side chain of ecotin Met84 is found in the substrate binding pocket of trypsin where it makes few contacts, but also does not disrupt the solvent structure or cause misalignment of the scissile bond. This first case of protein dimerization being used to augment binding energy and allow chelation of a target protein provides a new model for protein-protein interactions and for protease inhibition.     

Insight into the structural basis of the dual inhibitory mode of Lima bean (Phaseolus lunatus) serine protease inhibitor

Bovine pancreatic trypsin was crystallized, in-complex with Lima bean trypsin inhibitor (LBTI) (Phaseolus lunatus L.), in the form of a ternary complex. LBTI is a Bowman–Birk-type bifunctional serine protease inhibitor, which has two independent inhibitory loops. Both of the loops can inhibit trypsin, however, only the hydrophobic loop is specific for inhibiting chymotrypsin. The structure of trypsin incomplex with the LBTI has been solved and refined at 2.25 Å resolution, in the space group P4_1, with R_work/R_free values of 18.1/23.3. The two binding sites of LBTI differ in only two amino acids. Lysine and leucine are the key residues of the two different binding loops positioned at the P1, and involved in binding the S1 binding site of trypsin. The asymmetric unit cell contains two molecules of trypsin and one molecule of LBTI. The key interactions include hydrogen bonds between LBTI and active site residues of trypsin. The 3D structure of the enzyme–inhibitor complex provided details insight into the trypsin inhibition by LBTI. To the best of our knowledge, this is the first report on the structure of trypsin incomplex with LBTI.     

Inhibition of factor Xa by a peptidyl-alpha-ketothiazole involves two steps. Evidence for a stabilizing conformational change.

Recently, peptidylketothiazoles have been shown to be potent inhibitors of proteases, but the details of the interaction have not yet been studied. In the work presented here, the interaction of factor Xa, a coagulation protease, with the transition state inhibitor BnSO(2)-D-Arg-Gly-Arg-ketothiazole (C921-78) is characterized. C921-78 is a tight and selective inhibitor of the coagulation protease factor Xa (K(d) = 14 pM). The hydrolytic activity of factor Xa was inhibited by C921-78 in a time-dependent manner. The rate-limiting step of the bimolecular combination of inhibitor and enzyme was competitive with the substrate. Conversely, the inhibitor could be displaced from the active site of the enzyme after exposure of the preformed complex to an excess of substrate or to the active site inhibitor dansyl-Glu-Gly-Arg-chloromethyl ketone (DEGR-CMK) in a slow reaction. The formation of the C921-78-factor Xa complex resulted in a 60% increase in the magnitude of the fluorescence emission spectrum. Rapid mixing of the enzyme and inhibitor produces a monophasic fluorescence increase, compatible with spectral transition in a single step. The rate constant for this reaction increased hyperbolically with the concentration of C921-78, but the amplitude remained constant. These results are consistent with the initial formation of an enzyme-inhibitor complex (EI), followed by a unimolecular conversion of EI to EI linked to a spectral transition. The rate constants of the isomerization provide an estimate of 300000-fold stabilization. Thus, the inhibition of factor Xa by C921-78 follows a mechanism similar to that described classically for slow tight binding inhibitors. However, the two steps of the reaction cannot be kinetically separated by the rapid equilibrium assumption, and therefore, the formation of EI is partially rate-limiting, too. The driving energy for the unusually fast isomerization step may result from the highly favorable interactions of the inhibitor in the primary binding site.     

Enzymatic properties of alpha 2-macroglobulin-proteinase complexes. Apparent discrimination between covalently and noncovalently bound trypsin by reaction with soybean trypsin inhibitor

The binding of trypsin to alpha 2-macroglobulin, the appearance of free beta-cysteinyl thiol groups of the formed complexes, the steady-state kinetics of their enzymic hydrolysis of carbobenzoxy-L-valyl-glycyl-L-arginyl-4-nitroanilide and finally their reactions with soybean trypsin inhibitor leading to the formation of ternary alpha 2-macroglobulin-trypsin-soybean trypsin inhibitor complexes were investigated. Each alpha 2-macroglobulin molecule binds two trypsin tightly; the dissociation constants were found to be unmeasureably small, but the extent of formation of 1:1 and 1:2 complexes at different molar ratios of alpha 2-macroglobulin to trypsin as determined from the appearance of thiol groups clearly indicated that binding of trypsin to alpha 2-macroglobulin shows negative cooperativity. Binding of the first trypsin makes the access of the second less easy. The kinetic results showed a decrease of the kc/Km value of hydrolysis of the tripeptide substrate by approx. 4-fold compared to that of free trypsin for each alpha 2-macroglobulin-bound trypsin. Here no differences were seen between the bound trypsins. The analysis of the reactions between the alpha 2-macroglobulin-trypsin complexes and soybean trypsin inhibitor shows that ternary complexes do form, although slowly, and that two processes occur, not only when 1:2 complexes but also when 1:1 complexes react with soybean trypsin inhibitor. Soybean trypsin inhibitor apparently discriminates between two distinct binding modes of trypsin to alpha 2-macroglobulin, the covalently and the noncovalently alpha 2-macroglobulin-bound trypsins.     

Conformational aspects of beta-trypsin interaction with substrates and pancreatic trypsin inhibitor. III. Catalytic act of trypsin and its inhibition

Basing on the results of the theoretical conformational analysis of the nonbonded and valence complexes of trypsin with substrate molecules, the catalytical act of the enzyme is described in details as a spontaneous process. Conformational aspects of interactions of trypsin with pancreatic trypsin inhibitor are analysed. The complete inhibition process and the geometry of the enzyme-inhibitor complex are described in details. The point amino acid replacements, which will provide for an exclusion of BPTI inhibition and will radically change the specificity of the enzyme are proposed.     

Active site-independent recognition of substrates and product by bovine prothrombinase: a fluorescence resonance energy transfer study

The conversion of prothrombin to thrombin is catalyzed by prothrombinase, an enzyme complex composed of the serine proteinase factor Xa and a cofactor protein, factor Va, assembled on membranes. Kinetic studies indicate that interactions with extended macromolecular recognition sites (exosites) rather than the active site of prothrombinase are the principal determinants of binding affinity for substrate or product. We now provide a model-independent evaluation of such ideas by physical studies of the interaction of substrate derivatives and product with prothrombinase. The enzyme complex was assembled using Xa modified with a fluorescent peptidyl chloromethyl ketone to irreversibly occlude the active site. Binding was inferred by prethrombin 2-dependent perturbations in the fluorescence of Oregon Green(488) at the active site of prothrombinase. Active site-independent binding was also unequivocally established by fluorescence resonance energy transfer between 2,6-dansyl tethered to the active site of Xa and eosin tethered to the active sites of either thrombin or meizothrombin des fragment 1. Comparable interprobe distances obtained from these measurements suggest that substrate and product interact equivalently with the enzyme. Competition established the ability of a range of substrate or product derivatives to bind in a mutually exclusive fashion to prothrombinase. Equilibrium dissociation constants obtained for the active site-independent binding of prothrombin, prethrombin 2, meizothrombin des fragment 1 and thrombin to prothrombinase were comparable with their affinities inferred from kinetic studies using active enzyme. Our findings directly establish that binding affinity is principally determined by the exosite-mediated interaction of either the substrate, both possible intermediates, or product with prothrombinase. A single type of exosite binding interaction evidently drives affinity and binding specificity through the stepwise reactions necessary for the two cleavage reactions of prothrombin activation and product release.     

Extended intermolecular interactions in a serine protease-canonical inhibitor complex account for strong and highly specific inhibition

We have previously shown that a trypsin inhibitor from desert locust Schistocerca gregaria (SGTI) is a taxon-specific inhibitor that inhibits arthropod trypsins, such as crayfish trypsin, five orders of magnitude more effectively than mammalian trypsins. Thermal denaturation experiments, presented here, confirm the inhibition kinetics studies; upon addition of SGTI the melting temperatures of crayfish and bovine trypsins increased 27 degrees C and 4.5 degrees C, respectively. To explore the structural features responsible for this taxon specificity we crystallized natural crayfish trypsin in complex with chemically synthesized SGTI. This is the first X-ray structure of an arthropod trypsin and also the highest resolution (1.2A) structure of a trypsin-protein inhibitor complex reported so far. Structural data show that in addition to the primary binding loop, residues P3-P3' of SGTI, the interactions between SGTI and the crayfish enzyme are also extended over the P12-P4 and P4'-P5' regions. This is partly due to a structural change of region P10-P4 in the SGTI structure induced by binding of the inhibitor to crayfish trypsin. The comparison of SGTI-crayfish trypsin and SGTI-bovine trypsin complexes by structure-based calculations revealed a significant interaction energy surplus for the SGTI-crayfish trypsin complex distributed over the entire binding region. The new regions that account for stronger and more specific binding of SGTI to crayfish than to bovine trypsin offer new inhibitor sites to engineer in order to develop efficient and specific protease inhibitors for practical use.     

In silico analyses of substrate interactions with human serum paraoxonase 1

Human paraoxonase (HuPON1) is a serum enzyme that exhibits a broad spectrum of hydrolytic activities, including the hydrolysis of various organophosphates, esters, and recently identified lactone substrates. Despite intensive site-directed mutagenesis and other biological studies, the structural basis for the specificity of substrate interactions of HuPON1 remains elusive. In this study, we apply homology modeling, docking, and molecular dynamic (MD) simulations to probe the binding interactions of HuPON1 with representative substrates. The results suggest that the active site of HuPON1 is characterized by two distinct binding regions: the hydrophobic binding site for arylesters/lactones, and the paraoxon binding site for phosphotriesters. The unique binding modes proposed for each type of substrate reveal a number of key residues governing substrate specificity. The polymorphic residue R/Q192 interacts with the leaving group of paraoxon, suggesting it plays an important role in the proper positioning of this substrate in the active site. MD simulations of the optimal binding complexes show that residue Y71 undergoes an "open-closed" conformational change upon ligand binding, and forms strong interactions with substrates. Further binding free energy calculations and residual decomposition give a more refined molecular view of the energetics and origin of HuPON1/substrate interactions. These studies provide a theoretical model of substrate binding and specificity associated with wild type and mutant forms of HuPON1, which can be applied in the rational design of HuPON1 variants as bioscavengers with enhanced catalytic activity.     

Cytochrome P-450scc-substrate interactions. Role of the 3 beta- and side chain hydroxyls in binding to oxidized and reduced forms of the enzyme

The steroid binding specificity of cytochrome P-450scc has been investigated for different oxidation/reduction and ligand-binding states of the enzyme (oxidized, reduced, oxygen-bound, and carbon monoxide-bound forms). The oxygen of the 3 beta-hydroxyl of cholesterol is important for the initial enzyme-substrate interaction. Significant binding requires the correct stereochemistry and appears to be controlled by the electron density on the 3 beta-oxygen. Interactions at this position (located at least 13 A from the heme iron) can modulate the heme midpoint potential. The binding site in this region contains a cleft which can accommodate up to two carbons joined in an ether linkage to the 3 beta-oxygen. The steroid intermediates of side chain cleavage (22R-hydroxycholesterol and 20 alpha,22R-dihydroxycholesterol) bind more tightly to the ferric enzyme than does cholesterol and utilize specific interactions of these side chain hydroxyls with a grouping(s) on the polypeptide chain (i.e. not with the heme iron). The interaction requires the correct stereochemistry; a 22S-hydroxyl cannot be readily accommodated in the binding site. The specificity of the interaction for hydroxyls at the 22R- versus the 20 alpha-position is altered upon reduction of the enzyme, indicating a reduction-induced conformational change in the active site. The specific interference of binding of 22R-hydroxy steroids by heme-bound carbon monoxide (but not oxygen), together with the known bond angles and distances for Fe-C-O and Fe-O-O, allows localization of the 22R-hydroxyl group on a line perpendicular to the heme plane, between 2 and 3 A from the iron.