Influence of size and polarity of residue 31 in porcine pancreatic phospholipase A2 on catalytic properties

Residue 31 of porcine pancreatic phospholipase A₂ (PLA₂) islocated at the entrance to the active site. To study the roleof residue 31 in PLA₂, six mutant enzymes were produced by site-directedmutagenesis, replacing Leu by either Trp, Arg, Ala, Thr, Seror Gly. Direct binding studies indicated a three to six timesgreater affinity of the Trp31 PLA₂ for both monomeric and micellarsubstrate analogs, relative to the wild-type enzyme. The otherfive mutants possess an unchanged affinity for monomers of theproduct analog n-decylphosphocholine and for micelles of thediacyl substrate analog rac-l,2-dioctanoylamino-dideoxy-glycero-3-phosphocholine.The affinities for micelles of the monoacyl product analog n-hexadecylphosphocholinewere decreased 9–20 times for these five mutants. Kineticstudies with monomeric substrates showed that the mutants haveV_max values which range between 15 and 70% relative to the wild-typeenzyme. The V_max values for micelles of the zwitterionic substratel,2-dioctanoyl-sn-glycero-3-phosphocholine were lowered 3–50times. The K_m values for the monomeric substrate and the k_mvalues for the micellar substrate were hardly affected in thecase of five of the six mutants, but were considerably decreasedwhen Trp was present at position 31. The results of these investigationspoint to a versatile role for the residue at position 31: involvementin the binding and orientating of monomeric substrate (analogs),involvement in the binding of the enzyme to micellar substrateanalogs and possibly involvement in shielding the active sitefrom excess water.     

Incorporation of an unnatural amino acid in the active site of porcine pancreatic phospholipase A2. Substitution of histidine by l,2,4-triazole-3-alanine yields an enzyme with high activity at acidic pH

The effect of the substitution of the active site histidine48 by the unnatural 1,2,4-triazole-3-alanine (TAA) amino acidanalogue in porcine pancreas phospholipase A₂ (PLA₂) was studied.TAA was introduced biosynthetically using a his-auxotrophicEscherichia coli strain. To study solely the effect of the substitutionof the active site histidine, two nonessential histidines (i.e.His17 and His 115) were replaced by asparagines, resulting ina fully active mutant enzyme (His-PLA₂). In this His-PLA₂ thesingle histidine at position 48 was substituted by TAA withan incorporation efficiency of about 90%, giving a mixture ofHis-PLA₂ and TAA-PLA₂. Based on the charge difference at acidicpH, both forms could be separated by FPLC, allowing for thepurification of TAA-PLA₂ free from His-PLA₂. At pH 6, TAA-PLA₂has a fivefold reduced activity compared with His-PLA₂. Thisreduced activity paralells a reduced rate of covalent modificationwith p-nitrophenacyl bromide of TAA-PLA₂ compared with His-PLA₂.Competitive inhibition gave comparable IC₅₀ values for WT-PLA₂,His-PLA₂ and TAA-PLA₂. These results indicate that the reductionin activity is not caused by a different affinity for the substrate,but more likely results from a reduced k_cat value in TAA-PLA₂.The enzymatic activities for native and mutant PLA₂s were measuredat different pH values. For WT-PLA₂ and His-PLA₂ the activityis optimal at pH 6 and is strongly deminished at acidic pH,with no observable activity at pH 3. In contrast, TAA-PLA₂ isas active at pH 3 as at pH 6. Most likely, the decrease in activityobserved for WT-PLA₂ and His-PLA₂ is caused by the protonationof the active site His48, which is the general base involvedin the activation of the nucleophilic water molecule. In TAA-PLA₂,however, the active site residue TAA48 is unprotonated at bothpH 3 and 6 as a result of the low pK_a of TAA compared with histidine.     

Function of the fully conserved residues Asp99, Tyr52 and Tyr73 in phospholipase A2

In the active centre of pancreatic phospholipase A₂ His48 isat hydrogen-bonding distance to Asp99. This Asp-His couple isassumed to act together with a water molecule as a catalytictriad. Asp99 is also linked via an extended hydrogen bondingsystem to the side chains of Tyr52 and Tyr73. To probe the functionof the fully conserved Asp99, Tyr52 and Tyr73 residues in phospholipaseA₂, the Asp99 residue was replaced by Asn, and each of the twotyrosines was separately replaced by either a Phe or a Gln.The catalytic and binding properties of the Phe52 and Phe73mutants did not change significantly relative to the wild-typeenzyme. This rules out the possibility that either one of thetwo Tyr residues in the wild-type enzyme can function as anacyl acceptor or proton donor in catalysis. The Gln73 mutantcould not be obtained in any significant amounts probably dueto incorrect folding. The Gln52 mutant was isolated in low yield.This mutant showed a large decrease in catalytic activity whileits substrate binding was nearly unchanged. The results suggesta structural role rather than a catalytic function of Tyr52and Tyr73. Substitution of asparagine for aspartate hardly affectsthe binding constants for both monomeric and micellar substrateanalogues. Kinetic characterization revealed that the Asn99mutant has retained no less than 65% of its enzymatic activityon the monomeric substrate rac 1,2-dihexanoyldithio-propyl-3-phosphocholine,probably due to the fact that during hydrolysis of monomericsubstrate by phospholipase A₂ proton transfer is not the rate-limitingstep. The Asp to Asn substitution decreases the catalytic rateon micellar 1,2-dioctanoyl-sn-glycero-3-phosphocholine 25-fold.To explain this remaining activity we suggest that in the mutantthe Asn99 orients His48 in the same way as Asp99 orients His48in native phospholipase A₂ and that the lowered activity iscaused by a reduced stabilization of the transition state.     

Adaptability of restrained molecular dynamics for tertiary structure prediction: application to Crotalus atrox venom phospholipase A2

In order to assess the adaptability and/or applicability ofthe restrained molecular dynamics (RMD) simulation for buildinga possible tertiary structure of a protein from the X-ray crystalstructure of a family reference protein, the tertiary structureprediction of Crotalus atrox venom phospholipase A₂ (PLA₂) wasattempted based on the X-ray crystal structure of bovine pancreaticPLA₂. For the formation of secondary and tertiary structuresfrom the fully extended starting structure, the RMD simulationwith interatomic distance restraints and torsion angle restraints,which were derived from homologous amino acid sequence regionsin the reference protein, was carried out until the molecularsystem was fully equilibrated. The predicted tertiary structureof C.atrox venom PLA₂ was compared with its X-ray crystal structure,and furthermore the utility of this method was discussed byreference to the similar tertiary structure prediction of ß-trypsinfrom the X-ray crystal structure of an elastase.     

Engineering cytochrome P-450cam to increase the stereospecificity and coupling of aliphatic hydroxylation

Site-directed mutants were constructed in cytochrome P-450_camto re-engineer the stereochemistry and coupling of ethylbenzenehydroxyiation. The reaction with wild-type (WT) enzyme producesone regioisomer 1-phenylethanol with 5% reduced nicotinamideadenine deoxyribonucleic acid to product conversion of and aratio of 73:27 for the R and S enantiomers respectively. Ethyibenzenewas modeled into the active site of WT P-450_cam in a rigid modeand oriented to optimize either pro-R or pro-S hydrogen abstraction.Residues T101, T185 and V247 make extensive contacts with thesubstrate in the static complexes and were therefore chosenfor site-directed mutagenesis. Single mutants T101M, V247A andV247M are more stereospedik producing 89,87 and 82% (R)-1-phenylethanolrespectively. The coupling of the reaction is doubled for thesingle mutants T185L, T185F and V247M. In an effort to engineerincreased stereospecificity and coupling into a single catalystthe T101M, T185F and V247M mutants were combined in a multiplemutant of P-450_cam.This protein hydroxylates ethyibenzene resultingin an R:S ratio of 87:13 for the 1-phenylethanols and 13% couplingof reducing equivalents to product. The catalytic stereospecificityand stoichiometry with T101M–T185F–V247M does notrepresent a summation of the changes observed for the singlemutants. A portion of the individual effects on substrate recognitionproduced by the single substitutions is either eliminated ordegenerate within the triple mutant.     

Site-directed mutagenesis and X-ray crystallography of two phospholipase A2 mutants: Y52F and Y73F

Tyr52 and Tyr73 are conserved amino acid residues throughoutall vertebrate phospholipases A₂. They are part of an extendedhydrogen bonding system that links the N-terminal -NH⁺₃ -groupto the catalytic residues His48 and Asp99. These tyrosines werereplaced by phenylalanines in a porcine pancreatic phospholipaseA₂ mutant, in which residues 62–66 had been deleted (62–66PLA₂).The mutations did not affect the catalytic properties of theenzyme, nor the folding kinetics. The stability against denaturatlonby guanidine hydrochloride was decreased, however. To analysehow the enzyme compensates for the loss of the tyrosine hydroxylgroup, the X-ray structures of the Y52F and AY73F mutants weredetermined. After crystallographic refinement the final crystallographicR-factors were 18.1% for the %Y52F mutant (data between 7 and2.3 Å resolution) and 19.1% for the Y73F mutant (databetween 7 and 2.4 Å resolution). No conformational changesoccurred in the mutants compared with the 62–66PLA₂, butan empty cavity formed at the site of the hydroxyl group ofthe former tyrosine. In both mutants the Asp99 side chain losesone of its hydrogen bonds and this might explain the observeddestabilization.     

Dimeric character of a basic phospholipase A2 from cobra venom: experimental and modelling study

When it is gel filtered on Sephadex in the absence of calciumions, basic phospholipase A₂ from Naja nigricollis venom elutesas a dimer. In order to study the possibility of this dimerizationfrom a structural point of view, three-dimensional models ofboth monomeric and dimeric N. nigricollis phospholipases A havebeen graphically built on the basis of homologies with the phospholipasesA₂ from pancreatic bovine and Crotalus atrox venom. The buildingof a duneric model is made possible by the deletion of a particularloop of the bovine structure. The predicted models of N. nigricollisphospholipase A₂ have been checked using molecular mechanicsand molecular dynamics techniques according to a suitable protocolwhich has been developed starting from refined X-ray structuresof phospholipases A₂ as the test case. The observed stabilityof the dimeric model, in the absence of calcium, agrees withthe hypothesis of the dimerization of the basic phospholipaseA Particularly, Arg31, which replaces the hydrophobic residuepresent in pancreatic bovine and C.atrox venom phospholipasesA₂, contributes to this stability.     

Catalytic role of the active site histidine of porcine pancreatic phospholipase A2 probed by the variants H48Q, H48N and H48K

The catalytic contribution of His48 in the active site of porcinepancreatic phospholipase A2 was examined using site-directedmutagenesis. Replacement of His48 by lysine (H48K) gives riseto a protein having a distorted lipid binding pocket. Activityof this variant drops below the detection limit which is 10⁷-foldlower than that of the wild-type enzyme. On the other hand,the presence of glutamine (H48Q) or asparagine (H48N) at thisposition does not affect the structural integrity of the enzymeas can be derived from the preserved lipid binding propertiesof these variants. However, the substitutions H48Q and H48Nstrongly reduce the turnover number, i.e. by a factor of 10⁵.Residual activity is totally lost after addition of a competitiveinhibitor. We conclude that proper lipid binding on its ownaccelerates ester bond hydrolysis by a factor of 10². With theselected variants, we were also able to dissect the contributionof the hydrogen bond between Asp99 and His48 on conformationalstability, being 5.2 kJ/mol. Another hydrogen bond with His48is formed when the competitive inhibitor (R)-2-dodecanoylamino-hexanol-1-phosphoglycolinteracts with the enzyme. Its contribution to binding of theinhibitor in the presence of an interface was found to be 5.7kJ/mol.     

Molecular dynamics simulations of phospholipases A2

An extensive molecular dynamics study of phospholipases A₂ frompancreatic bovine and Crotalus atrox venom has shown that thewell-conserved homologous core of the phospholipases A₂, includingthe so called catalytic network, is very stable during the courseof the calculations. The fluctuations which occur are locatedin segments which have significantly different three-dimensionalconformations in the two phospholipases A₂ studied, suggestingthat a particularly stable core conformation gives rise to alarge homologous family of similar three-dimensional structure.The calcium ion, which exhibits a crucial structural role inthe monomeric phospholipases A₂, appears not to be requiredto stabilize the C.atrox dimer. Moreover, the behaviour of thedimeric structure during the dynamics raises the question ofa possible dissociation of the two subunits into functionalmonomers.     

Identification by site-directed mutagenesis of amino acids in the subsite of bovine pancreatic ribonuclease A

In addition to hydrolysing RNA, bovine pancreatic ribonucleasesplits esters of pyrimidine nucleoside 3'-phosphates, includingdinucleotides. For a series of 3':5'-linked dinucleotides ofgeneral structure CpN, where N is a 5' linked nucleoside, k_calfor the release of N varies enormously with the precise structureof N. Structural studies have been interpreted to indicate thatthe group N interacts with a subsite, B2, on the enzyme thatcomprises Gln69, Asn71 and Glulll. We report studies by site-directedmutagenesis that indicate that Gln69 is not involved in productiveinteractions with any of the dinucleotide substrates and thatAsn71 is an important component of subsite B2 for all dinucleotidesubstrates tested. Glulll appears to be functionally involvedin catalysis for dinucleotide substrates solely when N is guanosine.     

An evolution-based analysis scheme to identify CO2/O2 specificity-determining factors for ribulose 1,5-bisphosphate carboxylase/oxygenase

Ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBisCo) catalyzes a rate-limiting step in photosynthetic carbon assimilation (reacting with CO2) and its competitive photo-respiratory carbon oxidation (reacting with O2). RuBisCo enzyme with an enhanced CO2/O2 specificity would boost the ability to make great progress in agricultural production and environmental management. RuBisCos in marine non-green algae, resulting from an earlier endo-symbiotic event, diverge greatly from those in green plants and cyanobacteria and, further, have the highest CO2/O2 specificity whereas RuBisCos in cyanobacteria have the lowest. We assumed that there exist different levels of CO2/O2 specificity-determining factors, corresponding to different evolutionary events and specificity levels. Based on this assumption, we devised a scheme to identify these substrate-determining factors. From this analysis, we are able to discover different categories of the CO2/O2 specificity-determining factors that show which residue substitutions account for (relatively) small specificity changes, as happened in green plants, or a tremendous enhancement, as observed in marine non-green algae. Therefore, the analysis can improve our understanding of molecular mechanisms in the substrate specificity development and prioritize candidate specificity-determining surface residues for site-directed mutagenesis.     

Comparison of the construction of a 3-D model for human thromboxane synthase using P450cam and BM-3 as templates: implications for the substrate binding pocket

A 3-D model of human thromboxane A₂ synthase (TXAS) was constructedusing a homology modeling approach based on information fromthe 2.0 crystal structure of the hemoprotein domains of cytochromeP450BM-3 and P450cam. P450BM-3 is a bacterial fatty acid monooxygenaseresembling eukaryotic microsomal cytochrome P450s in primarystructure and function. TXAS shares 26.4% residue identity and48.4% residue similarity with the P450BM-3 hemoprotein domain.The homology score between TXAS and P450BM-3 is much higherthan that between TXAS and P450cam. Alignment between TXAS andthe P450BM-3 hemoprotein domain or P450cam was determined throughsequence searches. The P450BM-3 or P450cam main-chain coordinateswere spplied to the TXAS main chain in those sements where thetwo sequences were well aligned. These segments were linkedto one another using a fragment search method, and the sidechains were added to produce a 3-D model for TXAS. A TXAS substrate,prostaglandin H₂ (PGH₂) was docked into the TXAS cavity correspondingto the arachidonic acid binding pocket in P450BM-3 or camphorbinding site in P450cam. Regions of the heme and putative PGH2binding cavities in the TXAS model were identified and analyzed.The segments and residues involved in the active-site pocketof the TXAS model provide reasonable candidates for TXAS proteinengineering and inhibitor design. Comparison of the TXAS modelbased on P450BM-3 with another TXAS model based on the P450BM-3with another TXAS model based on the P450cam structure indicatedthat P450BM-3 is a more suitable template for homology modelingof TXAS.     

Enhancing the stability of microsomal cytochrome b5: a rational approach informed by comparative studies with the outer mitochondrial membrane isoform

The outer mitochondrial membrane isoform of mammalian cytochrome b5 (OM b5) is much less prone to lose heme than the microsomal isoform (Mc b5), with a conserved difference at position 71 (leucine versus serine) playing a major role. We replaced Ser71 in Mc b5 with Leu, with the prediction that it would retard heme loss by diminishing polypeptide expansion accompanying rupture of the histidine to iron bonds. The strategy was partially successful in that it slowed dissociation of heme from its less stable orientation in bMc b5 (B). Heme dissociation from orientation A was accelerated to a similar extent, however, apparently owing to increased binding pocket dynamic mobility related to steric strain. A second mutation (L32I) guided by results of previous comparative studies of Mc and OM b5s diminished the steric strain, but much greater relief was achieved by replacing heme with iron deuteroporphyrin IX (FeDPIX). Indeed, the stability of the Mc(S71L) b5 FeDPIX complex is similar to that of the FeDPIX complex of OM b5. The results suggest that maximizing heme binding pocket compactness in the apo state is a useful general strategy for increasing the stability of engineered or designed proteins.     

Protein engineering of diphtheria-toxin-related interleukin-2 fusion toxins to increase cytotoxic potency for high-affinity IL-2-receptor-bearing target cells

We have used site-directed insertion and point mutagenesis inan attempt to increase the cytotoxic potency and receptor-bindingaffinity of the diphtheria-toxin-related interleukin-2 (IL-2)fusion toxins. Previous studies have demonstrated that boththe DAB₄₈₆-IL-Z and DAB₃₈₉-IL-2 forms of the fusion toxin consistof three functional domains: the N-tenninal fragment-A-assodatedADP-ribosyltransferase, the hydrophobk-membrane-associatingdomains, and the C-terminal receptor-binding domain of humanIL-2. By insertion mutagenesis we have increased the apparentflexibility of the polypeptide chain between the membraneassociatingdomains and the receptor-binding domain of this fusion toxin.In comparison to DAB₄₈₆-IL-2, the cytotoxic potency of the insertionmutants was increased by 17-fold for high-affinity IL-2-receptor-bearingcell lines in vitro. Moreover, competitive displacement experimentsusing [¹²⁵I]rIL-2 demonstrate that the increase in cytotoxicpotency correlates with an increase in receptor-binding affinityfor both the high and intermediate forms of the IL-2 receptor.     

Influenza virus M2 protein: a molecular modelling study of the ion channel

The influenza A M₂ protein forms cation-selective ion channelswhich are blocked by the anti-influenza drug amantadine. A molecularmodel of the M₂ channel is presented in which a bundle of fourparallel M₂ transbilayer helices surrounds a central ion-permeablepore. Analysis of helix amphipathicity was used to aid determinationof the orientation of the helices about their long axes. Thehelices are tilted such that the N-terminal mouth of the poreis wider than the C-terminal mouth. The channel is lined byresidues V27, S31 and I42. Residues D24 and D44 are locatedat opposite mouths of the pore, which is narrowest in the vicinityof I42. Energy profiles for interaction of the channel withNa⁺, amantadine-H⁺ and cyclopentylamine-H⁺ are evaluated. Theinteraction profile for Na⁺ exhibits three minima, one at eachmouth of the pore, and one in the region of residue S31. Theamantadine-H⁺ profile exhibits a minimum close to S31 and abarrier near residue I42. This provides a molecular model foramantadine-H⁺ block of M₂ channels. The profile for cyclopentylamine-H⁺does not exhibit such a barrier. It is predicted that cyclopentyl-amine-H⁺will not act as an M₂ channel blocker.     

Probing the substrate specificity of the intracellular brain platelet-activating factor acetylhydrolase

Platelet-activating factor acetylhydrolases (PAF-AHs) are uniquePLA2s which hydrolyze the sn-2 ester linkage in PAF-like phospholipidswith a marked preference for very short acyl chains, typicallyacetyl. The recent solution of the crystal structure of the₁ catalytic subunit of isoform Ib of bovine brain intracellularPAF-AH at 1.7 Å resolution paved the way for a detailedexamination of the molecular basis of substrate specificityin this enzyme. The crystal structure suggests that the sidechains of Thr103, Leu48 and Leu194 are involved in substraterecognition. Three single site mutants (L48A, T103S and L194A)were overexpressed and their structures were solved to 2.3 Åresolution or better by X-ray diffraction methods. Enzyme kineticsshowed that, compared with wild-type protein, all three mutantshave higher relative activity against phospholipids with sn-2acyl chains longer than an acetyl. However, for each of themutants we observed an unexpected and substantial reductionin the V_max of the reaction. These results are consistent withthe model in which residues Leu48, Thr103 and Leu194 indeedcontribute to substrate specificity and in addition suggestthat the integrity of the specificity pocket is critical forthe expression of full catalytic function, thus conferring veryhigh substrate selectivity on the enzyme.     

Characterization of the apparent negative co-operativity induced in Escherichia coli aspartate aminotransferase by the replacement of Asp222 with alanine. Evidence for an extremely slow conformational change

The strictly conserved active site residue, Asp222, which formsa hydrogen-bonded salt bridge with the pyridine nitrogen atomof the pyridoxal 5' phosphate (PLP) co-factor of aspartate aminotransferase(AATase), was replaced with alanine (D222A) in the Escherichiacoli enzyme. The D222A mutant exhibits non–hyberbolicsaturation behavior with amino acid substrates which appearas apparent negative eooperativity in steady–state kineticanalyses. Single turnover progress curves for D222A are welldescribed by the sum of two exponentials, contrasting with themonophasic kinetics of the wild-type enzyme. An active/inactiveheterodimer containing the D222A mutation retains this biphasickinetic response, proving that the observed eooperativity isnot the result of induced allostery. The anomalous behavioris explained by a hysteretic kinetic model involving two slowlyinterconverting enzyme forms, only one of which is catalyticallycompetent. The slow functional transition between the two formshas a half–life of 10 mins. Preincubation of the mutantwith the dicarboxylk inhibitor maleate shifts the equilibriumpopulation of the enzyme towards the catalytically active form,suggesting that the slow transition is related to the domainclosure known to occur upon association of this inhibitor withthe wild-type enzyme. The importance of Asp222 in the chemicalsteps of transamination is confirmed by the l0⁵fold decreasein catalytic competence in the D222A mutant, and by the largeprimary C–deuterium kinetic isotope effect (6.7 versus2.2 for the wild–type). The transamination activity ofthe D222A mutant is enhanced 4– to 20–fold by reconstltutionwith the co-factor analog N–methylpyridoxal–5–phosphate(N–MePLP), and the C–proton abstraction step isless rate determining, as evidenced by the decrease in the primarykinetic isotope effect from 6.7 to 2.3. These results suggestthat the conserved interaction between the protonated pyridinenitrogen of PLP and the negatively charged carboxylate of Asp222is important not only for efficient C–proton abstraction,but also for conformational transitions concomitant with thetransamination process     

Study of cysteine residues in the {alpha} subunit of Escherichia coli tryptophan synthase. 2. Role in enzymatic function

To understand the functional roles of Cys residues in the subunitof tryptophan synthase from Escherichia coli, single mutantsof the subunit, in which each of the three Cys residues wassubstituted with Ser, Gly, Ala or Val, were constructed by site-directedmutagenesis. The effects of the substitutions on the functionof tryptophan synthase were investigated by activity measurements,calorimetric measurements of association with the ßsubunit and steadystate kinetic analysis of catalysis. Althoughthe three Cys residues are located away from the apparentlyimportant parts for enzymatic activity, substitutions at position81 by Ser, Ala or Val caused decreases in the intrinsic activityof the subunit. Furthermore, Cys81Ser and Cys81Val reducedstimulation activities in the and ß reactions dueto formation of a complex with the ß subunit. Thelower stimulation activities of the mutant proteins were notcorrelated with their abilities to associate with the ßsubunit but were correlated with decreases in k_cat. The presentresults suggest that position 81 plays an indirectly importantrole in the activity of the subunit itself and the mutual activationmechanism of the complex.     

Redesign of the coenzyme specificity in L-Lactate dehydrogenase from Bacillus stearothermophilus using site-directed mutagenesis and media engineering

L-Lactate dehydrogenase (LDH) from Bacillus stearothermophilusis a redox enzyme which has a strong preference for NADH overNADPH as coenzyme. To exclude NADPH from the coenzyme-bindingpocket, LDH contains a conserved aspartate residue at position52. However, this residue is probably not solely responsiblefor the NADH specificity. In this report we examine the possibilitiesof altering the coenzyme specificity of LDH by introducing arange of different point mutations in the coenzyme-binding domain.Furthermore, after choosing the mutant with the highest selectivityfor NADPH, we also investigated the possibility of further alteringthe coenzyme specificity by adding an organic solvent to thereaction mixture. The LDH mutant, I51K:D52S, exhibited a 56-foldincreased specificity to NADPH over the wild-type LDH in a reactionmixture containing 15% methanol. Furthermore, the NADPH turnovernumber of this mutant was increased almost fourfold as comparedwith wild-type LDH. To explain the altered coenzyme specificityexhibited by the D52SI51K double mutant, molecular dynamicssimulations were performed.     

A proposal for the catalytic mechanism in phospholipase C based on interaction energy and distance geometry calculations

The non-specific phospholipase C from Bacillus cereus preferentiallyhydrolyses phosphatidylcholine but is also active against phosphatidylserine,phosphatidylethanolaniine and at a much lower level, sphingomyelin.A minimal substrate model containing all required structuraland configurational elements of a high affinity substrate wasdocked into the active site. The enzyme–substrate attachmentpoints were from molecular interaction energy calculations usingthe program GRID and from a previous phosphate inhibitor complexstructure. Available conformational space for the substratewas sampled by distance geometry calculations using the programDGEOM. This investigation clearly identifies the attacking nucleophile,a catalytically favourable orientation of the phosphate groupin its tetra-, as well as its penta-, coordinated state anda crucial stabilizing environment for the alkoxide intermediate.Based on this information a complete catalytic cycle is proposed.