Homogenization and crystallization of histidine ammonia-lyase by exchange of a surface cysteine residue

Histidase (histidine ammonia-lyase, EC 4.3.1.3) from Pseudomonasputida was expressed in Escherichia coli and purified. In theabsence of thiols the tetrameric enzyme gave rise to undefinedaggregates and suitable crystals could not be obtained. Thesolvent accessibility along the chain was predicted from theamino acid sequence. Among the seven cysteines, only one waslabeled as `solvent-exposed'. The exchange of this cysteineto alanine abolished all undefined aggregations and yieldedreadily crystals diffracting to 1.8 Å resolution.     

Structural and mutagenesis studies of leishmania triosephosphate isomerase: a point mutation can convert a mesophilic enzyme into a superstable enzyme without losing catalytic power

The dimeric enzyme triosephosphate isomerase (TIM) has a verytight and rigid dimer interface. At this interface a criticalhydrogen bond is formed between the main chain oxygen atom ofthe catalytic residue Lys13 and the completely buried side chainof Gln65 (of the same subunit). The sequence of Leishmania mexicanaTIM, closely related to Trypanosoma brucei TIM (68% sequenceidentity), shows that this highly conserved glutamine has beenreplaced by a glutamate. Therefore, the 1.8 Å crystalstructure of leishmania TIM (at pH 5.9) was determined. Thecomparison with the structure of trypanosomal TIM shows no rearrangementsin the vicinity of Glu65, suggesting that its side chain isprotonated and is hydrogen bonded to the main chain oxygen ofLys13. Ionization of this glutamic acid side chain causes apH-dependent decrease in the thermal stability of leishmaniaTIM. The presence of this glutamate, also in its protonatedstate, disrupts to some extent the conserved hydrogen bond network,as seen in all other TIMs. Restoration of the hydrogen bondingnetwork by its mutation to glutamine in the E65Q variant ofleishmania TIM results in much higher stability; for example,at pH 7, the apparent melting temperature increases by 26°C(57°C for leishmania TIM to 83°C for the E65Q variant).This mutation does not affect the kinetic properties, showingthat even point mutations can convert a mesophilic enzyme intoa superstable enzyme without losing catalytic power at the mesophilictemperature.     

Histidine-15: an important role in the cytotoxic activity of human tumor necrosis factor

The amino acids that are required for the cytotoxic activityof recombinant human tumor necrosis factor- (TNF) were investigatedby chemical modification and oligonucleotide-directed site-specificmutagenesis. TNF contains three histidine residues, locatedat positions 15, 73 and 78. The histidine-specific reagent diethylpyrocarbonate(DEP) was used to chemically modify TNF. The chemical inactivationof the in vitro cytotoxic activity of this lymphokine (usingmurine L929 target cells) was found to be time- and dose-dependent.Inactivated TNF failed to compete with fully bioactive [¹²⁵I]TNFfor human MCF-7 target cell receptors. Mutant polypeptides ofTNF were genetically engineered by oligonucoleotide-directedsite-specific mutagenesis. The cytotoxicity of a double histidinemutant, in which histidine-73 and histidine-78 were replacedwith glutamine, was not altered and was chemically inactivatedby DEP. Substituting glutamine for histidine-15 resulted in10–15% of the wild-type bioactivity. Replacing histidine-15with either asparagine, lysine or glycine resulted in a biologicallyinactive molecule. The data show that the histidine residueat position 15 is an amino acid that is required for the cytotoxicactivity of TNF.     

The sequence and X-ray structure of the trypsin from Fusarium oxysporum

The trypsin from Fusarium oxysporum is equally homologous totrypsins from Streptomyces griseus, Streptomyces erythraeusand to bovine trypsin. A DFP (diisopropylfluorophosphate) inhibitedform of the enzyme has been crystallized from 1.4 M Na₂SO₄,buffered with citrate at pH 5.0–5.5. The crystals belongto space group P2₁ with cell parameters a=33.43 Å, b=67.65Å, c=39.85 Å and ß=107.6°. There isone protein molecule in the asymmetric unit. X-ray diffractiondata to a resolution of 1.8 Å were collected on film usingsynchrotron radiation. The structure was solved by molecularreplacement using models of bovine and S.griseus trypsins andrefined to an R-factor of 0.141. The overall fold is similarto other trypsins, with some insertions and deletions. Thereis no evidence of the divalent cation binding sites seen inother trypsins. The covalently bound inhibitor molecule is clearlyvisible.     

Solution conformation of a synthetic bis-headed inhibitor of trypsin and carboxypeptidase A: new structural alignment between the squash inhibitors and the potato carboxypeptidase inhibitor

The trypsin carboxypeptidase peptide inhibitor (TCPI) whichinhibits both trypsin and carboxypeptidase A has been chemicallyengineered by modification of the Ecballium elaterium trypsininhibitor II (EETI-II). The solution conformation of TCPI, studiedby two-dimensional nuclear magnetic resonance, was shown tobe very close to those of squash inhibitors. Only limited deviationsof the trypsin binding loop compared to its location in theEETI-II/trypsin complex were detected. It was also shown thatthe position of the C-terminal tail did not significantly changefrom the position observed in the complex between carboxypeptidaseA and the potato carboxypeptidase inhibitor (PCI). The conformationof TCPI was carefully compared with the PCI one and a new structuralalignment between the two microproteins is proposed. This alignmentpoints out the very good conservation in the two inhibitorsof a subdomain comprising segments 7–15, 19–22 and25–28. Most importantly, the 2–19 disulfide bridgeof TCPI was not structurally conserved in PCI and appeared tobe rather unimportant for the early folding process of thesemolecules. This result agrees with the recent observation thatthe 2–19 bridge is the last to be formed in the foldingof the squash inhibitor EETI-II and suggests that this is alsothe case during the folding of the potato carboxypeptidase inhibitor.     

Geometry of interaction of metal ions with histidine residues in protein structures

An analysis of the geometry and the orientation of metal ionsbound to histidine residues in proteins is presented. Cationsare found to lie in the imidazole plane along the lone pairon the nitrogen atom. Out of the two tautomeric forms of theimidazole ring, the NE2-protonated form is normally preferred.However, when bound to a metal ion the ND1-protonated form ispredominant and NE2 is the ligand atom. When the metal coordinationis through ND1, steric interactions shift the side chain torsionalangle, X₂ from its preferred value of 90 or 270. The orientationof histidine residues is usually stabilized through hydrogenbonding; ND1-protonated form of a helical residue can form ahydrogen bond with the carbonyl oxygen atom in the precedingturn of the helix. A considerable number of ligands are foundin helices and ß-sheets. A helical residue hound toa heme group is usually found near the C-terminus of the helix.Two ligand groups four residues apart in a helix, or two residuesapart in a ß-strand are used in many proteins to bindmetal ions.     

Disulfide stabilization of antibody Fv: computer predictions and experimental evaluation

Using molecular modeling technology we have recently identifiedpositions in conserved framework regions of Fvs which can beused to stabilize antibody Fvs by an interchain disulfide bondengineered in between the structurally conserved framework positionsof the variable domains of heavy (V_H) and light (V_L) immunoglobulinchains (disulfide-stabilized Fv; dsFv). The computer model indicatedthe existence of other potential sites in the framework regionsthat might be suitable for disulfide bond formation betweenV_H and V_L. The possibility of obtaining dsFvs using these positionsis evaluated here experimentally by constructing dsFv immunotoxinsin which the Fv moiety is fused to a truncated form of Pseudomonasexotoxin. We analyzed the extent of dsFv formation and the activityof the resulting dsFv immunotoxins, and compared various dsFvmolecules with the scFv immunotoxin. Our results demonstratethat position H44-L105 is the only one which gives high productionyields of active dsFv. All other positions gave either low yieldsand activity or completely failed to produce active dsFv. Withone exception, the formation and activities of the dsFvs correspondedto the C-C distance between the VH and VL positions, with anoptimal distance of 5.7 Å producing the best dsFv. Distancesof 6.0–6.9 Å resulted in a' low yield of proteinthat was still capable of binding antigen, whereas distances>7.0 Å resulted in molecules in which dsFv formationwas not obtained.     

Multiple interactions of lysine-128 of Escherichia coli glutamate dehydrogenase revealed by site-directed mutagenesis studies

A highly conserved lysine at position 128 of Escherichia coliglutamate dehydrogenase (GDH) has been altered by sitedirectedmutagenesis of the gdhA gene. Chemical modification studieshave previously shown the importance of this residue for catalyticactivity. We report the properties of mutants in which lysine-128has been changed to histidine (K128H) or arginine (K128R). Bothmutants have substantially reduced catalytic centre activitiesand raised pH optima for activity. K128H also has increasedrelative activity with amino acid substrates other than glutamate,especially L-norvaline. These differences, together with alterationsin K_m values, K_d values for NADPH and K₁ values for D-glutamate,imply that lysine-128 is intimately involved in either director indirect interactions with all the substrates and also incatalysis. These multiple interactions of lysine-128 explainthe diverse effects of chemical modifications of the correspondinglysine in homologous GDHs. In contrast, lysine-27, another highlyreactive residue in bovine GDH, is not conserved in all of thesequenced NADP-specific GDHs and is therefore not likely tobe involved in catalysis.     

Removal of an inter-domain hydrogen bond through site-directed mutagenesis: role of serine 176 in the mechanism of papain

A mutant of papain, where an inter-domain hydrogen bond betweenthe side chain hydroxyl group of a serine residue at position176 and the side chain carbonyl oxygen of a glutamine residueat position 19 has been removed by site-directed mutagenesis,has been produced and characterized kinetically. The mutationof Ser176 to an alanine has only a small effect on the kineticparameters, the k_cat/K_m for hydrolysis of CBZ-Phe-Arg-MCA bythe Serl76Ala enzyme being of 8.1 x 10⁴ /M/s compared with 1.2x 10⁵ /M/s for papain. Serine 176 is therefore not essentialfor the catalytic functioning of papain, even though this residueis conserved in all cysteine proteases sequenced. The pH-activityprofiles were shown to be narrower in the mutant enzyme by upto 1 pH unit at high ionic strength. This result is interpretedto indicate that replacing Ser 176 by an alanine destabilizesthe thiolate—imidazolium form of the catalytic site Cys25-Hisl59residues of papain. Possible explanations for that effect aregiven and the role of a serine residue at position 176 in papainis discussed.     

Comparison of dielectric response models for simulating electrostatic effects in proteins

Two recent approaches for calculating pK shifts in proteinsare compared. The first of these uses Coulomb's law with a distance-dependentdielectric permittivity, e(r), to model the screening effectsof the environment, and the second uses a finite differenceapproach to solve Poisson's equation. It is shown that an explicitform of e(r) which has been fitted to experimentally determinedvalues of the dielectric permittivity in a range from 1 to 21Å can be approximated by a linear form in the functionallysignificant range of chargeseparations of {small tilde}3–10Å, but for distances >10 Å the effective permittivityis strongly nonlinear. A statistical analysis of the errorsin calculated pK shifts due to electrostatic interactions betweencharges with separations > 10 Å shows that there areonly marginal differences in reliability between using Coulomb'slaw with an appropriate form of e(r) or the finite differenceapproach for solving Poisson's equation. Thus it is concludedthat pK shifts can be calculated just as well, and with considerablyless effort, using Coulomb's law.     

Synthesis of a squash-type protease inhibitor by gene engineering and effects of replacements of conserved hydrophobic amino acid residues on its inhibitory activity

Cucurbita maxima trypsin inhibitor I (CMTI-I), a member of thesquash-type protease inhibitor family, is composed of 29 aminoacids and shows strong inhibition of trypsin by its compactstructure. To study the structure–function relationshipof this inhibitor using protein engineering methods, we constructedan expression system for CMTI-I as a fused protein with porcineadenylate kinase (ADK). A Met residue was introduced into thejunction of ADK and CMTI-I to cleave the fusion protein withCNBr, whereas a Met at position 8 of authentic CMTI-I was replacedby Leu. Escherichia coli JM109 transformed with the constructedplasmid expressed the fused protein as an inclusion body. Aftercleavage of the expressed protein with CNBr, fully reduced speciesof CMTI-I were purified by reversed-phase HPLC and then oxidizedwith air by shaking. For efficient refolding of CMTI-I, we used50 mM NH₄HCO₃ (pH 7.8) containing 0.1% PEG 6000 at higher proteinconcentration. Strong inhibitory activity toward trypsin wasdetected only in the first of three HPLC peaks. The inhibitorconstant of CMTI-I thus obtained, in which Met8 was replacedby Leu, was 1.4x10-¹⁰ M. The effect of replacement of Met withLeu at position 8 was shown to be small by comparison of theinhibitor constant of authentic CMTI-III bearing Lys at position9 (8.9x10-¹¹ M) with that of its mutant bearing Leu at position8 and Lys at position 9 (1.8x10-¹⁰ M). To investigate the roleof the well conserved hydrophobic residues of CMTI-I in itsinteraction with trypsin, CMTI-I mutants in which one or allof the four hydrophobic residues were replaced by Ala were prepared.The inhibitor constants of these mutants indicated that thosewith single replacements were 5–40 times less effectiveas trypsin inhibitors and that the quadruple mutant was –450times less effective, suggesting that the hydrophobic residuesin CMTI-I contribute to its tight binding with trypsin. However,each mutant was not converted to a temporary inhibitor.     

Determination of three-dimensional structures of proteins by simulated annealing with interproton distance restraints. Application to crambin, potato carboxypeptidase inhibitor and barley serine proteinase inhibitor 2

An automated method, based on the principle of simulated annealing,is presented for determining the three-dimensional structuresof proteins on the basis of short (<5 Å) interprotondistance data derived from nuclear Overhauser enhancement (NOE)measurements. The method makes use of Newton's equations ofmotion to increase temporarily the temperature of the systemin order to search for the global minimum region of a targetfunction comprising purely geometric restraints. These consistof interproton distances supplemented by bond lengths, bondangles, planes and soft van der Waals repulsion terms. The latterreplace the dihedral, van der Waals, electrostatic and hydrogen-bondingpotentials of the empirical energy function used in moleculardynamics simulations. The method presented involves the implementationof a number of innovations over our previous restrained moleculardynamics approach [Clore,G.M., Brünger,A.T., Karplus,M.and Gronenborn,A.M. (1986) J. Mol. Biol., 191, 523–551].These include the development of a new effective potential forthe interproton distance restraints whose functional form isdependent on the magnitude of the difference between calculatedand target values, and the design and implementation of robustand fully automatic protocol. The method is tested on threesystems: the model system crambin (46 residues) using X-raystructure derived interproton distance restraints, and potatocarboxypeptidase inhibitor (CPI; 39 residues) and barley serineproteinase inhibitor 2 (BSPI-2; 64 residues) using experimentallyderived interproton distance restraints. Calculations were carriedout starting from the extended strands which had atomic r.m.s.differences of 57, 38 and 33 Å with respect to the crystalstructures of BSPI-2, crambin and CPI respectively. Unbiasedsampling of the conformational space consistent with the restraintswas achieved by varying the random number seed used to assignthe initial velocities. This ensures that the different trajectoriesdiverge during the early stages of the simulations and onlyconverge later as more and more interproton distance restraintsare satisfied. The average backbone atomic r.m.s. differencebetween the converged structures is 2.2 ± 0.3 Åfor crambin (nine structures), 2.4 ± 0.3 Å forCPI (eight structures) and 2.5 ± 0.2 Å for BSPI-2(five structures). The backbone atomic r.m.s. difference betweenthe mean structures derived by averaging the coordinates ofthe converged structures and the corresponding X-ray structuresis 1.2 Å for crambin, 1.6 Å for CPI and 1.7 Åfor BSPI-2.     

3-D structure of the D153G mutant of Escherichia coli alkaline phosphatase: an enzyme with weaker magnesium binding and increased catalytic activity

The substitution of aspartate at position 153 in Escherichiacoli alkaline phosphatase by glycine results in a mutant enzymewith 5-fold higher catalytic activity (k_cat but no change inKm at pH 8.0 in 50 mM Tris-HCl. The increased k_cat is achievedby a faster release of the phosphate product as a result ofthe lower phosphate affinity. The mutation also affects Mg²⁺binding, resulting in an enzyme with lower metal affinity. The3-D X-ray structure of the D153G mutant has been refined at2.5 Å to a crystallographic Rfactor of 16.2%. An analysisof this structure has revealed that the decreased phosphateaffinity is caused by an apparent increase in flexibility ofthe guanidinium side chain of Argl66 involved in phosphate binding.The mutation of Aspl53 to Gly also affects the position of thewater ligands of Mg²⁺, and the loop Glnl52–Thrl55 is shiftedby 0.3 Å away from the active site. The weaker Mg²⁺ bindingof the mutant compared with the wild type is caused by an alteredcoordination sphere in the proximity of the Mg²⁺ ion, and alsoby the loss of an electrostatic interaction (Mg²⁺.COO^-Aspl53)in the mutant Its ligands W454 and W455 and hydroxyl of Thrl55,involved in the octahedral coordination of the Mg²⁺ ion, arefurther apart in the mutant compared with the wild-type     

Crystallization and structure solution at 4 A resolution of the recombinant synthase domain of N(5'-phosphoribosyl)anthranilate isomerase:indole-3-glycerol-phosphate synthase from Escherichia coli complexed to a substrate analogue

The recombinant synthase domain of the bifunctional enzyme N-(5'-phosphoribosyl)anthranilateisomerase:indole-3-glycerol-phosphate synthase from Escherichiacoli has been crystallized, and the structure has been solvedat 4 Å resolution. Two closely related crystal forms grownfrom ammonium sulphate diffract to 2 Å resolution. Oneform (space group R32, a = 163 Å, = 29.5°) containsthe unliganded synthase domain; the second crystal form (spacegroup P6₃22, a = 144 Å, c = 158 Å) is co-crystallizedwith the substrate analogue N-(5'-phosphoribit-1-yl)anthranilate.The structure of the synthase–inhibitor complex has beensolved by the molecular replacement method. This achievementrepresents the first successful use of a (ß)_g-barrelmonomer as a trial model. The recombinant synthase domain associatesas a trimer in the crystal, the molecules being related by apseudo-crystallographic triad. The interface contacts betweenthe three domains are mediated by those residues that are alsoinvolved in the domain interface of the bifunctional enzyme.This system provides a model for an interface which is usedin both intermolecular and intramolecular domain contacts.     

Modular mutagenesis of a TEM-barrel enzyme: the crystal structure of a chimeric E.coli TIM having the eighth {beta}{alpha}-unit replaced by the equivalent unit of chicken TIM

Abstract The crystal structure of a hybrid Escherichia coli triosephosphateisomerase (TIM) has been determined at 2.8 Å resolution.The hybrid TIM (ETIM8CHI) was constructed by replacing the eighthß-unit of E.coli TIM with the equivalent unit of chickenTIM. This replacement involves 10 sequence changes. One of thechanges concerns the mutation of a buried alanine (Ala232 instrand 8) into a phenylalanine. The ETIM8CHI structure showsthat the A232F sequence change can be incorporated by a side-chainrotation of Phe224 (in helix 7). No cavities or strained dihedralsare observed in ETIM8CHI in the region near position 232, whichis in agreement with the observation that ETIM8CHI and E.coliTIM have similar stabilities. The largest CA (C-alpha atom)movements, 3 Å, are seen for the C-terminal end of helix8 (associated with the outward rotation of Phe224) and for theresidues in the loop after helix 1 (associated with sequencechanges in helix 8). From the structure it is not clear whythe k_cat of ETIM8CHI is 10 times lower than in wild type E.coliTIM     

Testing the procedure of simulated annealing by refining homologous immunoglobulin light-chain dimers

The refinement of antigen-binding fragment structures by themethod of simulated annealing was tested. Using the programX-PLOR, we refined the structure of one immunoglobulin light-chaindimer against 2.8 Å diffraction data collected for a homologouslight-chain dimer. The refinement proceeded smoothly; -carbonsof the conserved segments of the domain moved to the positionsin the reference structure solved independently. An averagemovement of –1.5 Å for atoms in the variable domains(half of the molecule) was observed. Though the final R-factorsand energy terms of the reference and test structures were verysimilar, some of the chain segments of the hypervariable loops(HVR3s₃) and the ends of some side chains did not converge tothe positions in the reference structure. Therefore, althoughglobally the refinement worked very well, positions of the loopsand the side chains that are critical for immunoglobulin functionhave to be carefully examined by difference Fourier techniques.     

1.85 A structure of anti-fluorescein 4-4-20 Fab

The crystal complex of fluorescein bound to the high-affinityanti-fluorescein 4-4-20 Fab {K_a = 10¹⁰ M^–1 at 2°C)has been determined at 1.85 Å. Isomorphous crystals oftwo isoelectric forms (p1 = 7.5 and 7.9) of the antifluorescein4-4-20 Fab, an IgG2A [Gibson et al (1988)Proteins: Struct. FunctGenet., 3, 155–160], have been grown. Both complexes crystallizewith one molecule in the asymmetric unit in space group P1,with a = 42.75 Å, b =43.87 Å, c = 58.17 Å, = 95.15° , ß = 86.85° and = 98.01°.The final structure has an R value of 0.188 at 1.85 Åresolution. Interactions between bound fluorescein, the complementarity-determiningregions (CDRs) of the Fab and the active-site mutants of the4-4-20 single-chain Fv will be discussed. Differences were foundbetween the structure reported here and the previously reported2.7 Å 4-4-20 Fab structure [Herron et al. (1989) Proteins:Struct. Fund., 5, 271–280]. Our structure determinationwas based on 26 328 unique reflections — four times theamount of data used in the previous report. Differences in thetwo structures could be explained by differences in interpretingthe electron density maps at the various resolutions. The r.m.s.deviations between the variable and constant domains of thetwo structures were 0.77 and 1.54 Å, respectively. Fourregions of the light chain and four regions of the heavy chainhad r.m.s. backbone deviations of >4 Å. The most significantof these was the conformation of the light chain CDR 1.     

Comparison of backbone structures of glucose isomerase from Streptomyces and Arthrobacter

The C backbones of the glucose isomerase molecules of Streptomycesrubiginosus and Arthrobacter have been determined by X-ray crystallographyand compared. Each molecule is a tetramer of eight-stranded/ß barrels, and the mode of association of the tetramersis identical in each case. The Arthrobacter electron densityshows four additional amino acids at the carboxyl terminus.There is also an insertion of six amino acids at position 277,and two individual insertions at about positions 348 and 357(numbering according to the Streptomyces structure). There isa close structural homology throughout the whole molecule, whichis most accurate up to position 325. The r.m.s. displacementfor 315 homologous C positions up to this position is 0.92 Å.     

The 2 A crystal structure of subtilisin E with PMSF inhibitor

Using enzyme prepared by the DNA recombination technique, subtilisinE from Bacillus subtilis was crystallizedin space group P2₁2₁2₁with two molecules in an asymmetric unit. The crystal structureof PMSF-inhibited subtilisin E was solved by molecular replacementfollowed by refinement with the X-PLOR program. This resultedin the 2.0 Å structure of subtilisin E with an R-factorof 0.191 for 8–2 Å data and r.m.s. deviations fromideal values of 0.021 Å and 2.294° for bond lengthsand bond angles respectively. The PMSF group covalently boundto Ser221 appeared very clearly in the electron density map.Except for the active site disturbed by PMSF binding, the structuralfeatures of subtilisin E are almost the same as in other subtilisins.The calcium-binding sites are different in detail in the twoindependent molecules of subtilisin E. Based on the structure,the remarkably enhanced heat stability of mutant N118S of subtilisinE is discussed. It is very likely that there is an additionalwater molecule in the mutant structure, which is hydrogen bondedto side chains of Serll8 and its neighbouring residues Lys27and Asp 120.     

Deletion analysis of the starch-binding domain of Aspergillus glucoamylase

The large form of glucoamylase (GAI) from Aspergillus awamori(EC 3.2.1.3 [EC] ) binds strongly to native granular starch, whereasa truncated form (GAII) which lacks 103 C-terminal residues,does not. This C-terminal region, conserved among fungal glucoamylasesand other starch-degrading enzymes, is part of an independentstarch-binding domain (SBD). To investigate the SBD boundariesand the function of conserved residues in two putative substrate-bindingsites, five gluco-amylase mutants were constructed with extensivedeletions in this region for expression in Saccharomyces cerevisiae.Progressive loss of both starch-binding and starch-hydrolyticactivity occurred upon removal of eight and 25 C-terminal aminoacid residues, or 21 and 52 residues close to the N-terminus,confirming the requirement for the entire region in formationof a functional SBD. C-terminal deletions strongly impairedSBD function, suggesting a more important role for one of theputative binding sites. A GAII phenocopy showed a nearly completeloss of starch-binding and starch-hydrolytic activity. The deletionsdid not affect enzyme activity on soluble starch or thermo-stabilityof the enzyme, confirming the independence of the catalyticdomain from the SBD.