Development of fructosyl amine oxidase specific to fructosyl valine by site-directed mutagenesis

Docking models of fructosyl amine oxidase (FAOD) from the marineyeast Pichia N1-1 (N1-1 FAOD) with the substrates fructosylvaline (f-Val) and fructosyl-N-lysine (f-Lys) were producedusing three-dimensional protein model as reported previously(Miura et al., 2006, Biotechnol. Lett., 28, 1895-1900). Theresidues involved in recognition of substrates were proposed,particularly Asn354, which interacts closely with f-Lys, butnot with f-Val. Substitution of Asn354 to histidine and lysinesimultaneously resulted in an increase in activity of f-valand a decrease in activity of f-Lys and thus, increasing thespecificity for f-Val from 13- to 19-fold. In addition to creatingtwo mutant FAODs with great potential for the measurement ofglycated hemoglobin, we have provided the first structural modelof substrate binding with eukaryotic FAOD, which is expectedto contribute to further investigation of FAOD.     

Interactions of (Ala*Ala*Lys*Pro)n and (Lys*Lys*Ser*Pro)n with DNA. Proposed coiled-coil structure of AlgR3 and AlgP from Pseudomonas aeruginosa

The proteins, AlgR3 and AlgP, are involved in the regulationof alginate synthesis in Pseudomonas. They contain multiplerepeats of Ala^*Ala^*Lys^*Pro as do several other proteins thatresemble histones. The interactions of synthesis oligopeptidescomposed of repeated Ala^*Ala^*Lys^*Pro or Lys^*Lys^*Ser^*Pro unitswith DNA were studied by fluorescence of the Fmoc (9-fluorenylmethyloxycarbonyl)group attached to the N-termini of the peptides. DNA quenchingof the Fmoc fluorescence of the peptides was used to estimatethe apparent association constants for the interaction of Fmoc(AAKP)_nOH(n = 2, 4, 8, 18, 32) and of Fmoc(KKSP)_nOH (n = 2, 4, 8, 16,20, 32) with DNA. The Fmoc(AAKP)_nOH peptides bind to DNA onlyat low ionic strength; the Fmoc(KKSP)_n OH peptides interactwith DNA at both low (0.05 M KCl) and high (0.2 M KCl) saltAt low ionic strength an increase in the number of the repeatunits causes an increase in the apparent association constantup to {small tilde}2 x 10⁶ M^–1 for both types of peptidesat N 24. The insertion of an AAKTA unit into the middle ofthe Fmoc(AAKP)₈OH peptide increases its affinity to DNA. Wepropose a model of (AAKP)_n and of its interaction with DNA.The repeat unit consists of a single turn of -helix followedby a bend necessitated by Pro. The resultant coiled-coil formsa right-handed superhelix with 10 AAKPs per repeat distanceof {small tilde}33 Å. With only slight modification ofthe canonical parameters of this model the AAKP super helixfits into the major groove of B-form DNA with one AAKP tetramerper base pair repeat of 3.4 Å. The -amine nitrogen ofLys can form a polar hydrogen bond with a phosphate oxygen atomof the DNA backbone. A better fit is obtained when the modelis modified to accommodate [(AAKP)₅AAKTA]_n as actually observedin AlgR3. We suggest that this coiled-coil represents a generalmotif for other protein–DNA interactions.     

Free energy perturbation study on a Trp-binding mutant (Ser88 ->Cys) of the trp-repressor

The Ser⁸⁸Cys mutant of the trp-repressor showed a lower affinityfor the corepressor than the wild-type repressor [G = 1.7 ±0.3 kcal/mol, Chou and Matthews (1989) J. Biol. Chem., 264,18314–18319].A molecular dynamics/free energy cycle perturbation study wasperformed to understand the origin of the decreased affinity.A value (G = 1.58 ± 0.28 kcal/mol) comparable with theexperimental value was obtained by the simulation. Free energycomponent analysis revealed that destabilization of the vander Waals interaction between Ser⁸⁸ and Trp¹⁰⁹ (corepressor)mainly contributed to the decreased affinity of the mutant.The rotational transition of the hydroxyl (sulfhydryl) groupof Ser⁸⁸ (Cys⁸⁸) during the simulations affected the contributionsof Arg⁸⁴ and water to the free energy change in the aporepressorand those of Arg⁸⁴ and Trp ¹⁰⁹ to that in the holorepressor.However, the contributions from different residues compensatedeach other, and the total free energy changes were almost invariablein the various simulations.     

Engineering of human lysozyme as a polyelectrolyte by the alteration of molecular surface charge

The surface positive charges of human lysozyme were either increasedor decreased to alter the electrostatic interaction betweenenzyme and substrate in the lytic action of human lysozyme usingsite-directed mutagenesis. The amino acid substitutions accompanyingeither the addition or the removal of two units of positivecharge have shifted the optimal ionic strength (NaCl concentrationin 10 mM Mes buffer, pH 6.2) for the lysis of Micrococcus lysodeikticuscell from 0.04 M to 0.1 M and from 0.04 M to 0.02 M respectively.In addition to the change in ionic strength–activity profile,the pH–activity profile and the effect of a polycationicelectrolyte, poly-L-Lys-HCl, on the lytic activity were significantlychanged. Owing to the shifts in both ionic strength profilesand pH profiles the Arg⁷⁴/Arg¹²⁶ mutant has become a bettercatalyst than wild-type enzyme under the conditions of highionic strength and high pH, and the Gln⁴¹/Ser¹⁰¹ mutant hasbecome a better catalyst under the conditions of low ionic strengthand low pH.     

Altered specificities of genetically engineered {alpha}1 antitrypsin variants

Seven active site variants of human ₁-antitrypsin (₁AT) wereproduced in Escherichia coli following site-specific mutagenesisof the ₁AT complementary DNA. ₁AT (Ala ³⁵⁸), ₁AT (Ile³⁵⁸ and₁AT (Val³⁵⁸), were efficient inhibitors of both neutrophil andpancreatic elastases, but not of cathepsin G. ₁AT (Ala³⁵⁸, Val³⁵⁸)and ₁AT (Phe³⁵⁸ specifically inhibited pancreatic elastase andcathepsin G respectively. The most potent inhibitor of neutrophilelastase was ₁AT (Leu³⁵⁸), which also proved to be effectiveagainst cathepsin G. The ₁AT (Arg³⁵⁸) variant inactivated thrombinwith kinetics similar to antithrombin III in the presence ofheparin. Electrophoretic analysis showed that SDS-stable highmol. wt complexes were formed between the mutant inhibitorsand the cognate proteases in each case. These data indicatethat effective inhibition occurs when the ₁AT P1 residue (position358) corresponds to the primary specificity of the target protease.Moreover, alteration of the P3 residue (position 356) can furthermodify the reactivity of the inhibitor. Two of the variantshave therapeutic potential: ₁AT (Leu³⁵⁸ may be more useful thanplasma ₁AT in the treatment of destructive lung disorders and₁ (Arg³⁵⁸ could be effective in the control of thrombosis.     

Over-production of 5-enolpyruvylshikimate-3-phosphate synthase in Escherichia coli: use of the T7 promoter

5-Enolpyruvylshikimate-3-phosphate (EPSP) synthase, the productof the Escherichia coli aroA gene, has been overproduced inE.coli BL21(DE3) under the control of the T7 gene 10 promoterand ribosome binding site, to a level of {small tilde}50% oftotal cell protein. EPSP synthase is the primary target of thepost-emergence herbicide, glyphosate, commonly known as Roundup^TM.A simple two step purification is described, which results in99% pure homogeneous protein (as determined by PAGE). The integrityof the protein has been compared with previously characterizedprotein from .E.coli AB2829(pKD501) by determination of itskinetic parameters, N-terminal protein and DNA sequences, aminoacid analysis and ¹³C-NMR spectroscopy. This new overproducingstrain readily provides the gram quantities of highly pure proteinrequired for NMR studies of the active site and the developmentof novel time-resolved solid-state NMR techniques currentlyunderway in this laboratory.     

Secretion of recombinant human IgE-Fc by mammalian cells and biological activity of glycosylation site mutants

We have constructed an expression vector that leads to secretionof the whole Fc of human immunoglobulin E (hIgE-Fc) from mammaliancells at levels up to 100 mg/l of culture. Two surface glycosylationsites at Asn265 and Asn371 have been changed to glutamine, toobtain a more homogeneous preparation of hIgE-Fc for structuralstudies. Comparison of wild-type and mutant products revealedthat Asn371 is rarely glycosylated in Chinese hamster ovarycells. Both the double mutant and wild-type hIgEFc bind to thehigh-affinity IgE receptor, FcRI, with about the same affinityas myeloma IgE (K_a in the range 10¹⁰–10¹¹ M^–1),and were able to sensitize isolated human basophils for anti-IgEtriggering of histamine release. However, only the double mutanthIgE-Fc approached the affinity of myeloma IgE for the low-affinityreceptor, FcRII (K_a = 7.3x10⁷ M^–1), whereas the wild-type hIgE-Fc bound with a 10-fold lower affinity (K_a = 4.1x10⁶M^–1).     

Effects of amino acid replacements around the reactive site of chicken ovomucoid domain 3 on the inhibitory activity toward chymotrypsin and trypsin

We have previously shown that replacing the P1-site residue(Ala) of chicken ovomucoid domain 3 (OMCHI3) with a Met or Lysresults in the acquisition of inhibitory activity toward chymotrypsinor trypsin, respectively. However, the inhibitory activitiesthus induced are not strong. In the present study, we introducedadditional amino acid replacements around the reactive siteto try to make the P1-site mutants more effective inhibitorsof chymotrypsin or trypsin. The amino acid replacement AspTyrat the P2' site of OMCHI3(P1Met) resulted in conversion to a35000-fold more effective inhibitor of chymotrypsin with aninhibitor constant (K_i) of 1.17x10^–11 M. The K_i valueof OMCHI3(P1Met, P2'Ala) indicated that the effect on the interactionwith chymotrypsin of removing a negative charge from the P2'site was greater than that of introducing an aromatic ring.Similarly, enhanced inhibition of trypsin was observed whenthe AspTyr replacement was introduced into the P2' site of OMCHI3(P1Lys).Two additional replacements, AspAla at the P4 site and ArgAlaat the P3' site, made the mutant a more effective inhibitorof trypsin with a K_i value of 1.44x10^–9 M. By contrast,ArgAla replacement at the P3' site of OMCHI3(P1Met, P2'Tyr)resulted in a greatly reduced inhibition of chymotrypsin, andAspAla replacement at the P4 site produced only a small changewhen compared with a natural variant of OMCHI3. These resultsclearly indicate that not only the P1-site residue but alsothe characteristics, particularly the electrostatic properties,of the amino acid residues around the reactive site of the proteaseinhibitor determine the strength of its interactions with proteases.Furthermore, amino acids with different characteristics arerequired around the reactive site for strong inhibition of chymotrypsinand trypsin.     

Alteration of the amino acid substrate specificity of clostridial glutamate dehydrogenase by site-directed mutagenesis of an active-site lysine residue

Two residues, K89 and S380, thought to interact with the -carboxylgroup of the substrate L-glutamate, have been altered by site-directedmutagenesis of clostridial glutamate dehydrogenase (GDH). Thesingle mutants K89L and S380V and the combined double mutantK89L/S380V were constructed. All three mutants were satisfactorilyoverproduced in soluble form. However, only the K89L mutantwas retained by the dye column normally used in purifying thewild-type enzyme. All three mutant enzymes were purified tohomogeneity and tested for substrate specificity with 24 aminoacids. The single mutant S380V showed no detectable activity.The alternative single mutant K89L showed an activity towardsL-glutamate that was decreased nearly 2000-fold compared withwild-type enzyme, whereas the activities towards the monocarboxylicsubstrates -aminobutyrate and norvaline were increased 2- to3-fold. A similar level of activity was obtained with methionine(0.005 U/mg) and norleucine (0.012 U/mg), neither of which giveany activity with the wild-type enzyme under the same conditions.The double mutant showed decreased activity with all substratescompared with the wild-type GDH. In view of its novel activities,the K89L mutant was investigated in greater detail. A strictlylinear relationship between reaction velocity and substrateconcentration was observed up to 80 mM L-methionine and 200mM L-norleucine, implying very high K_m values. Values of k_cat/K_m,for L-methionine and L-norleucine were 6.7x10^–2 and 0.15s^–1M^–1, respectively. Measurements with dithiobisnitrobenzoicacid showed that the mutant enzymes all reacted with a stoichiometryof one -SH group per subunit and all showed protection by coenzyme,indicating essentially unimpaired coenzyme binding. With glutamateor 2-oxoglutarate as substrate the K_m values for the vestigialactivity in the mutant enzyme preparations were strikingly closeto the wild-type K_m values. Both for wild-type GDH and K89L,L-glutamate gave competitive product inhibition of 2-oxoglutaratereduction but did not inhibit the reduction of 2-oxocaproatecatalysed by K89L enzyme. This suggests that the low levelsof glutamate/2-oxoglutarate activity shown by the mutant enzymeare due to trace contamination. Since stringent precautionswere taken, it appears possible that this reflects the levelof reading error during overexpression of the mutant proteins.CD measurements indicate that the S380V mutant has an alteredconformation, whereas the K89L enzyme gave an identical CD spectrumto that of wild-type GDH; the spectrum of the double mutantwas similar, although somewhat altered in intensity. The resultsconfirm the key role of K89 in dicarboxylate recognition byGDH.     

Point mutation of alanine (31) to valine prohibits the folding of reduced lysozyme by sulfhydryl--disulfide interchange

In the preceding paper in this issue, we described the overproduction of one mutant chicken lysozyme in Escherichia coil.Since this lysozyme contained two amino acid substitutions (Ala³¹ValandAsn¹⁰⁶Ser)in addition to an extra methionine residue at theNH₂-terminus the substituted amino acid residues were convertedback to the original ones by means of oligonucleotide-directedsite-specific mutagenesis and in vitro recombination. Thus fourkinds of chicken lysozyme [Met^–1 Val³¹Ser¹⁰⁶-, Met^–1Ser¹⁰⁶-,Met^–1 Val³¹-and Met^–1 (wild type)] wereexpressed in E. coli. From the results of folding experimentsof the reduced lysozymes by sulfhydryl-disulfide interchangeat pH 8.0 and 38°C, follow ed by the specific activity measurementsof the folded en zymes, the following conclusions can be drawn:(i) an extra methionine residue at the NH₂-terminus reducesthe folding rate but does not affect the lysozyme activity ofthe folded enzyme; (ii) the substitution of Asn¹⁰⁶ by Ser decreasesthe activity to 58% of that of intact native lysozyme withoutchanging the folding rate; and (iii) the substitution of Ala³¹Val prohibits the correct folding of lysozyme. Since the wildtype enzyme (Met^–1-lysozyme) was activated in vitro withoutloss of specific activity, the systems described in this study(mutagenesis, overproduction, purification and folding of inactivemutant lysozymes) may be useful in the study of folding pathways,expression of biological activity and stability of lysozyme.     

Recombinant-derived interleukin-1{alpha} stabilized against specific deamidation

Recombinant-derived human interleukln-1 (IL-1), purified fromEscherichia coli, was resolved by isoelectric focusing on polyacrylamidegels into two species of isoelectric points (pI) 5.45 and 5.20,which constituted 75% and 25% of the total IL-1 protein respectively.The pI 5.45 and pI 5.20 species were separated by chromatofocusingand subjected to N-terminal sequence analysis. The pI 5.45 speciescontained the expected Asn residue at position 36 of the matureprotein sequence whereas the pI 5.20 species contained an Aspresidue at the same position. A mutant protein in which Asn-36was substituted for a Ser residue was isolated from E.coli andshown to be homogeneous on isoelectric focusing analysis witha pI = 5.45. ¹H-n.m.r. and circular dichroism analyses of wild-typeand the mutant IL-1 indicated a similar conformation which wasalso indicated by the identical receptor binding affinitiesof IL-1 with Asn, Asp or Ser in position 36. The mutant proteinwas stabilized against specific base catalysed and temperature-induceddeamidation, and may be more suitable than the wild-type positionfor physical and structural studies.     

Highly controlled carbodiimide reaction for the modification of lysozyme. Modification of Leu129 or Asp119

In the cross-linking reaction of lysozyme between Leu¹²⁹ (-COO^–)and Lys¹³ (-NH₃⁺ using imidazole and 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimidehydrochloride (EDC), a side reaction of the peptide bond inversionfrom to ß between A and Gly¹⁰² was greatly reducedby addition of ß-(1,4)-linked trimer of N-acetyl-D-glucosamine[(NAG)₃] When methylamine or 2-hydroxyethylamine was furtheradded, the extent of the cross-link formation was decreasedand the derivative where the -carboxyl group of Leu¹²⁹ was modifiedwith the amine was newly obtained. On the other hand, when ammoniawas added, the ß-carboxyl group of Asp¹¹⁹ insteadof the -carboxyl group was mainly amidated. From these results,the presence of a salt bridge between Asp¹¹⁹ and Arg¹²⁵ besidesthat between Lys¹³ and Leu¹²⁹ is proposed. Enzymatic activitiesof the derivatives prepared here indicated that the modificationof the -carboxyl group reduced the activity to {small tilde}90% of that of native lysozyme. Des-Leu¹²⁹ lysozyme, which lacksLeu¹²⁹ also showed {small tilde} 90% of the activity of nativelysozyme. Therefore, the salt bridge between Lys¹³ and Leu¹²⁹may play some role in maintaining the active conformation oflysozyine.     

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     

The de novo protein with grafted biological function: transferring of interferon blast-transforming activity to albebetin

The de novo protein albebetin has been designed recently toform a predetermined tertiary fold that has not yet been observedin natural proteins. An eight amino acid fragment (131–138)of human interferon ₂ carrying the blasttransforming activityof the protein was attached to the N-terminus of albebetin nextto its initiatory methionine residue. The gene of chimeric proteinwas expressed in a wheat germ cell-free translation system andsynthesized protein was tested for its compactness and stability.Its ability for receptor binding was also studied. We have shownthat albebetin with attached octapeptide is practically as compactas natural proteins of corresponding molecular weight and possesseshigh stability toward the urea-induced unfolding. It binds murinethymocyte receptor at a high affinity and activates the thymocyteblast transformation efficiently at a concentration of 10^-11M.     

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.     

Effects of substitution of Thr63 by alanine on the structure and function of Lactobacillus casei dihydrofolate reductase

A mutant of Lactobacillus casei dihydrofolate reductase hasbeen constructed in which Thr63, a residue which interacts withthe 2'-phosphate group of the bound coenzyme, is replaced byalanine. This substitution does not affect k_cat, but producesan 800-fold increase in the K_m for NADPH, which reflects dissociationof NADPH from the enzyme-NADPH-tetrahydrofolate complex, anda 625-fold increase (corresponding to 3.8 kcal/mol) in the dissociationconstant for the enzyme-NADPH complex. The difference in magnitudeof these effects indicates a small effect of the substitutionon the negative cooperativity between NADPH and tetrahydrofolate.Stopped-flow studies of the kinetics of NADPH binding show thatthe weaker binding arises predominantly from a decrease in theassociation rate constant. NMR spectroscopy was used to comparethe structures of the mutant and wild-type enzymes in solution,in their complexes with methotrexate and with methotrexate andNADPH. This showed that only minimal structural changes resultfrom the mutation; a total of 47 residues were monitored fromtheir resolved ¹H resonances, and of these nine in the binarycomplex and six in the ternary differed in chemical shift betweenmutant and wild-type enzyme. These affected residues are confinedto the immediate vicinity of residue 63. There is a substantialdifference in the ³¹P chemical shift of the 2'-phosphate ofthe bound coenzyme, reflecting the loss of the interaction withthe side chain of Thr63. The only changes in nuclear Overhausereffects (NOEs) observed were decreases in the intensity of NOEsbetween protons of the adenine ring of the bound coenzyme andthe nearby residues Leu62 and Ile102, showing that the substitutionof Thr63 does cause a change in the position or orientationof the adenine ring in its binding site.     

Expression and characterization of apolipoprotein(a) kringle IV types 1, 2 and 10 in mammalian cells

We have designed expression constructs containing sequencescorresponding to apolipoprotein(a) kringle FV types 1, 2 and10 and used these constructs to transfect human embryonic kidneycells. We have also expressed a mutant form of kringle FV type2 in which the N-linked glycosylation site has been removedby replacement of an asparagine residue with an alanine. Immunoprecipitationanalysis of [³⁵S]Cys-labeled transfected cell culture supernatantsresulted in the observation of two bands for kringle IV type1 (M_r 30 000 and 26 000), two bands for kringle IV type 2 (M_r25 000 and 22 000), two bands for kringle IV type 10 (M_r 27000 and 23 000) and one band for the glycosylation mutant (M_r22 000). In all cases, observed molecular weights greatly exceededthose predicted from amino acid sequence, suggesting the presenceof both N- and O-linked glycans. None of the recombinant singlekringles were observed to bind to fibrinogen as determined byELISA or by co-immunoprecipitation in the case of kringle IVtype 10 and only kringle IV type 10 was able to bind to lysine-Sepharose.These data suggest that apo(a) binding to fibrinogen/fibrinmay require motif(s) in addition to apo(a) kringle IV type 10.     

The net energetic contribution of interhelical electrostatic attractions to coiled-coil stability

The net energetic contribution of interhelical electrostaticattractions to coiled-coil stability has been quantitated usingde novo designed synthetic coiled-coils. The synthesized modelcoiled-coil (EK), denoted by amino acid res-idues in positionse and g, which contains only interhelical ionic interactionswithout any possible (i, i + 3) and (i, i + 4) intrahelicalionic interaction, consists of two identical 35 residue polypeptidechains with a heptad repeat KgLaG-bAcLdEeKf. Three mutant coiled-coilswere prepared where five Glu residues at e positions in EK weremutated to Gin residues (QK); five Lys residues at g positionswere altered to Gin residues (EQ) or these mutations were effectedat both positions e and g (QQ). The stabilities of the fourcoiled-coils were determined by measuring the ellipticitiesat 220 nm as a function of urea concentration at 20C. By usinga double-mutant cycle analysis it was possible to isolate theenergetic contribution of interhelical ionic attractions tocoiled-coil stability from the other contributions such as helicalpreference and hydro-phobicity. The 0.37 0.01 kcal/mol ofenergetic contribution of one interhelical ion pair to the coiled-coilstability was obtained from three independent comparisons. Thisfinding suggests that a large number of weak interhelical electrostaticinteractions on the surface of a protein can make a substantialcontribution to protein stability. In addition, the energeticcontributions of a single mutation E^– Q, K⁺Q, Q E andE^– Ewere also determined (G = 0.22, 0.26, 0.46 and 0.65kcal/mol for the single mutations, respectively). The greatercontribution of a protonated Glu residue to coiled-coil stabilitycompared with an ionized Glu residue (0.65 kcal/mol) can outweighthe relatively smaller contribution of an interhelical ion pair(0.37 kcal/mol), which clearly explains why most coiled-coilsare more stable at acidic pH compared with neutral pH even wheninterhelical salt bridges contribute to the coiled-coil stabilityat neutral pH.     

Calcium binding mode of {gamma}-carboxyglutamic acids in conantokins

Conantokin-T (con-T) and conantokin-G (con-G) are two highlyhomologous peptide toxins found in Conus venom. The former isa 21-residue peptide with four -carboxyglutamic acid (Gla) residues(at positions 3, 4, 10 and 14), while the latter is a 17-residuepeptide with five -carboxyglutamic acid residues (at positions3, 4, 7, 10 and 14). Despite the apparent similarity in numberand relative positions of the -carboxyglutamic acid residues,¹¹³Cd-NMR studies indicated a distinct metal binding behaviorfor con-G and con-T. There appears to be four binding sitesin con-G in contrast to one metal binding site in con-T. Toelucidate the mode of calcium binding by the -carboxyglutamicacid residues in these conantokins, we designed various analogouspeptides with their -carboxyglutamic acid replaced by otheramino acid residues. ¹¹³Cd-NMR experiments on conantokin analoguesreveal that the major difference in the number of metal bindingsites between con-G and con-T is due to the residue at position7. We also performed molecular simulations to calculate therelative binding free energies of several potential bindingsites. Based on our theoretical and experimental results, wepropose a `four-site' binding model for conantokin-G and a `single-site'binding model for conantokin-T.     

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.