Introduction of a stabilizing 10 residue {beta}-hairpin in Bacillus subtilis neutral protease

A 10 residue ß-hairpin, which is characteristic ofthermostable Bacillus neutral proteases, was engineered intothe thermolabile neutral protease of Bacillus subtilis. Therecipient enzyme remained fully active after introduction ofthe loop. However, the mutant protein exhibited autocatalyticnicking and a 0.4°C decrease in thermostability. Two additionalpoint mutations designed to improve the interactions betweenthe enzyme surface and the introduced ß-hairpin resultedin reduced nicking and increased thermostability. After theintroduction of both additional mutations in the loopcontainingmutant, nicking was largely prevented and an increase in thermostabilityof 1.1°C was achieved.     

The effect of cavity-filling mutations on the thermostability of Bacillus stearothermophilus neutral protease

Cavities in the hydrophobic core of the neutral protease ofBacillus stearothermophilus were analyzed using a threedimensionalmodel that was inferred from the crystal structure of thermolysin,the highly homologous neutral protease of B.thermoproteolyticus(85% sequence identity). Site–directed mutagenesis wasused to fill some of these cavities, thereby improving hydrophobicpacking in the protein interior. The mutations had small effectson the thermostability, even after drastic changes, such asLeu284Trp and Met168Trp. The effects on T50, the temperatureat which 50% of the enzyme is irreversibly inactivated in 30min, ranged from 0.0 to +0.4°C. These results can be explainedby assuming that the mutations have positive and negative structuraleffects of approximately the same magnitude. Alternatively,it could be envisaged that the local unfolding steps, whichrender the enzyme susceptible towards autolysis and which arerate limiting in the process of thermal inactivation, are onlyslightly affected by alterations in the hydrophobic core.     

Effect of Glu-143 and His-231 substitutions on the catalytic activity and secretion of Bacillus subtilis neutral protease

On the basis of the homology with the Bacillus thermoproteolyticuszinc endopeptidase thermotysin, we hypothesized that Glu-143and His-231 are the key residues for the catalytic activityof the Bacillus subtilis neutral protease. To test this possibilityby site-directed mutagenesis, we substituted these two residueswith Ala, Ser, Trp and Arg, and Leu, Val and Cys respectively.All these substitutions dramatically affected the amount ofsecreted mutant proteins, as determined by immunological methods,and their catalytic activities. No appreciable secretion wasobserved with the three Glu mutants Trp, Ser and Arg, whereasthe Glu–Ala mutant enzyme was secreted at a level of afew hundred micrograms per litre of culture. The His mutantswere all secreted at higher levels (in the order of a few milligramsper litre) and their residual catalytic activity could be determinedusing Z-Ala-Leu-Ala as substrate. Our results confirm the keyrole played by Glu-143 and His-231 in catalysis and moreoversuggest the existence of a relationship between the catalyticactivity of the enzyme and the extent of its secretion. In thiscontext, we present data suggesting an autoproteolytic mechanismof cleavage of the precursor form of the enzyme, analogous tothe one previously reported for the B.subtilis subtilisin.     

Introduction of disulfide bonds into Bacillus subtilis neutral protease

The effects of engineered disulfide bonds on autodigestion andthermostability of Bacillus subtilis neutral protease (NP-sub)were studied using site-directed mutagenesis. After modellingstudies two locations that might be capable of forming disulfidebonds, both near previously determined autodigestion sites inNP-sub, were selected for the introduction of cysteines. Analysisof mutant enzymes showed that disulfide bonds were indeed formedin vivo, and that the mutant enzymes were fully active. Theintroduced disulfides did not alter the autodigestion patternof the NP-sub. All mutant NP-subs exhibited decreased thermostability,which, by using reducing agents, was shown to be caused by theintroduction of the cysteines and not by the formation of thedisulfides. Mutants containing one cysteine exhibited intermoleculardisulfide formation at elevated temperatures, which, however,was shown not to be the cause of the decreased thermostability.Combining the present data with literature data, it would seemthat the introduction of disulfide bridges is unsuitable forthe stabilization of proteases. Possible explanations for thisphenomenon are discussed.     

A single amino acid substitution can restore the solubility of aggregated colicin A mutants in Escherichia coli

Mutants of colicin A have been prepared in which the three tryptophanresidues (Trp86, Trpl30 and Trpl40), localized in the C-terminaldomain of the soluble wild-type protein, have been substitutedby phenylalanine. The Trpl40Phe single mutation had the effectof decreasing the percentage of protein that is expressed asinsoluble aggregates. The created hydrophobic cavity decreasedthe stability of the protein during its folding, resulting inpartial aggregation in the cytoplasm of the Escherichia coli-producingcells. Aggregation was increased when Trpl40 was substitutedby Lys, Leu or Cys, or if the Trpl40 mutation was combined withthe Trp86Phe and/ or Trpl30Phe mutations. A single mutation,Lysll3Phe, however, was able to restore the solubility of theaggregated mutants in vivo. Detailed analysis of the 3-D structureof the C-terminal domain of colicin A suggests that fillingof the hydrophobic cavity is responsible for this effect.     

Stabilization of the neutral protease of Bacillus stearothermophilus by removal of a buried water molecule

Using site-directed mutagenesis, Ala166 in the neutral proteaseof Bacillus stearothermophilus was changed into Ser. Model buildingand molecular dynamics simulations of the mutant enzyme indicatedthat the Ser hydroxyl group fits well in a cavity which containsa water molecule in the wild-type enzyme. The Alal66 - Ser mutationwas expected to exert a stabilizing effect because of the gainin entropy resulting from the release of a water molecule fromthe folded protein to the solvent. In addition, the hydrogen-bondingnetwork around residue 166 was improved upon the mutation. Asa result of this mutation the thermostability of the neutralprotease was increased by 1.2 ± 0.1°C.     

Functional roles and subsite locations of Leu177, Trp178 and Asn182 of Aspergillus awamori glucoamylase determined by site-directed mutagenesis

Fungal glucoamylases contain four conserved regions. One regionfrom the Aspergillus niger enzyme contains three key carboxylicacid residues, the general acid catalytic group, Glu179, alongwith Asp176 and Glu180. Three site-directed mutations, Leu177– His, Trp178 – Arg and Asn182 – Ala, wereconstructed near these acidic groups to reveal the functionof other conserved residues in this region. Leu177 and Trp178are strictly conserved among fungal glucoamylases, while anamide, predominantly Asn, always occurs at position 182. Substitutionsof Leu177 or Trp178 cause significant decreases in k_cat withthe substrates tested. Similar increases in activation energiesobtained with Leu177 – His with both -(1,4)- and -(1,6)-linkedsubstrates indicate Leu177 is located in subsite 1. K_M valuesobtained with the Trp178 – Arg mutation increase for an-(1,6)-linked substrate, but not for -(1,4)-linked substrates.Calculated differences in activation energy between substratesindicate Trp178 interacts specifically with subsite 2. The Asn182 Ala mutation did not change k_cat or K_M values, indicating thatAsn182 is not crucial for activity. These results support amechanism for glucoamylase catalytic activity consisting ofa fast substrate binding step followed by a conformational changeat subsite 1 to stabilize the transition state complex.     

Cumulative stabilizing effects of glycine to alanine substitutions in Bacillus subtilis neutral protease

Oligonucleotide-directed mutagenesis has been used to replaceglycine residues by alanine in neutral protease from Bacillussubtilis. One Gly to Ala substitution (G147A) was located ina helical region of the protein, while the other (G189A) wasin a loop. The effects of mutational substitutions on the functional,conformational and stability properties of the enzyme have beeninvestigated using enzymatic assays and spectroscopic measurements.Single substitutions of both G1y147 and Gly189 with Ala residuesaffect the enzyme kinetic properties using synthetic peptidesas substrates. When Gly replacements were concurrently introducedat both positions, the kinetic characteristics of the doublemutant were roughly intermediate between those of the two singlemutants, and similar to those of the wild-type protease. Bothmutants G147A and G189A were found to be more stable towardsirreversible thermal inactivation/unfolding than the wild-typespecies. Moreover, the stabilizing effect of the Gly to Alasubstitution was roughly additive in the double mutant G147A/G189A,which shows a 3.2°C increase in T_m with respect to the wild-typeprotein. These findings indicate that the Gly to Ala substitutioncan be used as a strategy to stabilize globular proteins. Thepossible mechanisms of protein stabilization are also discussed.     

Phe496 and Leu497 are essential for receptor binding and cytotoxic action of the murine interleukin-4 receptor targeted fusion toxin DAB389-mIL-4

DAB₃₈₉-mIL-4 is a murine interleukin-4 (mIL-4) diphtheria toxin-relatedfusion protein which has been shown to be selectively toxicto cells expressing the mIL-4 receptor. In this report, we haveused site-directed and in-frame deletion mutagenesis to studythe role of the putative C-terminal -helix (helix E) of themIL-4 component of DAB₃₈₉-mIL-4 in the intoxication process.We demonstrate that deletion of the C-terminal 15 amino acidsof the fusion toxin leads to loss of cytotoxicity. The substitutionof Phe496 with either Pro, Ala or Tyr, results in a > 20-folddecrease in cytotoxic activity of the respective mutant fusiontoxins. In addition, substitution of Leu497 with either Alaor Glu results in a similar loss of cytotoxic activity. Allof these mutant forms of the mIL-4 fusion toxin demonstratea significant decrease in binding affinity (K_i) to the mIL-4receptor in a competitive radioligand binding assay. In markedcontrast, however, the substitution of Asp495 with Asn resultsin a 4-fold increase in cytotoxic potency and binding affinityto mIL-4 receptor bearing cells in vitro.     

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.     

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.     

Crystal structure of the high-alkaline serine protease PB92 from Bacillus alcalophilus

The crystal structure of a serine protease from the alkalophilicstrain Bacillus alcalophilus PB92 has been determined by X-raydiffraction at 1.75 Â resolution. The structure has beensolved by molecular replacement using the atomic model of subtilisinCarlsberg. The model of the PB92 protease has been refined toan R-factor of 14.0% and contains 1882 protein atoms, two calciumions and 188 water molecules. The overall folding of the polypeptide chain closely resembles that of the subtilisins. Furthermore,almost all of the secondary structure elements found in subtilisinCarlsberg are also present in the PB92 protease. The major differencesbetween the two structures are located around the deletion regions(residues 37 and 158–161 in subtilisin Carlsberg) andin two loops which are known to be the most variable parts ofsubtilisin structures. Flexibility of one of these loops (residues126–130 in the PB92 protease) is believed to account forthe inducedfit mechanism of substrate binding.     

Increasing the thermostability of a neutral protease by replacing positively charged amino acids in the N-terminal turn of {alpha}-helices

The 247–260 and 289–299 -helices of Bacillus subtilisneutral protease have a lysine in their N-terminal turn. Theselysines were replaced by Ser or Asp in order to improve electrostaticinteractions with the -helix dipole. After replacing Lys bySer at positions 249 or 290, the thermostability of the enzymewas increased by 0.3 and 1.0°C, respectively. The Asp249and Asp290 mutants exhibited a stabilization of 0.6 and 1.2°C,respectively. The results show the feasibility of stabilizingenzymes by introducing favourable residues at the end of -helices.     

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.     

Bipartite organization of the Bacillus subtilis endo-{beta}-1,4-glucanase revealed by C-terminal mutations

The C-terminal boundary of primary sequence of the Bacillussubtilis PAP115 endo-ß-1,4-glucanase (EG) requiredfor stable catalytic activity has been mapped by site-directedmutagenesis using Escherichia coli as host. The 52 kDa cel geneproduct, EG₄₇₀ and a 33 kDa mutant (EG₃₀₀), lacking 170 residuesthrough a nonsense mutation at the leucine-330 codon of thegene, exhibited similar patterns of enzymatic activity and pHoptima using cellooligopentaose as substrate.CD spectra indicatedthat the bulk of the -helical secondary structure in EG₄₇₀ wascontained within EG₃₀₀. However, relative to EG₄₇₀, the specificactivity of EG₃₀₀ was 3- to 4-fold lower with amorphous celluloseas substrate and {small tilde}4-to5-fold higher with carboxymethylcellulose(soluble cellulose).These results along with data which showthat EG₄₇₀ binding capacity to mirocrystalline cellulose is{small tilde} 11 times more than that of EG₃₀₀, demonstratethe importance of residues 330–499 for non-catalytic bindingof cellulose. A construct of the cel gene carrying a deletionof codons 330–499 and an insertion of a nonsense codonat leucine-330, was further used to make mutants EG₂₉₆ and EG₂₉₁with nonsense codon substitutions at arginine and serine-321,respectively.Western analysis using EG-specific antiserum revealedthat relative losses in enzymatic activity of EG₂₉₆ (50%) andEG₂₉₁ (95%) could be accounted for by the extent of their proteolysis,signifying a marked destabilization of these enzymes by removalof only a few amino acids.     

Effect of Lys->Arg mutation on the thermal stability of Cu,Zn superoxide dismutase: influence on the monomer-dimer equilibrium

The thermal stability of two single (K3R, K67R) and one double(K3R-K67R) mutants of Xenopus laevis B Cu,Zn superoxide dismutasehas been studied to test LysArg substitution as an ‘electrostaticallyconservative’ strategy to increase protein stability.The K3R mutant displays an increased thermostability with respectto the wild-type enzyme, whilst a decreased stability was observedin the case of the K67R and K3R-K67R mutants. Concentrationdependence of the apparent inactivation constant (k_app) of thelatter mutants, as compared to that of the wild type enzymeand K3R mutant, indicates that their higher sensitivity to heatinactivation is due to a perturbation of the dimer association.These results are confirmed also by fluorescence anisotropymeasurements of the internal probe Tyr149. The possible roleof Arg67 in perturbing the dimer dissociation equilibrium towardthe monomeric form is discussed.     

Site-directed mutagenesis at the active site Trpl20 of Aspergillus awamori glucoamylase

Trpl20 of Aspergillus awamori glucoamylase has previously beenshown by chemical modification to be essential for activityand tentatively to be located near subsite 4 of the active site.To further test its role, restriction sites were inserted inthe cloned A.awamori gene around the Trpl20 coding region, andcassette mutagenesis was used to replace it with His, Leu, Pheand Tyr. All four mutants displayed 2% or less of the maximalactivity (k_cat) of wild-type glucoamylase towards maltose andmaltoheptaose. MichaelLs constants (K_M) of mutants decreased2- to 3-fold for maltose and were essentially unchanged formaltoheptaose compared with the wild type, except for a >3-fold decrease for maltoheptaose with the Trp120 – Tyrmutant. This mutant also bound isomaltose more strongly andhad more selectivity for its hydrolysis than wild-type glucoamylase.A subsite map generated from malto-oligosaecharide substrateshaving 2 – 7 D-glucosyl residues indicated that subsites1 and 2 had greater affinity for D-glucosyl residues in theTrp120 – Tyr mutant than in wild-type glucoamylase. Theseresults suggest that Trpl20 from a distant subsite is crucialfor the stabilization of the transition-state complex in subsites1 and 2.     

Replacing the glutamate ligand in the structural zinc site of Sulfolobus solfataricus alcohol dehydrogenase with a cysteine decreases thermostability

The alcohol dehydrogenase gene from the thermophilic archaeumSulfolobus solfataricus has been subcloned and expressed inEscherichia coli under the control of the T7 inducible promoter.Therecombinant protein shows properties analogous to those of thenative enzyme, including thermostability, despite the fact thatE.coli does not post-translationally modify two lysine residueswhich are N--methylated in the native enzyme. We constructeda 3-D model of the S.solfataricus alcohol dehydrogenase usingthe known structure of its isozyme from horse liver as a template.Our analysis of the structural zinc binding site suggested thatthis site is present andfunctional in the S.solfataricus enzymeand that a glutamate ligand can contribute to thermostabilityby influencing electrostatic interactions around the metal centre.To investigate thishypothesis, we constructed, expressed andcharacterized a mutant where the glutamate is replaced by acysteine, thus restoring the zinc binding site of mesophilicalcohol dehydrogenases. Themutant shows the same activity buta reduced thermostability with respect to the wild-type recombinantprotein, as suggested by our model.     

Thermostabilization of the Bacillus circulansxylanase by the introduction of disulfide bonds

The thermostability of the 20 396 Da Bacillus circulans xylanasewas increased by the introduction of both intra and intermoleculardisulfide bridges by site-directed muta-genesis. Based on the3-D structure of the enzyme, sites were chosen where favourablegeometry for a bridge existed; in one case, to obtain favourablegeometry additional mutations around the cysteine sites weredesigned by computer modelling. The disulfide bonds introducedinto the xylanase were mostly buried and, in the absence ofprotein denaturants, relatively insensitive to reduction bydithiothreitol. The mutant proteins were examined for residualenzymatic activity after various thermal treatments, and wereassayed for enzymatic activity at elevated temperatures to assesstheir productivity. Wes have examined one of these mutants byX-ray crystallography. All of the disulfide bond designs testedincreased the thermostability of the B.circulans xylanase, butnot all enhanced the activity of the enzyme at elevated temperatures.     

Expression of synthetic genes coding for completely new, nutritionally rich, artificial proteins

Synthetic genes (A, AB and AHB) constructed and cloned intopKK233-2 vector were recloned from the parent plasmid into thenew procaryotic expression vectors pGFY221N and pBIO52. GeneAF^–B (coding for all amino acids besides phenylalanine)was obtained by ‘cassette mutagenesis’ from geneAB. The plasmid pGFY221N was constructed from pGFY218L by replacingthe PstI by an NcoI site; plasmid pBIO52 was derived from pGFY221Nthrough replacing the 221-bp EoRl/NcoI fragment with a syntheticDNA segment of 52 bp representing the Escherichia coli atpEgene translational initiation region. The genes A, AB, AHB andAF^–B in the vector pGFY221N were expressed with a six-amino-acid-longleader sequence; in pBIO52 the genes were expressed directly.in vitro expression experiments were successful with all thegenes except with the AHB gene integrated into pGFY221N. Inthe E. coli minicell system expression was demonstrated withthe A gene in pGFY221N and the AF^–B and AHB genes in pBIO52.Complete translation of the expressed genes AB, AF^–B andAHB in either the in vitro or in vivo systems could be shownby using ³⁵S-labelled N-terminal methionine and C-terminal cysteine.Both amino acids occur only once in the peptide sequences.