Contribution of a proline residue and a salt bridge to the stability of a type I reverse turn in chymotrypsin inhibitor-2

The contributions of the components of a type I reverse turnto the stability of chymotrypsin inhibitor-2 (Lys43-Pro44-Gly45)have been determined by protein engineering methods. A double-mutantcycle was used to determine the interaction between Lys43 andGlu45 by replacing them with alanine. We also mutated Pro44,which gives the geometry of the turn, to alanine and analysedthe stability of the resulting mutants compared with wild-typechymotrypsin inhibitor-2, using equilibrium denaturation inducedby guanldinium chloride. There are decreases in stability (inkcal/mol) of 0.64 = 0.06 for Lys43 - Ala, 0.57 ± 0.15for Glu45 - Ala, 0.95 ± 0.06 for Lys43 - Ala/Glu45 -Ala and 1.93 ± 0.09 for Pro44 - Ala. The free energyof interaction between Lys43 and Glu45 is calculated to be only0.25 ± 0.09 kcal/mol. From the changes in denaturationmidpoint, T_m measured by circular dkhroism, we estimate theenergy of interaction between Lys43 and Glu45 to be 0.36 ±0.07 kcal/mol whereas the contribution of Pro44 is -2.0 kcal/mol.The contribution of the salt bridge to the stability of theprotein is very small and the residue Pro44 plays the key rolein stabilizing the turn     

Hydrophobic effects on protein/nucleic acid interaction: enhancement of substrate binding by mutating tyrosine 45 to tryptophan in ribonuclease Tl

Hydrophobic effects on binding of ribonuclease Tl to guaninebases of several ribonucleotides have been proved by mutatinga hydrophobic residue at the recognition site and by measuringthe effect on binding. Mutation of a hydrophobic surface residueto a more hydrophobic residue (Tyr45 – Trp) enhances thebinding to ribonucleotides, including mononucleotide inhibitorand product, and a synthetic substrate-analog trinudeotide aswell as the binding to dinucleotide substrates and RNA. Enhancementson binding to non-substrate ribonucleotides by the mutationhave been observed with free energy changes ranging from –2.2 to – 3 .9 kJ/mol. These changes are in good agreementwith that of substrate binding, –2.3 kJ/mol, which iscalculated from Michaelis constants obtained from kinetic studies.It is shown, by comparing the observed and calculated changesin binding free energy with differences in the observed transferfree energy changes of the amino acid side chains from organicsolvents to water, that the enhancement observed on guaninebinding comes from the difference in the hydrophobic effectsof the side chains of tyrosine and tryptophan. Furthermore,a linear relationship between nucleolytic activities and hydrophobicityof the residues (Ala, Phe, Tyr, Trp) at position 45 is observed.The mutation could not change substantially the base specificityof RNase Tl, which exhibits a prime requirement for guaninebases of substrates.     

Mutations to alter Aspergillus awamori glucoamylase selectivity. IV. Combinations of Asn20->Cys/Ala27->Cys, Ser30->Pro, Gly137->Ala, 311314 Loop, Ser411->Ala and Ser436->Pro

Six previously constructed and nine newly constructed Aspergillusawamori glucoamylases with multiple mutations made by combiningexisting single mutations were tested for their ability to produceglucose from maltodextrins. Multiple mutations have cumulativeeffects on glucose yield, specific activity and thermostability.No general correlation between glucose yield and thermostabilitywas observed, although mutations that presumably impede unfoldingat high temperatures uniformly increase thermostability andgenerally increase glucose yield. Peak glucose yields decreasewith increasing temperature. The best combination of high glucoseyield, high specific activity and high thermostability occursin Asn20Cys/Ala27Cys/Ser30Pro/Gly137Ala glucoamylase.     

Improvement of Fc-erythropoietin structure and pharmacokinetics by modification at a disulfide bond

Erythropoietin (Epo) is a cytokine that controls the production of red blood cells (RBCs). Epo acts continuously on RBC precursors to prevent apoptosis, so it is important to maintain high levels of Epo activity when treating anemic patients. We describe here modified human Epo [Epo(NDS)] with mutations His32Gly, Cys33Pro, Trp88Cys and Pro90Ala that result in the rearrangement of the disulfide bonding pattern from Cys29-Cys33 to Cys29-Cys88 and that, in the context of an Fc-Epo(NDS) fusion protein, lead to significantly improved properties. Fc-Epo was secreted from NS/0 myeloma cells as about 35% high molecular weight aggregates, was unstable upon removal of N-linked oligosaccharides and showed poor pharmacokinetics and little efficacy in mice. In contrast, a corresponding Fc-Epo(NDS) was secreted almost exclusively as a unit dimer, was relatively stable to removal of N-linked oligosaccharides, had much improved pharmacokinetic properties and had a significantly improved effect on RBC production. These results indicate that rearrangement of the disulfide bonding pattern in a therapeutic protein can have a significant effect on pharmacokinetics and, potentially, the dosing schedule of a protein drug.     

Stabilization of Aspergillus awamori glucoamylase by proline substitution and combining stabilizing mutations

To stabilize Aspergillus awamori glucoamylase (GA), three proline substitution mutations were constructed. When expressed in Saccharomyces cerevisiae, Ser30-->Pro (S30P) stabilized the enzyme without decreased activity, whereas Asp345-->Pro (D345P) did not significantly alter and Glu408-->Pro (E408P) greatly decreased enzyme thermostability. The S30P mutation was combined with two previously identified stabilizing mutations: Gly137-->Ala, and Asn20-->Cys/Ala27-- >Cys (which creates a disulfide bond between positions 20 and 27). The combined mutants demonstrated cumulative stabilization as shown by decreased irreversible thermoinactivation rates between 65 and 80 degrees C. Additionally, two of the combined mutants outperformed wild- type GA in high-temperature (65 degrees C) saccharifications of DE 10 maltodextrin and were more active than the wild-type enzyme when assayed using maltose as substrate.      

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.     

Folding and conformational studies on SCR1-3 domains of human complement receptor 1

Short consensus repeats SCR3 and SCR1-3 are soluble recombinantproteins, consisting of the third and first three N-terminaldomains of complement receptor 1, respectively, which retainsome anti-complement activity. The conformational stabilitiesand folding/unfolding of SCR3 and SCR1-3 have been studied usingcircular dichroism and equilibrium and pre-equilibrium fluorescencespectroscopy. Denaturation by guanidinium hydrochloride (GdnHCl)is rapid and completely reversible. Reduction of disulphidebridges in the folded proteins by ß-mercaptoethanolleads to an increase in fluorescence intensity. The fluorescenceintensity of the folded proteins is {small tilde}7.5% of thatof the respective unfolded proteins. The data can be approximatedto a two-state transition between native and denatured formsof the proteins. SCR3 has a conformational stability in waterof 12–13 kJ/mol whereas that of SCR1-3 is 19.5–19.9kJ/mol depending upon the technique utilized. The heat capacitychange associated with the unfolding of SCR1-3 was obtainedby a series of GdnHCl unfolding experiments over a range oftemperatures and was found to be 6.6 kJ/K.mol or 33.8 J/K.mol_residue.The refolding process of SCR3 was found to be simple, describedby a single exponential equation, whereas that of SCR1-3 wasfound to be complex and could be fitted to a double exponentialequation indicating the presence of folding intermediates.     

Specificity determinants of rat tissue kallikrein probed by site-directed mutagenesis

Site-specific mutagenesis was employed to study structure-functionrelationships at the substrate binding site of rat tissue kallikrein.Four kallikrein mutants, the Pro219 deletion (P219del), the34–38 loop Tyr-Tyr-Phe-Gly to Ile-Asn mutation [YYFG(34–38)IN],the Trp215Gly exchange (W215G) and the double mutant with Tyr99Hisand Trp215Gly exchange (Y99H:W215G) were created by site-directedmutagenesis to probe their function in substrate binding. Themutant proteins were expressed in Esclzerichia coli at highlevels and analyzed by Western blot. These mutant enzymes werepurified to apparent homogeneity. Each migrated as a singleband on SDS-PAGE, with slightly lower molecular mass (36 kDa)than that of the native enzyme, (38 kDa) because of their lackof glycosylation. The recombinant kallikreins are immunologicallyidentical to the native enzyme, displaying parallelism withthe native enzyme in a direct radioimmunoassay for rat tissuekallikrein. Kinetic analyses of K_m and k_cat using fluorogenicpeptide substrates support the hypothesis that the Tyr99–Trp215interaction is a major determinant for hydrophobic P2 specificity.The results suggest an important role for the 34–38 loopin hydrophobic P3 affinity and further show that Pro219 is essentialto substrate binding and efficient catalysis of tissue kallikrein.     

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.     

Effect of introducing proline residues on the stability of Aspergillus awamori

In Aspergillus awamori glucoamylase, Ala27, Ala393, Ala435, Ser436 and Ser460 were replaced with proline residues, in order to stabilize the enzyme by forming more rigid peptide backbones. Specific activities were unaffected except for a decrease in Ser460-->Pro glucoamylase. Thermostability was increased in Ser436-->Pro glucoamylase, unchanged in Ala435-->Pro glucoamylase and decreased in Ala27-->Pro, Ala393-->Pro glucoamylases. As measured by circular dichroism, mutant glucoamylases Ala435-->Pro and Ser436-->Pro resisted unfolding caused by guanidine hydrochloride at pH 4.5 and 25 degrees C better than wild-type glucoamylase, whereas mutant glucoamylases Ala27-->Pro, Ala393-->Pro and Ser460-->Pro were more susceptible to unfolding than wild-type glucoamylase, reaching a level of 50% unfolded enzyme at guanidine hydrochloride concentrations 0.50-0.75 M lower than that of the wild- type enzyme. Mutations Ala435-->Pro and Ser436-->Pro are located in a non-regular structure, which is assumed to be stabilized by these mutations. The Ala27-->Pro residue is partially buried, which may result in unfavorable steric contact and/or regional strains; mutation Ala393-->Pro results in loss of a hydrogen bond, since the N of the proline residue does not have an extra hydrogen to act as donor; and mutation Ser480-->Pro eliminates an O-glycosylation site, which could explain how these mutations destabilized glucoamylase.      

Confirmation of the predicted source of a slow folding reaction: proline 8 of bovine pancreatic trypsin inhibitor

A major question in protein structural analysis concerns theapplicability of results from model systems to other proteins.Theoretical approaches seem the best manner of transferringinformation from one system to another, but their accuracy inthe model systems must first be tested with results from experiment.Since bovine pancreatic trypsin inhibitor (BPTI) is a modelsystem for the evaluation of energy minimization and moleculardynamics routines, we can use folding and stability measurementsto examine the reliability of these methods. All two-disulfidemutants of BPTI investigated thus far have two very slow foldingreactions which have characteristics of proline isomerization.These reactions may occur because the non-native cis form oftwo of the four prolines in BPTI significantly destabilizesthe folded state of the protein. Previous energy minimizationstudies of wild-type BPTI suggested that the cis form of Pro8was the most destabilizing of the four prolines [Levitt,M. (1981)J. Mol. Biol., 145, 251–263]. In this paper, we show thatmutation of Pro8 - Gln in the two-disulfide bond mutant Val30–Ala51results in a loss of the slowest folding reaction, consistentwith Levitt's prediction.     

Enhancing the thermal stability of mitochondrial cytochrome b5 by introducing a structural motif characteristic of the less stable microsomal isoform

Outer mitochondrial membrane cytochrome b5 (OM b5) is the most thermostable cytochrome b5 isoform presently known. Herein, we show that OM b5 thermal stability is substantially enhanced by swapping an apparently invariant motif in its heme-independent folding core with the corresponding motif characteristic of its less stable evolutionary relative, microsomal cytochrome b5 (Mc b5). The motif swap involved replacing two residues, Arg15 with His and Glu20 with Ser, thereby introducing a Glu11-His15-Ser20 H-bonding triad on the protein surface along with a His15/Trp22 pi-stacking interaction. The ferric and ferrous forms of the OM b5 R15H/E20S double mutant have thermal denaturation midpoints (Tm values) of approximately 93 degrees C and approximately 104 degrees C, respectively. A 15 degrees C increase in apoprotein Tm plays a key role in the holoprotein thermal stability enhancement, and is achieved by one of the most common natural mechanisms for stabilization of thermophilic versus mesophilic proteins: raising the unfolding free energy along the entire stability curve.     

Structural study of mutants of Escherichia coli ribonuclease HI with enhanced thermostability

Systematic replacement of the amino acid residues in Escherichiacoli ribonuclease HI with those in the thermophilic counterparthas revealed that two mutations, His62–Pro (H62P) andLys95Gly (K95G), increased the thermostability of the protein.These single-site mutant proteins, together with the mutantproteins His62Ala (H62A), Lys95Asn (K95N) and Lys95Ala (K95A),were crystallized and their structures were determined at 1.8Å resolution. The crystal structures of these mutant proteinsreveal that only the local structure around each mutation siteis essential for the increase in thermostability. For each mutantprotein, the stabilization mechanism is considered to be asfollows: (i) H62P is stabilized because of a decrease in theentropy of the unfolded state, without a change in the nativebackbone structure; (ii) K95G is stabilized since the straincaused by the left-handed backbone structure in the typical3:5 type loop is eliminated; and (iii) K95N is slightly stabilizedby a hydrogen bond formed between the side-chain N-atom of themutated aspargine residue and the main-chain carbonyl oxygenwithin the same residue.     

Hydrophobicity engineering of cholera toxin A1 subunit in the strong adjuvant fusion protein CTA1-DD

Protein engineering of the cholera toxin A1 subunit (CTA1) fusedto a dimer of the Ig-binding D-region of Staphylococcus aureusprotein A (DD) was employed to investigate the effect of specificamino acid changes on solubility, stability, enzymatic activityand capacity to act as an adjuvant in vivo. A series of CTA1-DDanalogues were selected by a rational modeling approach, inwhich surface-exposed hydrophobic amino acids of CTA1 were exchangedfor hydrophilic counterparts modeled for best structural fit.Of six different mutants initially produced, two analogues,CTA1Phe132Ser-DD and CTA1Pro185Gln-DD, were demonstrated tohave 50 and 70% increased solubility, respectively, at neutralpH. The double mutant CTA1Phe132Ser/Pro185Gln-DD was at leastthreefold more soluble, demonstrating an additive effect ofthe two mutations. Only the Phe132Ser analogue retained fullbiological activity and stability compared with the native CTA1-DDfusion protein. Two mutants, Pro185Gln and Phe31His mutations,exhibited unaltered ADP-ribosyltransferase activity in vitro,but demonstrated markedly reduced adjuvant function. Since thePro185 and Phe31 amino acids are located in close vicinity onthe distal side of the molecule relative to the enzymaticallyactive cleft, it is conceivable that this region is involvedin mediating a biological function, separate from the enzymaticactivity but intrinsic to the adjuvant activity of CTA1.     

Site-directed mutagenesis reveals functional contribution of Thr218, Lys220 and Asp304 in chymosin

The functional contributions of amino acid residues Thr218 andAsp304 of chymosin, both of which are highly conserved in theaspartic proteinases, are analysed by means of site-directedmutagenesis. The optimum pH values, milk-clotting (C) and proteolytic(P) activities and kinetic parameters for synthetic oligopeptidesas substrates were examined for the mutant enzymes. The mutationThr2l8Ser caused a marked increase in the C/P ratio, which seemedto be due to a change in substrate recognition. Although thenegative charge of Asp304 had been expected to play a role inlowering the optimum pH values in the aspartic proteinases,this turned out not to be the case in chymosin because boththe mutations Asp304Ala and Asp304Glu caused a similar shiftof the optimum pH towards the acidic side. In addition, themutation Lys220Leu, which we generated previously, was foundto cause a decrease in the C/P ratio, mainly due to the increasein the proteolytic activity.     

A sequence motif in the transmembrane region of growth factor receptors with tyrosine kinase activity mediates dimerization

A mechanism by which ligand binding to the extracellular domainof a growth factor receptor causes activation of its cytoplasmictyrosine kinase domain is that binding promotes receptor dimerization.Recently we proposed a model in which dimerization of the transmembrane-helices in one member of this family, rat neu, is mediatedby the presence of three specific residues. This paper showsthat a similar sequence motif is observed in 18 of the 20 transmembrane-helices of the tyrosine kinase family of growth factor receptors.The motif encompasses a five residue segment in which position0 (P0) requires a small side chain (Gly, Ala, Ser, Thr or Pro),P3 an aliphatic side chain (Ala, Val, Leu or Ile) and P4 onlythe smallest side chains (Gly or Ala). In addition other featuresof the transmembrane sequences are reported. It is concludedthat the dimerization of transmembrane -helices may be a generalmechanism of tyrosine kinase activation in this family of growthfactor receptors.     

Mutations to alter Aspergillus awamori glucoamylase selectivity. III. Asn20-->Cys/Ala27-->Cys, Ala27-->Pro, Ser30-->Pro, Lys108-->Arg, Lys108- ->Met, Gly137-->Ala, 311-314 Loop, Tyr312-->Trp and Ser436-->Pro

Mutations Asn20-->Cys/Ala27-->Cys (SS), Ala27-->Pro, Ser30-->Pro, Lys108-->Arg, Gly137-->Ala, Tyr312-->Trp and Ser436-->Pro in Aspergillus awamori glucoamylase, along with a mutation inserting a seven-residue loop between Tyr311 and Gly314 (311-314 Loop), were made to increase glucose yield from maltodextrin hydrolysis. No active Lys108-->Met glucoamylase was found in the supernatant after being expressed from yeast. Lys108-->Arg, 311-314 Loop and Tyr312-->Trp glucoamylases have lower activities than wild-type glucoamylase; other GAs have the same or higher activities. SS and 311-314 Loop glucoamylases give one-quarter to two-thirds the relative rates of isomaltose formation from glucose compared with glucose formation from maltodextrins at 35, 45 and 55 degrees C, correlating with up to 2% higher peak glucose yields from 30% (w/v) maltodextrin hydrolysis. Conversely, Lys108-->Arg glucoamylase has relative isomaltose formation rates three times higher and glucose yields up to 4% lower than wild- type glucoamylase. Gly137-->Ala and Tyr312-->Trp glucoamylases also give high glucose yields at higher temperatures. Mutated glucoamylases that catalyze high rates of isomaltose formation give higher glucose yields from shorter than from longer maltodextrins, opposite to normal experience with more efficient glucoamylases.      

Mutations to alter Aspergillus awamori glucoamylase selectivity. II. Mutation of residues 119 and 121

Mutations Ser119-->Glu, Ser119-->Gly, Ser119-->Trp, Gly121-->Ala and Gly121-->Ala/Ser411-->Gly were constructed in glucoamylase to change substrate specificity. Mutation Ser411-->Gly was already known to decrease glucoamylase selectivity toward isomaltose formation and to increase peak glucose yield. All mutated glucoamylases had slightly lower specific activities on maltose than on wild-type glucoamylase. Ser119-->Glu, Ser119-->Gly and Ser119-->Trp glucoamylases were about as active on isomaltose and DP 4-7 maltooligosaccharides as wild-type glucoamylase. Gly121-->Ala and Gly121-->Ala/Ser411-->Gly glucoamylases were less active. At 55 degrees C Ser119-->Glu, wild-type, Ser119-- >Trp, Ser119-->Gly, Gly121-->Ala and Gly121-->Ala/Ser411-->Gly glucoamylases had progressively higher peak glucose yields, generally in the opposite order to their activities. There was also an inverse correlation between peak glucose yield and ratio of initial rate of isomaltose production from glucose condensation to that of glucose production from maltodextrin hydrolysis. The effect of mutations Gly121- ->Ala and Ser411-->Gly was not additive in predicting the effect of the double mutation on the ratio or on peak glucose yield.      

Cellulase EGZ of Erwinia chrysanthemi: structural organization and importance of His98 and Glu133 residues for catalysis

Biochemical, genetic and primary sequence analyses of the Erwiniachrysanthemi endoglucanase EGZ allowed us to identify two functionaldomains and to locate their boundaries. The catalytic domainextends from residue 1 to 288, while a domain required for EGZto bind to microcrystalline cellulose lies from residues 324to 385. Each domain was found capable of functioning in theabsence of the other. A region rich in Pro, Thr and Ser residueslinks both domains and appeared to be susceptible to proteolyticattack. Based upon predictions derived from a method developedto compare sequences sharing a low level of similarity, e.g.hydrophobic cluster analysis (HCA), we analysed the importanceof either residue His98 or Glul33 in EGZ catalytic activity.Two EGZ-derived proteins were engineered in which either His98or Glul33 amino acid was converted to an Ala residue. Characterizationof the purified proteins showed that no enzymatic activity couldbe detected, by using carboxymethylcellulose (CMC) or paranitrophenyl-cellobioside(pNPC) as substrates, while both mutated proteins retained thecapacity to bind to microcrystalline cellulose. These studies,which to date constitute the first experimental testing of HCA-derivedpredictions, allowed us to identify two particular amino acidsinvolved in cellulolytic activity. By taking into account datafrom chemical modification studies of other cellulases, we speculatethat the His98 residue is involved in the folding of the catalyticdomain while the Glul33 residue intervenes directly in the ß,1–4 glycosidic bond cleavage.     

Contribution of a disulfide bridge to the stability of 1,3-1,4-P-D-glucan 4-glucanohydrolase from Bacillus licheniformis

Bacillus 1,3-1,4-ß-glucanases possess a highly conserveddisulfide bridge connecting a ß-strand with a solventexposedloop lying on top of the extended binding site cleft The contributionof the disulfide bond and of both individual cysteines (Cys61and Cys90) in the Bacillus licheniformis enzyme to stabilityand activity has been evaluated by protein engineering methods.Reduction of the disulfide bond has no effect on kinetic parameters,has only a minor effect on the activity-temperature profileat high temperatures, and destabilizes the protein by less than0.7 kcal/mol as measured by equilibrium urea denatu ration at37°C. Replacing either of the Cys residues with Ala destabilizesthe protein and lowers the specific activity. C90A retains 70%of wild-type (wt) activity (in terms of Vmax), whereas C61Aand the double mutant C61A–C90A have 10% of wt V_max. Alarger change in free energy of unfolding is seen by equilibriumurea denaturation for the C61A mutation (loop residue, 3.2 kcal/molrelative to reduced wt) as compared with the C90A mutation (ß-strandresidue, 1.8 kcal/mol relative to reduced wt), while the doublemutant C61A–C90A is 0.8 kcal/mol less stable than thesingle C61A mutant. The effects on stability are interpretedas a result of the change in hydrophobic packing that occursupon removal of the sulfur atoms in the Cys to Ala mutations