Molecular dynamics study of Ca2+ binding loop variants of parvalbumin with modifications at the `gateway' position

The helix–loop–helix (i.e. EF-hand) Ca²⁺ ion bindingmotif is characteristic of a large family of high-affinity Ca²⁺ion binding proteins, including the parvalbumins and calmodulins.In this paper we describe a set of molecular dynamics computationson the major parvalbumin from the silver hake (SHPV-B). In allvariants examined, both whole protein and fragments thereof,the ninth loop residue in the Ca²⁺ binding coordination sitein the CD helix–loop–helix region (the so-called`gateway' residue) has been mutated. The three gateway mutationsexamined are arginine, which has never been found at the gatewayposition of any EF-hand protein, cysteine, which is the residueobserved least in natural EF-hand sites, and serine, which isthe most common (by far) non-acidic residue substitution atthis position in EF-hand proteins in general, but never in parvalbumins.Results of the molecular dynamics simulations indicate thatall three modifications are disruptive to the integrity of themutated Ca²⁺ binding site in the whole parvalbumin protein.In contrast, only the arginine and cysteine mutations are disruptiveto the integrity of the mutated Ca²⁺ binding site in the CDfragment of the parvalbumin protein. Surprisingly, the serinevariant of the CD helix–loop–helix fragment exhibitedremarkable stability during the entire molecular dynamics simulation,with retention of the Ca²⁺ binding site. These results indicatethat there are no inherent problems (for Ca²⁺ ion binding) associatedwith the sequence of the CD helix–loop–helix fragmentthat precludes the incorporation of serine at the gateway position.Since the CD site is totally disrupted in the whole proteinserine variant, this indicates that the Ca²⁺ ion binding deficienciesare most likely related to the unique interaction that existsbetween the paired EF-hands in the whole protein. Our theoreticalresults correlate well with previous studies on engineered EF-handproteins and with all of our experimental evidence on the silverhake parvalbumin.     

Effects of mutations in the calcium-binding sites of recoverin on its calcium affinity: evidence for successive filling of the calcium binding sites

A molecule of the photoreceptor Ca²⁺-binding protein recoverincontains four potential EF-hand Ca²⁺-binding sites, of whichonly two, the second and the third, are capable of binding calciumions. We have studied the effects of substitutions in the second,third and fourth EF-hand sites of recoverin on its Ca²⁺-bindingproperties and some other characteristics, using intrinsic fluorescence,circular dichroism spectroscopy and differential scanning microcalorimetry.The interaction of the two operating binding sites of wild-typerecoverin with calcium increases the protein's thermal stability,but makes the environment around the tryptophan residues moreflexible. The amino acid substitution in the EF-hand 3 (E121Q)totally abolishes the high calcium affinity of recoverin, whilethe mutation in the EF-hand 2 (E85Q) causes only a moderatedecrease in calcium binding. Based on this evidence, we suggestthat the binding of calcium ions to recoverin is a sequentialprocess with the EF-hand 3 being filled first. Estimation ofCa²⁺-binding constants according to the sequential binding schemegave the values 3.7 x 10⁶ and 3.1 x 10⁵ M^–1 for thirdand second EF-hands, respectively. The substitutions in theEF-hand 2 or 3 (or in both the sites simultaneously) do notdisturb significantly either tertiary or secondary structureof the apo-protein. Amino acid substitutions, which have beendesigned to restore the calcium affinity of the EF-hand 4 (G160D,K161E, K162N, D165G and K166Q), increase the calcium capacityand affinity of recoverin but also perturb the protein structureand decrease the thermostability of its apo-form.     

Aspartic acid 50 and tyrosine 108 are essential for receptor binding and cytotoxic activity of tumour necrosis factor beta (lymphotoxin)

Single amino acid substitutions were generated in predictedhydrophilic loop regions of the human tumour necrosis factorbeta (TNF-ß) molecule, and the mutant proteins wereexpressed in Escherichia coli and purified. Mutants with singleamino acid changes at either of two distinct loop regions, atpositions aspartic acid 50 or tyrosine 108, were found to havegreatly reduced receptor binding and cytotoxic activity. Thesetwo regions in TNF-ß correspond to known loop regionswhere mutations also result in loss of biological activity ofTNF–, a related cytokine which shares the same cellularreceptors with TNF-ß. The two distinct loops at positions31-34 and 84-89 in the known three-dimensional structure ofTNF- (equivalent to positions 46–50 and 105–110respectively in TNF-ß), lie on opposite sides of theTNF- monomer. When the TNF-a monomer forms a trimer, the twoloops, each from a different subunit of the trimer, come togetherand lie in a cleft between adjacent subunits. Together, thesefindings suggest that a TNF receptor binds to a cleft betweensubunits via surface loops at amino acid residues 31–34and 84–89 in TNF–, and similarly via surface loopsincluding amino acids aspartic acid 50 and tyrosine 108 in TNF–ß.     

Enzymatic amidation of recombinant (Leu27) growth hormone releasing hormone-Gly45

By chemoenzymatic synthesis the gene for a (Leu²⁷) analogueof human growth hormone releasing hormone-Gly⁴⁵ [(Leu²⁷GHRH-Gly⁴⁵]was constructed, cloned and expressed in Escherichia coli asa fusion protein with ß-galactosidase under the controlof the lac promoter and operator. Upon induction with isopropyl-D-thio-ß-galactopyranosidethe fusion protein accumulated to a yield of 15–20% ofthe total cellular protein. After cyanogen bromide deavage ofthe fusion protein the precursor peptide (Leu²⁷)hGHRH-Gly⁴⁵was separated by extraction and purified by ion exchange andh.p.l.c.-RP18 chromatography. The purified peptide was analysedby sequencing, isolectric focusing, amino acid analysis andamino acid analysis after V8 protease digestion. The carboxy-terminalglydne was subsequently amidated by PAM (peptidylglycine--amidating-monooxygenase),an enzyme which was isolated and characterized from fresh bovinepituitaries. Correct amidatlon of the penultimate amino acid,leucine, was verified by peptide sequencing with an authenticleucine amide reference.     

A pore-forming protein with a metal-actuated switch

Staphylococcal -hemolysin, a pore-forming exotoxin, is a polypeptideof 293 amino acids that is secreted by Staphylococcus aureusas a water-soluble monomer. It assembles to form hexameric poresin lipid bilayers. Previous studies of pore formation have establishedthe involvement of a central glycine-rich loop. Here, we showthat when five consecutive histidine residues replace aminoacids 130–134 at the midpoint of the loop, they providea switch with which pore activity can be (i) turned off by micromolarconcentrations of divalent zinc ions and (ii) turned back onwith the chelating agent EDTA. Planar bilayer recordings showthat Zn²⁺ and EDTA can act on open channels from either sideof the bilayer and thus demonstrate that the central loop linespart of the conductive pathway. Our results suggest that genetically-engineeredpore-forming proteins might make useful components of metalion sensors     

Site-directed and deletion mutational analysis of the receptor binding domain of the interleukin-6 receptor targeted fusion toxin DAB389-IL-6

We have used site-directed and in-frame deletion mutationalanalysis in order to explore the structural features of theIL–6 portion of the diphtheria toxin-related interleukin–6(IL–6) fusion toxin DAB₃₈₉-IL–6 that are essentialfor receptorbinding and subsequent inhibition of protein synthesisin target cells. Deletion of the first 14 amino acids of theIL–6 component of the fusion toxin did not alter eitherreceptor binding affinity or cytotoxk potency. In contrast,both receptor binding and cytotoxic activity were abolishedwhen the C–terminal 30 amino acids of the fusion toxinwere deleted. In addition, we explored the relative role ofthe disulfide bridges within the IL–6 portion of DAB₃₈₉-IL–6in the stabilization of structure required for receptor-binding.The analysis of mutants in which the substitution of eitherCys⁴⁴⁰, Cys⁴⁴⁶, Cys⁴⁶⁹ or Cys⁴⁷⁹ to Ser respectively, demonstratesthat only the disulfide bridge between Cys⁴⁶⁹ and Cys⁴⁷⁹ isrequired to maintain a functional receptor binding domain. Inaddition, the internal in-frame deletion of residues 435–451,which includes Cys⁴⁴⁰ and Cys⁴⁴⁶, was found to reduce, but notabolish receptor binding affinity. These results further demonstratethat the disulfide bridge between Cys⁴⁴⁰ and Cys⁴⁴⁶ is not essentialfor receptor-binding. However, the reduced cytotoxic potencyof DAB₃₈₉-IL6(435–451) suggests that the conformationand/or receptor binding sites associated with this region ofthe fusion toxin is/are important for maintaining the wild typereceptor binding affinity and cytotoxic potency.     

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.     

Overproduction of bovine {beta}-casein in Escherichia coli and engineering of its main chymosin cleavage site

A cDNA clone containing the entire coding region for bovineß-casein A³ flanked by 53 base pairs of 5' non-codingand 358 base pairs of 3' non-coding sequences was isolated froma bovine mammary cDNA phagemid library. The coding segment formature ß-casein was subcloned into the T7 expressionsystem, in which the expression of recombinant ß-caseinwas controlled by the T7 gene 10 promoter and ribosome bindingsite. High level expression of Met-ß-casein to 20%of the total soluble proteins was obtained in Escherichia coliwithin 2 h after induction of T7 RNA-polymerase synthesis. Inan attempt to induce secretion the coding segment for matureß-casein was coupled to the ompA translations initiationsignal and signal peptide coding sequence but no secretion ofthe fusion protein and no processing of the signal peptide fromthe fusion protein was observed. Instead, the Met-ß-caseincould be isolated in asoluble form from E.coli cells after anosmotic shock, indicative of a periplasmic location. This proceduredid not lyse the cells. The protein was purified to homogeneityafter a pH 4.8 isoelectric precipitation followed by reversed-phasehigh-performance liquid chromatography. The ß-caseincDNA was altered to change the main chymosin cleavage siteinß-casein at position 192–193 in two ways, namelyfrom Leu–Tyr to Pro–Pro and to Leu–stop. Thesemutations were designed to prevent generation of the bitterpeptide ßcasein(193–209) by chymosin cleavage.The mutant Met-ß-caseins were expressed in E.colito the same level as wild-type Met-ß-casein. Purifiedmutant Met-ß-casein(Prol92– Prol93) was no longerhydrolysed by chymosin at the 192–193 bond.     

Mutant forms of {beta}-galactosidase with an altered requirement for magnesium ions

By random approaches we have previously isolated many variantsof Escherichia coli ß-galactosidase within a shortcontiguous tract near the N-terminus (residues 8–12 ofwildtype enzyme), some of which have increased stability towardsheat and denaturants. The activity of these mutants was originallyanalysed and quantitated in situ in activity gels without theaddition of magnesium ions to the buffer system. We now showthat the improved stability is only observable under such conditionsof limiting magnesium ion concentrations or in the presenceof appropriate concentrations of a metal chelator. In the presenceof EDTA, purified preparations of one of these mutant enzymeswere much more resistant to denaturants than wild-type, butthis differential was completely nullified in the presence of1 mM Mg²⁺. However, the stability of this mutant enzyme in EDTAwas lower than that shown by it, or the wild-type enzyme, inthe presence of magnesium ions. In addition, certain alterationswithin another N-terminal tract (residues 27–31 of wild-type)resulted in enzymes with greater dependence on Mg²⁺ than naturalß-galactosidase. We conclude that a small number ofresidue changes in a large protein can profoundly modulate therequirement for metal ion stabilization, allowing partial abrogationof this need in certain cases. Thus, some enzymes which requiredivalent metal ions for structural purposes only may be engineeredtowards metal independence.     

Dihydrofolate reductase: control of the mode of substrate binding by aspartate 26

The complex of Lactobacillus casei dihydrofolate reductase withthe substrate folate and the coenzyme NADP^* has been shown toexist in solution as a mixture of three slowly interconvertingconformations whose proportions are pH-dependent and which differin the orientation of the pteridine ring of the substrate inthe binding site. The Asp26 – Asn mutant of L. casei dihydrofolatereductase has been prepared by oligonucleotide-directed mutagenesisand studied by one-and two-dimensional ¹H-NMR spectroscopy.NMR studies of the mutant enzyme–folate–NADP^* complexshow that this exists to > 90% in a single conformation overthe pH^* range 5–7.1. The single conformation observedcorresponds to conformation I (the ‘methotrexate-like’conformation) of the wild-type enzyme–folate–NADP^*complex. These observations demonstrate that Asp26 is the ionizablegroup controlling the pH-dependence of the conformational equilibriumseen in the wild-type enzyme.     

Predicted structure for the calcium-dependent membrane-binding proteins p35, p36 and p32

A new family of proteins (annexins) that bind to membranes atmicromolar free Ca²⁺ has been recognized. Its members includean EGF-receptor kinase substrate (p35) a retroviral tyrosinekinase substrate (p36), the liver protein endonexin (p32) andan electric ray protein, calelectrin. Each protein containsfour sequence repeats with a further 2-fold Internal homology.Using the predicted secondary structure and pat tern of conservedhydrophobic residues in each repeat, we have built a three-dimensionalmodel that is largely isostruc tural with the known molecularconformation of bovine In testinal calcium-binding protein.The final (energy-refined) model had a core formed from theconserved hydrophobic residues. It differed from ICaBP principallyin the length of the two Ca²⁺ loops with only one loop beingable to bind. The model suuggest a mechanism for interactionof these new Ca²⁺ proteins with phospholipid bilayers.     

Stability effects associated with the introduction of a partial and a complete Ca2+-binding site into human lysozyme

Two mutants of human lysozyme were synthesized. Mutant A92D,in which Ala92 was substituted by Asp, contains a partial Ca²⁺-bindingsite and mutant M4, in which Ala83, Gm86, Asn88 and Ala92 werereplaced by Lys, Asp, Asp and Asp respectively, contains thecomplete Ca -binding site of bovine a-lactalbumin. The Ca²⁺-bindingconstants of wild type human lysozyme and of mutants A92D andM4, measured at 25C and pH 7.5, were 2(1) x 102 M"1, 8(2)x l^M"1 and 9(0.5) x 10* M"1 respectively. Information gatheredfrom mkrocalorimetrk and CD spectro-scopic measurements indicatesthat the conformational changes of the M4 mutant lysozyme, inducedby Ca²⁺ binding, are smaller than those observed for bovinea-lactalbumin and for the Ca²⁺-binding equine lysozyme. At pH4.5, the thermostability of both the apo and Ca²⁺ forms of theA92D human was decreased in comparison with that of native humanlysozyme. In particular, within the apo form of this mutantan a-helix-containing sequence was destabilized. In contrast,at the same pH the thermostability of the apo and Ca²⁺ formsof the M4 mutant lysozyme was increased. The e-ammonium groupof the Lys83 side chain is assumed to be responsible for thestabilization of the apo form of this mutant.     

Stereochemical modeling of disulfide bridges. Criteria for introduction into proteins by site-directed mutagenesis

A computer modeling procedure for assessing the stereochemicalsuitability of pairs of residues in proteins as potential sitesfor introduction of cystine disulfide crosslinks has been developed.Residue pairs with C – C distances of 6.5 Å andC^beta;–C^ß distances of 4.5 Å are chosenfor geometrical fixation of S atoms using the program MODIP.The stereochemistry of the modeled disulfides is evaluated usinglimits for the structural parameters of the various torsionangles and S–S bond length in the disulfide bridge. Theability of the procedure to correctly model disulfides has beenchecked with examples of cystine peptides of known crystal structuresand 103 disulfide bridges from 25 available protein crystalstructures determined at 2 Å resolution. An analysis ofresults on three proteins with engineered disulfides, T4 lysozyme,dihydrofolate reductase and subtilisin, is presented. Two positionsfor the introduction of ‘stereochemically optimal’disulfides are identified in subtilisin.     

Investigation of the solution structure of chymotrypsin inhibitor 2 using molecular dynamics: comparison to X-ray crystallographic and NMR data

The native solution structure and dynamics of chymotrypsin inhibitor2 (CI2) have been studied using a long (5.3 ns) molecular dynamics(MD) simulation without any imposed restraints. The majorityof the experimentally observed spin–spin coupling constants,short– and long–range nuclear Overhauser effect(NOE) cross peaks and the amide hydrogen exchange behavior werereproduced by the MD simulation. This good correspondence suggeststhat the major structural features of the protein during thesimulation are representative of the true protein structurein solution. Two water molecules formed hydrogen bond bridgesbetween ß₂ and ß₃, in agreement with X–raycrystallographic data and a recent reassessment of the solutionstructure using time averaged NMR restraints during MD refinement.The active–site loop of the protein displayed the greateststructural changes and the highest mobility. When this loopregion was excluded, the average C r.m.s. deviation of the simulatedsolution structures from the crystal structure was 1.5 from0.5 to 5 3 ns. There is structural heterogeneity in particularregions of the NMR–derived solution structures, whichcould be a result of imprecision or true internal motion. Astudy of the distribution of mobility through the protein allowsus to distinguish between these two alternatives. In particular,deviations in the active–site loop appear to be a resultof heightened mobility, which is also supported by good correspondencebetween calculated and experimental S² N–H order parameters.On the other hand, other ill–defined regions of the NMR-derivedstructures are well defined in the simulation and are probablythe result of a lack of structural restraints (i.e. NOEs), asopposed to reflecting the true mobility.     

Identifying the mechanism of protein loop closure: a molecular dynamics simulation of the Bacillus stearothermophilus LDH loopin solution

The ‘loop’ involving residues 98–110 in Bacillusstearothermophilus lactate dehydrogenase (BSLDH) is of greatinterest as substrate-induced ‘loop’ closure isthought to berate-limiting and essential in catalyzing the reactionand in determining substrate specificity. Consequently, we haveexplored the mechanism underlying ‘loop’ openingin BSLDH through a molecular dynamics simulation at high temperature(1000 K) in the presence of explicit solvent, starting fromthe X-ray structure of BSLDH complexed with the co-enzyme NAD+and oxamate at 2.5 Å. During the simulation, a significantconformational change occurred, as evidenced by sharp dihedralangle transitions, hydrogen bond breaking and formation andlarge root mean square deviations from the starting structure;these changes define the criteria for ‘loop’ opening.The mechanical elements responsible for ‘loop’ opening,i.e. ‘loop’ hinges and flap, are defined througha combination of order parameters, dihedral angle changes andtheir correlations and the dynamical cross-correlation map ofatomic displacements for the ‘loop’ residues. Theresults indicate that the ‘loop’ consists of twoflexible hinge regions on either side of a relatively rigidthree-residue segment that undergoes a significant spatial displacementduring ‘loop’opening. ‘Loop’ openingis made possible through an array of correlated dihedral anglechanges and intra-& ‘loop’ rearrangements ofhydrogen-bond interactions. The presentfindings are comparedto previous work related to ‘loop’ opening and site-directedmutagenesis experiments.     

A grafting approach to obtain site-specific metal-binding properties of EF-hand proteins

The EF-hand calcium-binding loop III from calmodulin was insertedwith glycine linkers into the scaffold protein CD2.D1 at threelocations to study site-specific calcium binding propertiesof EF-hand motifs. After insertion, the host protein retainsits native structure and forms a 1:1 metal–protein complexfor calcium and its analog, lanthanum. Tyrosine-sensitized Tb³⁺energy transfer exhibits metal binding and La³⁺ and Ca²⁺ competefor the metal binding site. The grafted EF-loop III in differentenvironments has similar La³⁺ binding affinities, suggestingthat it is largely solvated and functions independently fromthe host protein. Received May 25, 2002; revised January 23, 2003; accepted April 25, 2003.     

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.     

Conformational properties of the guanine-binding site of ribonuclease T1 inferred from the X-ray structure and protein engineering

Recognition by ribonuclease T₁ of guanine bases via multidentatehydrogen bonding and stacking interactions appears to be mediatedmainly by a short peptide segment formed by one stretch of aheptapeptide, Tyr⁴²-Asn⁴³-Asn⁴⁴-Tyr⁴⁵-Gly⁴⁶-Gly⁴⁷-Phe⁴⁸. Thesegment displays a unique folding of the polypeptide chain—consistingof a reverse turn, Asn⁴⁴-Tyr⁴⁵-Glu⁴⁶-Gly⁴⁷, stabilized by ahydrogen-bond network involving the side chain of Asn⁴⁴, themain-chain atoms of Asn⁴⁴, Gly⁴⁷ and Phe⁴⁸ and one water molecule.The segment is connected to the C terminus of a ß-strandand expands into a loop region between Asn⁴³ and Ser⁵⁴. Lowvalues for the crystallographic thermal parameters of the segmentindicate that the structure has a rigidity comparable to thatof a ß-pleated sheet. Replacement of Asn⁴⁴ with alanineleads to a far lower enzymatic activity and demonstrates thatthe side chain of Asn⁴⁴ plays a key role in polypeptide foldingin addition to a role in maintaining the segment structure.Substitution of Asn⁴³ by alanine to remove a weak hydrogen bondto the guanine base destabilized the transition state of thecomplex by 6.3 kJ/mol at 37°C. In contrast, mutation ofGlu⁴⁶ to alanine to remove a strong hydrogen bond to the guaninebase caused a destabilization of the complex by 14.0 kJ/mol.A double-mutant enzyme with substitutions of Asn⁴³ by a histidineand Asn⁴⁴ by an aspartic acid, to reproduce the natural substitutionsfound in ribonuclease M_s, showed an activity and base specificitysimilar to that of the wild-type ribonuclease M_s. The segmenttherefore appears to be well conserved in several fungal ribonucleases.     

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.