Expression and characterization of Lactobacillus 30a histidine decarboxylase in Escherichia coli

The genes coding for histidine decarboxylase from a wild-typestrain and an autoactivation mutant strain of Lactobacillus30a have been cloned and expressed in Escherichia coli. Themutant protein, G58D, has a single Asp for Gly substitutionat position 58. The cloned genes were placed under control ofthe ß-galactosidase promoter and the products arenatural length, not fusion proteins. The enzyme kinetics ofthe proteins isolated from E. coli are comparable to those isolatedfrom Lactobacillus 30a. At pH 4.8 the K_m of wild-type enzymeis 0.4 mM and the k_cat = 2800 min^–1; the correspondingvalues for G58D are 0.5 mM and 2750 min^–1. The wild-typeand G58D have autoactivation half-times of 21 and 9 h respectivelyunder pseudophysiological conditions of 150 mM K⁺ and pH 7.0.At pH 7.6 and 0.8 M K⁺ the half times are 4.9 and 2.9 h. Therelatively slow rate of autoactivation for purified proteinand the differences in cellular and non-cellular activationrates, coupled with the fact that wild-type protein is readilyactivated in wild-type Lactobacillus 30a but poorly activatedin E. coli, suggest that wild-type Lactobacillus 30a containsa factor, possibly an enzyme, that enhances the activation rate.     

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.     

The structure of E.coli soluble inorganic pyrophosphatase at 2.7 A resolution

Hie structure of E.coli soluble inorganic pyrophosphatase hasbeen refined at 2.7 resolution to an R-factor of 20.9. Theoverall fold of the molecule is essentially the same as yeastpyrophosphatase, except that yeast pyrophosphatase is longerat both the N- and C-termini. Escherichia coli pyrophosphataseis a mixed +ß protein with a complicated topology.The active site cavity, which is also very similar to the yeastenzyme, is formed by seven ß-strands and an -helixand has a rather asymmetric distribution of charged residues.Our structure-based alignment extends and improves upon earliersequence alignment studies; it shows that probably no more than14, not 15–17 charged and polar residues are part of theconserved enzyme mechanism of pyrophosphatases. Six of theseconserved residues, at the bottom of the active site cavity,form a tight group centred on Asp70 and probably bind the twoessential Mg⁺ ions. The others, more spreadout and more positivelycharged, presumably bind substrate. Escherichia coli pyrophosphatasehas an extra aspartate residue in the active site cavity, whichmay explain why the two enzymes bind divalent cation differently.Based on the structure, we have identified a sequence motifthat seems to occur only in soluble inorganic pyrophosphatases.     

In vivo copper- and cadmium-binding ability of mammalian metallothionein domain

The ß domain of mouse metallothionein 1 (ßMT) wassynthesized in Escherichia coli cells grown in the presenceof copper or cadmium. Homogenous preparations of Cu–ßMTand Cd–ßMT were used to characterize the correspondingin vivo-conformed metal-clusters, and to compare them with thespecies obtained in vitro by metal replacement to a canonicalZn₃–ßMT structure. The copper-containing ßMTclusters formed inside the cells were very stable. In contrast,the nascent ß peptide, although it showed cadmium bindingability, produced a highly unstable species, whose stoichiometrydepended upon culture conditions. The absence of ßMT proteinin E.coli protease-proficient hosts grown in cadmium-supplementedmedium pointed to drastic proteolysis of a poorly folded ßpeptide, somehow enhanced by the presence of cadmium. Possiblefunctional and evolutionary implications of the bioactivityof mammalian ßMT in the presence of monovalent and divalentmetal ions are discussed.     

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.     

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.     

The cystine knot of a squash-type protease inhibitor as a structural scaffold for Escherichia coli cell surface display of conformationally constrained peptides

The Ecballium elaterium trypsin inhibitor II (EETI-II), a memberof the squash family of protease inhibitors, is composed of28 amino acid residues and is a potent inhibitor of trypsin.Its compact structure is defined by a triple-stranded antiparallelß-sheet, which is held together by three intramoleculardisulfide bonds forming a cystine knot. In order to explorethe potential of the EETI-II peptide to serve as a structuralscaffold for the presentation of randomized oligopeptides, weconstructed two EETI-II derivatives, where the six-residue inhibitorloop was replaced by a 13-residue epitope of Sendai virus L-proteinand by a 17-residue epitope from human bone Gla-protein. EETI-IIand derived variants were produced via fusion to maltose bindingprotein MalE. By secretion of the fusion into the periplasmicspace, fully oxidized and correctly folded EETI-II was obtainedin high yield. EETI-II and derived variants could be presentedon the Escherichia coli outer membrane by fusion to truncatedLpp'–OmpA', which comprises the first nine residues ofmature lipoprotein plus the membrane spanning ß-strandfrom residues 46–66 of OmpA protein. Gene expression wasunder control of the strong and tightly regulated tetA promoter/operator.Cell viability was found to be drastically reduced by high levelexpression of Lpp'–OmpA'–EETI-II fusion protein.To restore cell viability, net accumulation of fusion proteinin the outer membrane was reduced to a tolerable level by introductionof an amber codon at position 9 of the lpp' sequence and utilizingan amber suppressor strain as expression host. Cells expressingEETI-II variants containing an epitope were shown to be surfacelabeled with the respective monoclonal antibody by indirectimmunofluorescence corroborating the cell surface exposure ofthe epitope sequences embedded in the EETI-II cystine knot scaffold.Cells displaying a particular epitope sequence could be enriched10⁷-fold by combining magnetic cell sorting with fluorescence-activatedcell sorting. These results demonstrate that E.coli cell surfacedisplay of conformationally constrained peptides tethered tothe EETI-II cystine knot scaffold has the potential to becomean effective technique for the rapid isolation of small peptidemolecules from combinatorial libraries that bind with high affinityto acceptor molecules.     

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.     

Biosynthesis of winter flounder antifreeze proprotein in E.coli

A semisynthetic winter flounder antifreeze proprotein (proAFP)coding region was constructed and inserted into a lacZ expressionvector. ProAFP was produced from the vector in Escherichia colias a C-terminal fusion to the first 289 amino acids of ß-galactosidase(ß-gal). The proAFP and ß-gal domains ofthe ß-gal–proAFP fusion protein were separatedby the recognition signal for the blood coagulation protease,factor X_a. Upon induction with isopropylthio-ß-D-galactosidethe fusion protein accumulated to levels of 15% of the totalprotein. The ß-gal–proAFP fusion protein waspartially purified by differential centrifugation, but requiredsolubilization prior to factor X_a digestion. The solubilizedfusion protein was efficiently and correctly cleaved by factorX_a, after which the proAFP was purified by gel permeation. BacterialproAFP was indistinguishable from natural proAFP by the criteriaof antifreeze activity, amino-terminal sequence (15 cycles),reverse-phase HPLC and SDS–polyacrylamide gel electrophoresis.Circular dichroism measurements showed that proAFP is a compositeof random coil and -helical secondary structure, with an -helicalcontent of 44% at 0°C. It seems probable that the C-terminalregion of proAFP, which corresponds to the mature AFP protein,is mainly -helical, and that the N-terminal pro-segment is randomcoiled.     

Engineering of the substrate-binding region of the sublilisin-like, cell-envelop proteinase of Lactococcus lactis

The substrate-binding region of the cell-envelope proteinaseof Lactococcus lactis strain SK11 was modelled, based on sequencebomology of the catalytic domain with the serine proteinasessubtilisin and thermitase. Substitutions, deletions and insertionswere introduced, by site-directed and cassette mutagenesfe ofthe prtP gene encoding this enzyme, based on sequence comparisonboth with subtilisin and with the homologous L.lactis strainWg2 proteinase, which has different proteolytic properties.The engineered enzymes were investigated for thermal stability,proteolytic activity and cleavage specificity towards smallchromogenk peptide substrates and the peptide _g1-casein(l–23).Mutations in the subtilisin-like substrate-binding region showedthat Ser433 is the active site residue, and that residues 138and 166 at either side of the binding cleft play an importantrole in substrate specificity, particularly when these residuesand the substrate are oppositely charged. The K748T mutationin a different domain also affected specificity and stability,suggesting that this residue is in close proximity to the subtilisin-likedomain and may form part of the substratebinding site. Severalmutant SK11 proteinases have novel properties not previouslyencountered in natural variants. Replacements of residues 137–139AKTalong one side of the binding cleft produced the 137–139GPPmutant proteinase with reduced activity and narrowed specificity,and the 137–139GLA mutant with increased activity andbroader specificity. Furthermore, the 137–139GDT mutanthad a specificity towards _g1,-casein(l–23) closely resemblingthat of L.lactis Wg2 proteinase. Mutants with an additionalnegative charge in the binding region were more stable towardsautoproteolysis.     

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).     

Cloning and expression in E.coli of a synthetic gene for the bacteriocidal protein caltrin/seminalplasmin

A synthetic gene coding for the bacteriocidal protein caltrin/seminalplasminwas constructed and expressed in Escherichia coli as a fusionwith ß-galactosidase. The gene was designed with arecognition site for the plasma protease, Factor X_a, coded forimmediately prior to the N-terminus of caltrin. The ß-galactosidase-caltrinfusion protein was cleaved with Factor X_a to give caltrin, whichwas identified by its size on SDS-PAGE, its ability to reactwith an antiserum raised to the N-terminal nonapeptide of caltrinand its N-terminal amino acid sequence. After partial purification,synthetic caltrin was found to be active in an assay involvinginhibition of growth of E.coli.     

A new protein conjugate that replaces the use of secondary antibodies engineered from the two staphylococcal enzymes protein A and 6-phospho-{beta}-galactosidase

The lacG gene encoding the 6-phospho-ß-galactosidase(E.C.3.2.1.85) of Staphylococcus aureus was fused to the proteinA gene in the plasmid pRIT2T. Escherichia coli cells containingthis plasmid produce a fusion protein with both IgG bindingand 6-phospho-ß-galactosidase activities after heatinduction. The recombinant gene was overexpressed and the hybridprotein was purified to homogeneity in high yield. The chimericprotein was shown to have almost identical enzymatic characteristicsto pure 6-phospho-ß-galactosidase. This result leadsto the conclusion that a free N-terminus of the 6-phospho-ß-galactosidaseis not required for biological activity. The hybrid proteinof protein A and 6-phospho-ß-galactosidase was usedas an enzyme conjugate in enzyme-linked immunosorbent assays(ELISA). The experiments presented demonstrate that the 6-phospho-ß-galactosidaseis a suitable fusion partner in various diagnostic applicationswhere an unique biological activity is required.     

Recombinant pro-regions from papain and papaya proteinase IV are selective high affinity inhibitors of the mature papaya enzymes

Proteolytic enzymes require the presence of their proregionsfor correct folding. Of the four proteolytic enzymes from Caricapapaya, papain and papaya proteinase IV (PPIV) have 68% sequenceidentity. We find that their proregions are even more similar,exhibiting 73.6% identity. cDNAs encoding the pro-regions ofthese two proteinases have been expressed in Escherichia coliindependently from their mature enzymes. The recombinant pro-regionsof papain and PPIV have been shown to be high affinity inhibitorsof all four of the mature native papaya cysteine proteinases.Their inhibition constants are in the range 10^–6–;10^–;9M. PPIV was inhibited two to three orders of magnitude lesseffectively than papain, chymopapain and caricain. The pro-regionof PPIV, however, inhibited its own mature enzyme more effectivelythan did the proregion of papain. Alignment of the sequencesof the four papaya enzymes shows that there is a highly variablesection towards the C-terminal of the pro-region. This regionmay therefore confer selectivity to the pro-regions for theindividual proteolytic enzymes.     

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.     

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.     

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.     

Internalization and translocation of a new chimeric protein composed of Pseudomonas aeruginosa exotoxin A and mouse dihydrofolate reductase as a model system

In an attempt to introduce a large peptide that is not normallytranslocated across membranes into the cytosol of eukaryoticcells, we created a new chimeric protein termed CEDH betweenPseudomonas aeruginosa exotoxin A (ETA) and a variant enzymeof Mus musculus dihydrofolate reductase (DHFR) with reducedaffinity for antifolates, ETA^1–413.DHFR^1–187.ETA^609–613.We have defined, genetically constructed and expressed the chimericprotein in Escherichia coli. We showed that the CEDH chimericprotein, purified to homogeneity on an immunoaffinity resin,confers a methotrexate-resistant phenotype to Chinese hamsterovary cells. Furthermore, the chimeric protein allowed the growthof dihydrofolate reductase-deficient Chinese hamster ovary cellsin the absence of hypoxanthine and thymidine. These resultsdemonstrated that the chimeric protein exhibited enzyme activityand possessed the tightly folded native structure, and thatthe DHFR protein can be selectively internalized and translocatedvia domains of exotoxin A. These data show that the ETA systemis an efficient system for the delivery of a variety of largepolypeptides into the cytosol without stress to the target cells,and extends the use of this delivery system to proteins thatare not normally translocated across membranes.     

High-level expression, purification, kinetic characterization and crystallization of protein farnesyltransferase -subunit C-terminal mutants

Protein farnesyltransferase (FPT) is a 97 000 Da heterodimericenzyme that catalyzes post-translational farnesylation of manycellular regulatory proteins including p21 Ras. To facilitatethe construction of site-directed mutants, a novel translationallycoupled, two-cistron Escherichia coli expression system forrat FPT has been developed. This expression system enabled yieldsof >5 mg of purified protein per liter of E.coli cultureto be obtained. The E.coli-derived FPT demonstrated an activitycomparable to that of protein isolated from other sources. Thereported expression system was used to construct three ß-subunitC-terminal truncation mutants, 5, 10 and 14, which were designedto eliminate a lattice interaction between the ß-subunitC-terminus of one molecule and the active site of a symmetry-relatedmolecule. Steady-state kinetic analyses of these mutants showedthat deletion up to 14 residues at the C-terminus did not reducethe value of k_cat; however, K_m values for both peptide and FPPincreased 2–3-fold. A new crystalline form of FPT was obtainedfor the 10 C-terminal mutant grown in the presence of the substrateanalogs acetyl-Cys-Val-Ile-Met-COOH peptide and -hydroxyfarnesylphosphonicacid. The crystals diffract to beyond 2.0 Å resolution.The refined structure clearly shows that both substrate analogsadopt extended conformations within the FPT active site cavity.     

Replacing the ({beta}{alpha})-unit 8 of E.coli TIM with its chicken homologue leads to a stable and active hybrid enzyme

In order to investigate how structural modifications interferewith protein stability, we modified a (ß)-unit inE.coli triosephosphate isomerase (TIM), a typical (ß)-barrelprotein, assuming that the pseudosymmetrical ß-barrelcan be divided into eight successive loop/ß-strand/loop/-helixmotifs. We replaced the eighth (ß)-unit of E.coliTIM with the corresponding chicken (ß)-unit. The substitution,involving the replacement of 10 of the 23 residues of this (ß)-unit, was evaluated first by modelling, then experimentally.Modelling by bomology suggests how the amino add replacementsmight be accommodated in the hybrid E.coli/chicken TIM (ETCM8CHI).Both natural and hybrid recombinant TIMs, overproduced in E.coli,were purified to homogeneity and characterized as to their stabilityand kinetics. Our kinetic studies show that the modificationperformed here leads to an active enzyme. The stability studiesindicate that the stability of ETIM8CHI is comparable to thatof the wild type TIM.