An engineered Staphylococcus aureus PCI {beta}-lactamase that hydrolyses third-generation cephalosporins

The ß-lactamase from Staphylococcus aureus PCI hasbeen cloned into an Escherichia coli vector for site-directedmutagenesis and high-level protein expression. A mutant enzymehas been produced in which Ala238 is replaced by a serine, andIle239 is deleted (A238S:I239del). The engineered enzyme hydrolysesthird-generation cephalosporins substantially more rapidly thanthe parental enzyme does, while hydrolysis of benzylpenicillinis slower with the mutant than with the wild-type and nativeenzymes. The mutant P-lactamase has been crystallized and thestructure determined and refined at 2.8 A resolution. The dispositionof the ß-strand which forms the side of the activesite is altered in comparison with the native S.aureus ß-lactamasestructure, widening the active site cleft and providing spaceto accommodate the bulky side-chains of the third-generationcephalosporins.     

Estimating the twist of {beta}-strands embedded within a regular parallel {beta}-barrel structure

The parallel ß-barrel is a recurrent structural motiffound in a large variety of different enzymes belonging to thefamily of /ß-proteins. It has been shown previouslythat the hyperboloid can be considered as a scaffold describingthe parallel ß-barrel structure. To assess restraintson ß-strand twist imposed by a given scaffold geometry,the notion of scaffold twist, T_s, is introduced. From T_s, theß-strand twist (Tw_ß) expected for a givenscaffold geometry can be derived and it is verified that thiscomputed twist can be used to identify ß-barrels characterizedby good hydrogen bonding. It is noted that Tw_ß isonly slightly affected for ß-barrels differing inthe number (N) of ß-strands, suggesting that restraintson main-chain conformation of ß-strands are not likelyto account for the N = 8 invariability observed in natural parallelß-barrels thereby strengthening previous work rationalizingthis constancy.     

The elusive role of the N-terminal extension of {beta}A3- and {beta}Al-crystallin

ß-Crystallins are structural lens proteins with aconserved two-domain structure and variable N- and C-terminalextensions. These extensions are assumed to be involved in quaternaryinteractions within the ß-crystallin oligomers orwith other lens proteins. Therefore, the production of ßA3-and ßAl-crystallin from the single ßA3/A1mRNA by dual translation initiation is of interest. These crystallinsare identical, except that ßAl has a much shorterN-terminal extension than ßA3. This rare mechanismhas been conserved for over 250 million years during the evolutionof the ßA3/A1 gene, suggesting that the generationof different N-terminal extensions confers a selective advantage.We therefore compared the stability and association behaviourof recombinant ßA3- and ßAl-crystallin.Both proteins are equally stable in urea- and pH-induced denaturationexperiments. Gel filtration and analytical ultracentrifugationestablished that ßA3 and ßA1 both form homodimers.In the water-soluble proteins of bovine lens, ßA3and ßA1 are present in the same molecular weight fractions,indicating that they oligomerize equally with other ß-crystallins.¹H-NMR spectroscopy showed that residues Met1 to Asn22 of theN-terminal extension of ßA3 have great flexibilityand are solvent exposed, excluding them from protein interactionsin the homodimer. These results indicate that the differentN-terminal extensions of ßA3 and ßA1 donot affect their homo- or heteromeric interactions.     

Predicted {beta}-structure stability parameters under experimental test

Recently, ß-structure stability parameters have beenmeasured for all 20 natural amino acids, separately for theedge and separately for the internal ß-sheet positions.Theoretical estimations of all these stability parameters havebeen obtained earlier on the basis of the molecular theory.Comparison shows a good concordance between the recent experimentalresults and the earlier theoretical predictions.     

Alcohol-induced changes of {beta}-lactoglobulin - retinol-binding stoichiometry

It has been demonstrated using CD that ethanol induces importantsecondary structure changes of ß-lactoglobulin. CDspectra indicate that ß-lactoglobulin secondary structure,which is mainly composed of ß-strands, becomes mostly-helical under the influence of the solvent polarity changes.The midpoint of ß-strand/-helix transition in ß-lactoglobulinis observed at dielectric constant {small tilde}60 (35% ethanol;v/v). According to CD measurements, the ethanol-dependent secondarystructure changes are reversible. The alkylation of lysines-NH₂ in ß-lactoglobulin weakens the central ß-barrelstructure, since the ß-strand/-helix transition midpointof alkylated ß-lactoglobulin is shifted to lower ethanolconcentration (25% ethanol; v/v). ß-Lactoglobulinstructural changes are triggering the dissociation of the ß-lactoglobulin- retinol complex as judged from complete quenching of its fluorescencein ethanol concentration >30% (v/v). However, in 20% ethanol(v/v), ß-lactoglobulin still retains most of its nativesecondary structure as shown by CD and, in this condition, oneß-lactoglobulin molecule binds an additional secondretinol molecule. This suggests that the highly populated speciesobserved around 20% ethanol (v/v) might represent an intermediatestate able to bind two molecules of retinol.     

Thermostable variants of bovine {beta}-lactoglobulin

The thermal stability of bovine ß-lactoglobulin (BLG)has been enhanced by the introduction of an additional disulfidebond. Wild-type BLG has two disulfide bonds, C106–C119and C66–C160, with a free cysteine at position 121. Wehave designed, with the aid of molecular modeling calculations,two mutants of a recombinant BLG (rBLG), L104C and A132C. Moleculardynamics simulations were performed at 300K to study the effectof these alterations on the conformation of the protein. Thesemutants were then created by site-directed mutagenesis and purifiedfrom Escherichia coli carrying a tac expression vector usinga two-step renaturation method. Formation of disulfide linkagesin the correct arrangement, as designed, was confirmed by peptidemapping. In contrast to wild-type rBLG, which polymerizes attemperatures >65°C, neither of the mutant proteins polymerized.The conformational stability of the L104C and A132C mutant proteinsagainst thermal denaturation has been substantially increased(8- 10°C) as compared with wild-type rBLG. Furthermore,the A132C rBLG exhibits an enhanced stability against denaturationby guanidine hydrocnloride as compared with the wild-type orL104C rBLG     

Secondary structure characterization of {beta}-lactamase inclusion bodies

The secondary structure of proteins in E.coli inclusion bodieswas investigated via Raman spectroscopy. Inclusion bodies werepurified from cells expressing different forms of RTEM ß-lactamaseand grown at either 37 or 42° C. All of the solid phaseinclusion body samples examined gave amide I band spectra thatwere perturbed from that of the native, purified protein inboth solution and powder forms; secondary structure estimatesindicated significant decreases in a-helix and increases inß-sheet contents in the inclusion body samples. The structureestimates for inclusion bodies isolated from 37°C cultureswere similar, regardless of aggregate localization in the E.colicytoplasmic or periplasmic spaces or ß-lactamase precursorcontent. Inclusion bodies obtained from 42°C cells exhibiteda further reduction of ß-helix and augmentation of ß-sheetcontents relative to those from 37°C cultures. These resultsare consistent with the paradigm for inclusion body formationvia the self-association of intra-cellular folding intermediateshaving extensive secondary structure content. Further, the overallsecondary structure content of inclusion bodies is not significantlyaffected by subcellular compartmentalization, but may be alteredat increased temperatures     

Insertion of an elastase-binding loop into interleukin-1{beta}

The protease-binding sequence EAIPMSIPPE from 1-antitrypsinhas been inserted into the cytokine interleykin-1ß,replacing residues 50–53. The resulting mutant proteinwas cleaved specifically at a singly site by elastase and chymotrypsin,but not by trypson. The cleavage by elastase was shown to bebetween Met and Ser of the inserted loop. In contrast, wild-typeinterleukin is not sus-ceptible to cleavage by any of theseenzymes. The mutant protein acts as an inhibitor of elastase,with a K1 of 30 µM. The wild type displays no such inhibitoryactitvity. The overall structure of the mutant, as demonstratedbyu CD, appears to be indistinguishabel from that fo the wildtype. These results indicate that the protease-binding regionfo 1-antitrypson can be recognized and is active even withinthe context of an entirely differentproteinstructure. Giventhat interleukinm-1ß binds to, and is intenalizedby, many types of cells, this hybrid protein also demonstratesthe feasibility of using interleukin-1ß as a deliverysystem for useful therapeutic agents.     

Molecular dynamics simulations of the whey protein {beta}-lactoglobulin

Molecular dynamics simulations have been used to model the motionsand conformational behavior of the whey protein bovine ß-lactoglobulin.Simulations were performed for the protein by itself and complexedto a single retinol ligand located in a putative interior bindingpocket. In the absence of the retinol ligand, the backbone loopsaround the opening of this ulterior pocket shifted inward topartially close off this cavity, similar to the shifts observedin previously reported molecular dynamics simulations of theuncomplexed form of the homologous retinol binding protein.The protein complexed with retinol does not exhibit the sameconformational shifts. Conformational changes of this type couldserve as a recognition signal allowing in vivo discriminationbetween the free and retinol complexed forms of the 3-lactoglobulinmolecule. The unusual bending of the single a-helix observedin the simulations of retinol binding protein were not observedin the present calculations     

Automating the identification and analysis of protein {beta}-barrels

ßBarrels are widespread and well-studied featuresof a great many protein structures. In this paper an unsuper-visedmethod for the detection of P-barrels is developed based ontechniques from graph theory. The hydrogen bonded connectivityof ß-sheets is derived using standard pattern recognitiontechniques and expressed as a graph. Barrels correspond to topologicalrings in these connectivity graphs and can thus be identifiedusing ring perception algorithms. Following from this, the characteristictopological structure of a barrel can be expressed using a novelform of reduced nomenclature that counts sequence separationsbetween successive members of the ring set These techniquesare tested by applying them to the detection of barrels in anon-redundant subset of the Brookhaven database. Results indicatethat topological rings do seem to correspond uniquely to ß-barrelsand that the technique, as implemented, finds the majority ofbarrels present in the dataset.     

6-Phospho-{beta}-galactosidases of Gram-positive and 6-phospho-{beta}-glucosidase B of Gram-negative bacteria: comparison of structure and function by kinetic and immunological methods and mutagenesis of the lacG gene of staphylococcus aureus

The 6-phospho-ß-galactosidase of Staphylococcus aureus,Lactococcus lactis and Lactobacillus casei and 6-phospho-ßglucosidaseB of Escherichia coli build a subfamily inside a greater enzymefamily, named the glycosal hydrolase family 1, which, hi addition,contains nine ß-glycosidases of different origins.Kinetic and immunological evidence is provided in this reportwhich strengthens the relationship of the four 6-phospho-ß-glycosidases.It is shown that the 6-phospho-ß-galactosidases and6-phospho-ß-glucosidase B are able to split aromaticß-galactoside phosphates and ß-glucosidephosphates. The turnover numbers of hydrolysis of substrateswith different epimerization at C-4 of the glycon vary up to15-fold only. Two polydonal antisera, one derived against thenative 6-phospho-ß-galactosidase from S.aureus andthe other derived against the 6-phospho-ß-glucosidaseB, cross-reacted with both enzymes. Peptides of the proteinswere separated by reverse phase HPLC. The cross-reacting peptideswere sequenced and shown to be localized at almost the sameposition in the aligned primary structures of both enzymes.An insertion of nine amino adds near these antigenic domainsis unique for the 6-phospho-ß-glycosidases and missingwithin the sequences of the ß-glycoside-specific membersof the family. The lacG gene of a 6-phospho-ß-galactosidasenegative S.aureus mutant was doned into E.coli and sequenced.In the totally inactive mutant protein only the glycine at position332 was changed to an arginine. This amino acid is part of thesequence insertion near the antigenic domain reacting with bothantisera. These data support the assumption that the regionis of great importance for the function of the enzymes and thatit is possible it determines the specificity of the phosphorylatedform of the substrates. In addition, the 6-phospho-ß-galactosidaseof S.aureus was modified by sitedirected mutagenesis of thecorresponding lacG gene hi order to replace residues Glul60and Glu375, which were suspected of being involved hi the generalacid catalysis of substrate hydrolysis, with glutamine residues.The mutant protein 160EQ retained some catalytic activity whilethe protein 375EQ was totally inactive. Glu375 is the activesite nudeophile of the 6-phospho-ß-galactosidase ofS.aureus. It is located in the sequence motif ENG where Glu358was identified as the catalytkally active nudeophile hi theß-glucosidase of Agrobacterium.     

Analysis and prediction of inter-strand packing distances between {beta}-sheets of globular proteins

Any two ß-strands belonging to two different ß-sheetsin a protein structure are considered to pack interactivelyif each ß-strand has at least one residue that undergoesa loss of one tenth or more of its solvent contact surface areaupon packing. A data set of protein 3-D structures (determinedat 2.5 Å resolution or better), corresponding to 428 proteinchains, contains 1986 non-identical pairs of ß-strandsinvolved in interactive packing. The inter-axial distance betweenthese is significantly correlated to the weighted sum of thevolumes of the interacting residues at the packing interface.This correlation can be used to predict the changes in the inter-sheetdistances in equivalent ß-sheets in homologous proteinsand, therefore, is of value in comparative modelling of proteins.     

Identification of two glutamic acid residues essential for catalysis in the {beta}-glycosidase from the thermoacidophilic archaeon Sulfolobus solfataricus

The Sulfolobus solfataricus, strain MT4, ß-glycosidase(Ssßgly) is a thermophilic member of glycohydrolasefamily 1. To identify active-site residues, glutamic acids 206and 387 have been changed to isosteric glutamine by site-directedmutagenesis. Mutant proteins have been purified to homogeneityusing the Schistosoma japonicum glutathione S-transferase (GST)fusion system. The proteolytic cleavage of the chimeric proteinwith thrombin was only obtainable after the introduction ofa molecular spacer between the GST and the Ssß-glydomains. The Glu387 Gin mutant showed no detectable activity,as expected for the residue acting as the nucleophile of thereaction. The Glu206 Gin mutant showed 10- and 60-fold reducedactivities on aryl-galacto and aryl-glucosides, respectively,when compared with the wild type. Moreover, a significant K_mdecrease with plo-nitrophenyl-ß-D-glucoside was observed.The residual activity of the Glu206 Gln mutant lost the typicalpH dependence shown by the wild type. These data suggest thatGlu206 acts as the general acid/base catalyst in the hydrolysisreaction.     

On the use of machine learning to identify topological rules in the packing of {beta}-strands

The machine learning program GOLEM was applied to discover topologicalrules in the packing ofß-sheets in /ß-domainproteins. Rules (constraints) were determined for four featuresof ß-sheet packing: (i) whether a ß-strandis at an edge; (ii) whether two consecutive ß-strandspack parallel or anti-parallel; (iii) whether twoß-strandspack adjacently; and (iv) the winding direction of two consecutiveß-strands. Rules were found with high predictive accuracyand coverage. The errors were generally associated with complicationsin domain folds, especially in one doubly wound domains. Investigationof the rules revealed interesting patterns, some of which wereknown previously, others that are novel. Novel features include(i) the relationship between pairs of sequential strands isin general one of decreasing size; (ii) more sequential pairsof strands wind in the direction out than in; and (iii) it takesa larger alteration in hydrophobicity to change a strand fromwinding in the direction out than in. These patterns in thedata may be the result of folding pathways in the domains. Therules found are of predictive value and could be used in thecombinatorial prediction of protein structure, or as a generaltest of model structures, e.g. those produced by threading.We conclude that machine learning has a useful role in the analysisof protein structures.     

Display of {beta}-lactamase on the Escherichia coli surface: outer membrane phenotypes conferred by Lpp'-OmpA'-{beta}-lactamase fusions

Bacterial cell-surface exposure of foreign peptides and solubleproteins has been achieved recently by employing a fusion proteinmethodology. An Lpp'–OmpA(46–159)–Bla fusionprotein has been shown previously to display the normally periplasmicenzyme ß-lactamase (Bla) on the cell surface of theGram-negative bacterium Escherichia coli. Here, we have investigatedthe role of the OmpA domain of the tripartite fusion proteinin the surface display of the passenger domain (Bla) and havecharacterized the effects of the fusion proteins on the integrityand permeability of the outer membrane. We show that in additionto OmpA(46–159), a second OmpA segment, consisting ofamino acids 46–66, can also mediate the display of Blaon the cell surface. Other OmpA domains of various lengths (aminoacids 46–84, 46–109, 46–128, 46–141and 46–145) either anchored the Bla domain on the periplasmicface of the outer membrane or caused a major disruption of theouter membrane, allowing the penetration of antibodies intothe cell. Detergent and antibiotic sensitivity and periplasmicleakage assays showed that changes in the permeability of theouter membrane are an unavoidable consequence of displayinga large periplasmic protein on the surface of E.coli. This isthe first systematic report on the effects that cell surfaceengineering may have on the integrity and permeability propertiesof bacterial outer membranes.     

The {alpha}/{beta} hydrolase fold

We have identified a new protein fold—the /ßhydrolase fold—that is common to several hydrolytic enzymesof widely differing phylogenetic origin and catalytic function.The core of each enzyme is similar: an /ß sheet, notbarrel, of eight ß-sheets connected by -helices. Theseenzymes have diverged from a common ancestor so as to preservethe arrangement of the catalytic residues, not the binding site.They all have a catalytic triad, the elements of which are borneon loops which are the best-conserved structural features inthe fold. Only the histidine in the nucleophile-histidine-acidcatalytic triad is completely conserved, with the nucleophileand acid loops accommodating more than one type of amino acid.The unique topological and sequence arrangement of the triadresidues produces a catalytic triad which is, in a sense, amirror-image of the serine protease catalytic triad. There arenow four groups of enzymes which contain catalytic triads andwhich are related by convergent evolution towards a stable,useful active site: the eukaryotic serine proteases, the cysteineproteases, subtilisins and the /ß hydrolase fold enzymes.     

A mutational analysis of receptor binding sites of interleukin-1{beta}:differences in binding of human interleukin-1{beta} muteins to human and mouse receptors

The 3-D crystal structure of interleukin-1ß(IL-1ß)has been used to define its receptor binding surface by mutationalanalysis. The surface of IL-1ß was probed by site-directedmutagenesis. A total of 27 different IL-1ß muteinswere constructed, purified and analyzed. Receptor binding measurementson mouse and human cell lines were performed to identify receptoraffinities. IL-1ß muteins with modified receptor affinitywere evaluated for structural integrity by CD spectroscopy orX-ray crystallography. Changes in six surface loops, as wellas in the C- and N-termini, yielded muteins with lower bindingaffinities. Two muteins with intact binding affinities showed10- to 100-fold reduced biological activity. The surface regioninvolved in receptor binding constitutes a discontinuous areaof 1000 Å2 formed by discontinuous polypeptide chain stretches.Based on these results, a subdivision into two distinct localareas is proposed. Differences in receptor binding affinitiesfor human and mouse receptors have been observed for some muteins,but not for wild-type IL-1ß. This is the first timea difference in binding affinity of IL-1ß muteinsto human and mouse receptors has been demonstrated     

The role of the sequence extensions in {beta}-crystallin assembly

The modular construction of the eye lens ß-crystallinsmakes them good candidates for protein engineering to ascertainthe rules of assembly of oligomers. X-ray studies have shownthat although the polypeptide chains of ßB2-crystallinand -crystallins fold to form similar N- and C-terminal domains,the conformation of the connecting peptides are such that the-crystallins are monomers and the ß-crystallin isa dimer. Unlike -crystallins, the numerous -crystallins haveextensions of variable sequence from the globular domains. Wehave tested the effect of removing the N- and C-terminal extensionsfrom rat ßB2-crystallin using a bacterial expressionsystem. Abundant proteins were produced in Escherichia coliusing the pET or pQE vectors. Full-length and truncated proteinswere purified and checked for refolding using circular dichroism.Sizing of the truncated proteins using gel filtration chroma-tographyshowed that the absence of either the N- or C-terminal extensiondoes not affect dimerization of ßB2-crystallin.     

Strong inhibition of fibrinogen binding to platelet receptor {alpha}IIb{beta}3 by RGD sequences installed into a presentation scaffold

In order to probe the structural constraints on binding of RGDsequences to the platelet receptor _IIbß₃ we have usedrecombinant DNA techniques to install the RGD sequence into‘presentation scaffolds’, small proteins of known3-D structure chosen to present guest sequences in constrainedorientations. Using Escherichia coli expression systems we madesequence variants in which loop residues of the immunoglobulinV_L domain REI and of human interleukin-1ß were replaced(without changing polypeptide length) by the RGD sequence atpositions predicted, based on small molecule studies, to orientthe RGD moiety into an active conformation. These variants donot compete for fibrinogen binding to _IIbß₃ up toalmost 1 mM concentration. Unfolded or proteolytically fragmentedforms of these same proteins do compete, however, showing thatthe RGD sequences in the mutants must be prohibited from bindingby constraints imposed by scaffold structure. To suppress theeffects of such structural constraints we constructed two sequencevariants in which RGD-containing sequences 42–57 or 44–55from the snake venom platelet antagonist kistrin were inserted(this increasing the length of the loop) into the third complementaritydetermining loop of REI. Both of these variants compete stronglyfor fibrinogen binding with IC₅₀s in the nM range. These results,plus data on kistrin-related peptides also presented here, suggestthat the molecular scaffold REI is capable of providing to aninstalled sequence a structural context and conformation beneficialto binding. The results also suggest that in order to bind wellto _IIbß₃, RGD sequences in protein ligands must eitherproject significantly from the surface of the scaffold and/orretain a degree of conformational flexibility within the scaffold.Molecular scaffolds like REI should prove useful in the elucidationof structure-function relationships and the discovery of newactive sequences, and may also serve as the basis for noveltherapeutic agents.     

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.