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     

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.     

Cloning of rabbit interleukin-1{beta}: differential evolution of IL-1{alpha} and IL-1{beta} proteins

We have cloned the rabbit IL-1ß cDNA, which encodesa 268 amino acid precursor similar in length to other sequencedIL-1 precursors. Comparison of all published IL-1 and IL-1ßsequences respectively indicates that the IL-1 gene family isevolving faster than the IL-1ß family, and that thetwo genes diverged –270 million years ago. Surprisingly,there are differences in the regions preferentially conservedwithin the two families. The IL-1 family is most conserved atthe amino terminus whereas the IL-1ß family is mostconserved in the carboxy-terminal half. This is despite thefact that the carboxy-terminal half encodes the active portionof both molecules and would be expected to adopt a similar ß-sheetstructure in IL-1 as in the published X-ray structure of matureIL-1ß. These findings suggest that differences inthe function and properties of the IL-1 and IL-1ßprecursor molecules may have been conserved. These differencesmay therefore provide an explanation for the existence of twoIL-1 molecules.     

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.     

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.     

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.     

Independent self-assembly of cadmium-binding {alpha}-fragment of metallothionein in Escherichia coli without participation of {beta}-fragment

We examined the independent self-assembly of the - and ß-fragmentsof human metallothionein (MT) into cadmiumbinding conformationin an Escherichia coli expression system, in addition to wild-typeMT expression. The expressed -fragment formed independentlythe structure of a metal-binding cluster without the aid ofthe ß-fragment. The -fragment and wild-type MT expressedin E.coli were purified and analyzed for their biochemical andspectroscopic properties. The apparent cadmium binding of the-fragment was approximately 12-fold greater than that for thewild-type MT, whereas in other respects the studied biochemicalproperties were similar. In contrast, we were unable to obtainany independently expressed ß-fragment as the cadmium-bindingform in this study. Possible explanations for this phenomenonare discussed.     

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.     

The crystal structure of {alpha}-bungarotoxin at 2.5 ? resolution: relation to solution structure and binding to acetylcholine receptor

We report collection of 2.5 ? resolution X-ray diffraction datafrom newly grown crystals of the rare ‘small unit cell’form of the long snake neurotoxin, -bungarotoxin. The previousmodel of the molecule has been rebuilt, and refined using least-squaremethods to a crystallographic residual of 0.24 at 2.5 ? resolution.-Bungarotoxin's crystal structure is compared with the crystalstructures of two other snake neurotoxins (cobratoxin and erabutoxin),and with its solution structure inferred from spectroscopicstudies. Significant differences include less ß-sheetin bungarotoxm's crystal structure than in solution, or in thecrystal structures of other neurotoxins, and an unusual orientationin the crystal of the invariant tryptophan. The functional,binding surface of bungarotoxin is described; it consists primarilyof hydrophobic and hydrogen-bonding groups and only a few chargedside chains. The structure is compared with experimental bindingparameters for neurotoxins.     

{beta}-sheet folding of fragment (16-36) of bovine pancreatic trypsin inhibitor as predicted by Monte Carlo simulated annealing

A tertiary structure prediction is described using Monte Carlosimulated annealing for the peptide fragment corresponding toresidues 16–36 of bovine pancreatic trypsin inhibitor(BPTI). The simulation starts with randomly chosen initial conformationsand is performed without imposing experimental constraints usingenergy functions given for generic interatomic interactions.Out of 20 simulation trials, seven conformations show a sheet-likestructure—two strands connected by a turn—althoughthis sheet-like structure is not as rigid as that observed innative BPTI. It is also shown that these conformations are mostlylooped and exhibit a native- like right-handed twist. Unlikethe case with the C-peptide of RNase A, no conspicuous -helicalstructure is found in any of the final conformations obtainedin the simulation. However, the lowest-energy conformation doesnot resemble exactly the native structure. This indicates thatthe rigid ß-sheet conformation of native BPTI merelycorresponds to a local minimum of the energy function if thefragment with residues 16–36 is isolated from the nativeprotein. A statistical analysis of all 20 final conformationssuggests that the tendency for the peptide segments to formextended ß-strands is strong for those with residues18–24, and moderate for those with residues 30–35.The segment of residues 25–29 does not tend to form anydefinite structure. In native BPTI, the former segments areinvolved in the ß-sheet and the latter in the turn.A folding scenario is also speculated from this analysis.     

Solution structure and dynamics of a serpin reactive site loop using interleukin 1 as a presentation scaffold

Human interleukin-1ß (IL1ß) was used as a presentationscaffold for the characterization of the reactive site loop(RSL) of the serpin 1-antitrypsin (A1AT), the physiologicalinhibitor of leukocyte elastase. A chimeric protein was generatedby replacement of residues 50–53 of IL1ß, correspondingto an exposed reverse turn in IL1ß, with the 10-residueP5-P5' sequence EAIPMSIPPE from A1AT. The chimera (antitrypsin-interleukin,AT-IL) inhibits elastase specifically and also binds the IL1ßreceptor. Multinuclear NMR characterization of AT-IL establishedthat, with the exception of the inserted sequence, the structureof the IL1ß scaffold is preserved in the chimera. Thestructure of the inserted RSL was analyzed relative to thatof the isolated 10-residue RSL peptide, which was shown to beessentially disordered in solution. The chimeric RSL was alsofound to be solvent exposed and conformationally mobile in comparisonwith the IL1ß scaffold, and there was no evidence of persistinginteractions with the scaffold outside of the N- and C-terminallinkages. However, AT-IL exhibits sigificant differences inchemical shift and NOE patterns relative to the isolated RSLthat are consistent with local features of non-random structure.The proximity of these features to the P1-P1' residues suggeststhat they may be responsible for the inhibitory activity ofthe chimera.     

Synthesis, purification and initial structural characterization of octarellin, a de novo polypeptide modelled on the {alpha}/{beta}-barrel Proteins

We have attempted to construct an artificial polypeptide thatfolds like the eight-stranded parallel ß-barrel structures.Our approach consists of repeating eight times a unit peptidedesigned to adopt a ‘ß-strand/-helix’pattern. A first ‘test’ sequence for this structuralunit was deduced from a series of parameters defined after ananalysis of three natural /ß-barrel proteins and includingprincipally the lengths of the secondary structure elements,the /ß packing and the fitting on average Garnierprofiles. The gene encoding this structural unit was synthesized,cloned and expressed in Escherichia coli either as a monomeror as direct repeats of 2–12 units. Preliminary structuralcharacterization of the 7-, 8- and 9-fold unit polypeptidesby circular dichroism measurements indicates the presence ofthe predicted amount of -helix in the three proteins. Furtheranalysis by urea-gradient gel electrophoresis demonstrates that,in the conditions tested, only the 8-fold unit polypeptide formsa compact structure through a cooperative and rapid two-statefolding transition involving long-range molecular interactions.     

Second-generation octarellins: two new de novo ({beta}/{alpha})8 polypeptides designed for investigating the influence of {beta}-residue packing on the {alpha}/{beta}-barrel structure stability

The sequence of octarellin I, the first de novo (ß/)₈polypeptide, was revised according to several criteria, amongothers the symmetry of the sequence, ß-residue volumeand hydrophobicity, and charge distribution. These considerationsand the overall conclusions drawn from the first design ledto two new sequences, corresponding to octarellins II and III.Octarellin II retains perfect 8-fold symmetry. Octarellin IIIhas the same sequence as octarellin II, except for the ß-strandswhich exhibit a 4-fold symmetry. The two proteins were producedin Escherichia coli. Infrared and CD spectral analyses of octarellinsII and III reveal a high secondary structure content. Non-denaturinggel electrophoresis, molecular sieve chromatography and analyticalultracentrifugation suggest that both of these second-generationartificial polypeptides exist as a mixture of a monomer anda dimer form. Octarellins II and III are at least 10 times moresoluble than octarellin I. Ureainduced unfolding followed byfluorescence emission suggests that the tryptophan residues,designed to be buried in the (ß/)₈, are indeed packedin the hydrophobic core of both proteins. However, octarellinIII displays a higher stability towards urea denaturation, indicatingthat introducing 4-fold symmetry into the ß-barrelmight be important for stability of the overall folding.     

Functionally essential, invariant glutamate near the C-terminus of strand {beta}5 in various ({alpha}/{beta})8-barrel enzymes as a possible indicator of their evolutionary relatedness

Twelve different (/ß)₈-barrel enzymes belonging tothree structurally distinct families were found to contain,near the C-terminus of their strand ß5, a conservedinvariant glutamic acid residue that plays an important functionalrole in each of these enzymes. The search was based on the ideathat a conserved sequence region of an (/ß)₈-barrelenzyme should be more or less conserved also in the equivalentpart of the structure of the other enzymes with this foldingmotif owing to their mutual evolutionary relatedness. For thispurpose, the sequence region around the well conserved fifthß-strand of a-amylase containing catalytic glutamate(Glu230, Aspergillus oryzae -amylase numbering), was used asthe sequence-structural template. The isolated sequence stretchesof the 12 (/ß)₈-barrels are discussed from both thesequence-structural and the evolutionary point of view, theinvariant glutamate residue being proposed to be a joining featureof the studied group of enzymes remaining from their ancestral(/ß)₈-barrel     

Structure-function analysis of human IL-1{alpha}: identification of residues required for binding to the human type I IL-1 receptor

Using oligonucleotide-directed mutagenesis, the binding siteon human interleukin-1 (IL-1) for the human type I IL-1 receptor(IL-1R) has been analyzed. Substitution of seven amino acids(Arg12, Ile14, Asp60, Asp61, Ile64, Lys96 and Trp109) resultedin a significant loss of binding to the receptor. Based on crystallographicinformation, the side chains of these residues are clusteredin one region of IL-1 and exposed on the surface of the protein.Five of the residues in the IL-1 binding site align with thebinding residues previously determined in human IL-1ß,demonstrating that the type I IL-1R recognizes homologous regionsin both ligands. Unexpectedly, only three of the aligned residuesare identical between IL-1 and IL-1ß. These observationssuggest that the composition of contact residues in the bindingsite is unique for each ligand–receptor complex in theIL-1 system.     

Expression of deletion constructs of bovine {beta}-1, 4-galactosyltransferase in Escherichia coli: importance of Cysl34 for its activity

Bovine ß-1, 4-galactosyltransferase (ß-1,4-GT; EC 2.4.1.90 [EC] ) belongs to the glycosyltransferase familyand as such shares a general topology: an N-terminal cytoplasmictail, a signal anchor followed by a stem region and a catalyticdomain at the C-tenninal end of the protein. cDNA constructsof the N-terminal deleted forms of ß-1, 4-GT wereprepared in pGEX-2T vector and expressed in E.coli as glutathione-S-transferase(GST) fusion proteins. Recombinant proteins accumulated withininclusion bodies as insoluble aggregates that were solubilizedin 5 M guanidine HCl and required an ‘oxido-shuffling’reagent for regeneration of the enzyme activity. The recombinant(ß-1, 4-GT, devoid of the GST domain, has 30–85%of the sp. act. of bovine milk ß-1, 4-GT with apparentK_ms for N-acetylglucosamine and UDP-galactose similar to thoseof milk enzyme. Deletion analysesshow that both (ß-1,4-GT and lactose synthetase activities remain intact even inthe absence of the first 129 residues (pGT-dl29). The activitiesare lost when either deletions extend up to residue 142 (pGT-dl42)or Cysl34 is mutatedto Ser (pGT-dl29C134S). These results suggestthat the formation of a disulfide bond involving Cysl34 holdsthe protein in a conformation that is required for enzymaticactivity.     

Search for the most stable folds of protein chains: II. Computation of stable architectures of {beta}-proteins using a self-consistent molecular field theory

In a preceding paper we presented a novel approach to computationof 3-D folds of protein chains from their amino acid sequences.This approach is a physically correct generalization of the‘threading’ methods. It is based on a self-consistentmolecular field theory and on a physical theory of protein foldingpatterns, which make it possible to examine all the varietyof ‘potentially stable’ folding patterns and allthe variety of the chain conformations within each of them andto determine the thermodynamically stable structure. In thispaper, we apply this approach to single out stable folding patternsand conformations for the chains of ß-sandwich proteinsand show that the similarity of the calculated and observedstructures is usually rather close.     

Spectroscopic investigation of structure in octarellin (a de novo protein designed to adopt the {alpha}/{beta}-barred packing)

We present here a spectroscopic structural characterizationof octarellin, a recently reported de novo protein modelledon /ß-barrel proteins [K. Go raj, A.Renard and J.A.Martial(1990) Protein Engng, 3, 259–266]. Infrared and Ramanspectra analyses of octarellin‘s secondary structure revealthe expected percentage of -helices (30%) and a higher ß-sheetcontent (40%) than predicted from the design. When the Ramanspectra obtained with octarellin and native triosephosphateisomerase (a natural /ß-barrel) are compared, similarpercentages of secondary structures are found. Thermal denaturationof octarellin monitored by CD confirms that its secondary structuresare quite stable, whereas its native-like tertiary fold is not.Tyrosine residues, predicted to be partially hidden from solvent,are actually exposed as revealed by Raman and UV absorptionspectra. We conclude that the attempted /ß-barrelconformation in octarellin may be loosely packed. The criteriaused to design octarellin are discussed and improvements suggested.     

Modular mutagenesis of a TEM-barrel enzyme: the crystal structure of a chimeric E.coli TIM having the eighth {beta}{alpha}-unit replaced by the equivalent unit of chicken TIM

Abstract The crystal structure of a hybrid Escherichia coli triosephosphateisomerase (TIM) has been determined at 2.8 Å resolution.The hybrid TIM (ETIM8CHI) was constructed by replacing the eighthß-unit of E.coli TIM with the equivalent unit of chickenTIM. This replacement involves 10 sequence changes. One of thechanges concerns the mutation of a buried alanine (Ala232 instrand 8) into a phenylalanine. The ETIM8CHI structure showsthat the A232F sequence change can be incorporated by a side-chainrotation of Phe224 (in helix 7). No cavities or strained dihedralsare observed in ETIM8CHI in the region near position 232, whichis in agreement with the observation that ETIM8CHI and E.coliTIM have similar stabilities. The largest CA (C-alpha atom)movements, 3 Å, are seen for the C-terminal end of helix8 (associated with the outward rotation of Phe224) and for theresidues in the loop after helix 1 (associated with sequencechanges in helix 8). From the structure it is not clear whythe k_cat of ETIM8CHI is 10 times lower than in wild type E.coliTIM