Structure of the Functional Form of the Mosquito Larvicidal Cry4Aa Toxin from Bacillus thuringiensis at a 2.8-Angstrom Resolution

The Cry4Aa ${delta}$ -endotoxin from Bacillus thuringiensis is toxic tolarvae of Culex, Anopheles, and Aedes mosquitoes, which arevectors of important human tropical diseases. With the objectiveof designing modified toxins with improved potency that couldbe used as biopesticides, we determined the structure of thistoxin in its functional form at a resolution of 2.8 Å.Like other Cry ${delta}$ -endotoxins, the activated Cry4Aa toxin consistsof three globular domains, a seven- ${alpha}$ -helix bundle responsiblefor pore formation (domain I) and the following two other domainshaving structural similarities with carbohydrate binding proteins:a ß-prism (domain II) and a plant lectin-like ß-sandwich(domain III). We also studied the effect on toxicity of aminoacid substitutions and deletions in three loops located at thesurface of the putative receptor binding domain II of Cry4Aa.Our results indicate that one loop is an important determinantof toxicity, presumably through attachment of Cry4Aa to thesurface of mosquito cells. The availability of the Cry4Aa structureshould guide further investigations aimed at the molecular basisof the target specificity and membrane insertion of Cry endotoxins.

INTRODUCTION

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Introduction

The gram-positive soil bacterium Bacillus thuringiensis subsp.israelensis produces four major insecticidal Cry proteins (Cry4Aa,Cry4Ba, Cry11Aa, and Cyt1Aa) that are toxic to larvae of insectsbelonging to the orders Diptera, Lepidoptera, Coleoptera, andHymenoptera (18, 54). These proteins are of great interest fordevelopment of new bioinsecticides that cause minimal ecologicaldamage and therefore are attractive alternatives to chemicalinsecticides for the control of insect pests. Engineered Crytoxins have potential applications in agriculture and also inthe control of mosquitoes, which are vectors of some importanttropical diseases, like malaria and viral hemorrhagic fevers(54). Cry ${delta}$ -endotoxins occur as protein crystals in sporulatingB. thuringiensis subsp. israelensis. These crystals are producedas inactive protoxin inclusions, which dissolve upon ingestionby insect larvae under the alkaline conditions present in themidgut lumen (54). The soluble Cry protoxin is activated bylarval midgut proteases, which remove the C-terminal half andapproximately 30 residues from the N terminus. This yields anactive and proteolytically resistant fragment which specificallybinds to receptors on the brush border membrane of the insectmidgut epithelium. Conformational changes subsequently allowthe activated toxin to insert into the host cell membrane andform pores. This in turn leads to ion leakage, cell lysis, andinsect death (54).

The crystal structures of the following Cry toxins have beenreported previously: Cry3Aa (42), Cry3Bb (25), Cry1Aa (29),Cry1Ac (41), Cry2Aa (46), and Cry4Ba (7). These toxins exhibitmarkedly different insect specificities in spite of their similarorganizations into three structurally conserved domains. N-terminaldomain I, an amphipathic ${alpha}$ -helical bundle, is responsible formembrane insertion and pore formation (26, 50a, 63, 65). DomainII is composed of antiparallel ß-strands connectedby loops that vary significantly in length and amino acid sequencein different toxins. These loops are therefore thought to participatein receptor binding and hence in determining the specificityof the toxin for insect larvae (5, 35, 51, 57). C-terminal domainIII, a sandwich of two antiparallel ß-sheets, is believedto protect the structural integrity of active toxin moleculesagainst further proteolytic cleavage and to promote target membranepermeabilization (45), and it could also participate in receptorrecognition (11, 39). Nevertheless, the precise sequence ofevents that follow receptor binding by the active toxin, leadingto membrane insertion and cell lysis, remains poorly defined.Extensive conformational changes of the toxin architecture arelikely to be involved, possibly leading to assembly of an oligomerictoxin structure.

Among the Cry toxins, the Cry4Aa and Cry4Ba toxins are the mostclosely related molecules, exhibiting 35% amino acid sequenceidentity (13, 66) (Fig. 1). Despite their similarity, however,these toxins exhibit different levels of toxicity against variousmosquito species. While Cry4Ba is highly toxic to Aedes andAnopheles larvae (vectors of dengue and yellow fever virusesand of malaria, respectively), it exhibits very little activityagainst Culex larvae (vector of West Nile and Japanese encephalitisviruses) (49). By contrast, Cry4Aa toxin exhibits a high levelof toxicity against Culex and Aedes larvae and is slightly lesstoxic to Anopheles larvae (49). In addition, Cry4Aa and Cry4Bashow synergism in vivo against larvae of all three mosquitogenera (2, 49). Because their interacting binding partners atthe insect membrane surface are not known, the molecular basisthat determines the specificity of these toxins has remainedelusive. Recently, the X-ray crystal structure of the B. thuringiensissubsp. israelensis Cry4Ba toxin was published, but the 50 N-terminalresidues (corresponding to helices ${alpha}$ 1 and ${alpha}$ 2) were not visiblein the electron density map, presumably because of proteolysisthat occurred during crystallization (7). Here we report thecrystal structure of the active Cry4Aa single mutant R235Q ata resolution of 2.8 Å. Below we discuss possible mechanismsof membrane pore formation and also the structural determinantsfor the specificity of B. thuringiensis subsp. israelensis Crytoxin in light of site-directed mutagenesis data. Our resultsprovide the first complete view of the three-dimensional structureof a dipteran-specific toxin and underline the importance ofloop 2 of domain II for Cry4Aa toxicity.

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FIG. 1. (A) Schematic representation of the three domains present in the mature Cry4Aa toxin. Amino acids 68 to 679 are visible in the final electron density map. The R235Q mutation, which makes the toxin resistant to further proteolysis, is also indicated. (B) Alignment of the amino acid sequences of the homologous dipteran-specific toxins Cry4Aa and Cry4Ba. Secondary structure elements of Cry4Aa, as determined in this work (using the Pymol program [16]), are indicated above the sequence; ${alpha}$ helices are indicated by rectangles, and ß strands are indicated by arrows. 8a is a short 3₁₀ helical segment. Residue numbers of both toxins are indicated.

MATERIALS AND METHODS

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Materials and Methods

Protein purification and crystallization. The active single-mutant protein Cry4Aa-R235Q was purified andcrystallized as described previously (6). In brief, crystalswere obtained at 23°C by vapor diffusion in hanging dropscontaining the purified protein at a concentration of 3 to 5mg ml^–1, 0.1 M Tris-acetate (pH 7.0), and 0.2 to 0.3 MKH₂PO₄. The crystals belong to space group C222₁ with unit cellparameters a = 91.2 Å, b = 202.1 Å, and c = 98.7Å and contain one endotoxin molecule per asymmetric unit.

Data collection, model building, refinement, and analysis. Synchrotron data collection and molecular replacement calculationsusing the Cry4Ba structure as a search model (PDB code 1W99)have been reported previously (6). Model building was done usingthe O program (34) interspersed with cycles of electron densitymap improvement as described previously (6). Several cyclesof molecular dynamics with a slow cooling protocol using CNS(10) were carried out. The DALI program (30) was used to searchfor similar three-dimensional structures in the PDB and to performa structural comparison with Cry4Ba toxin. An alignment of theamino acid sequences of Cry4A and Cry4B was produced with theMAPS program (http://bioinfo1.mbfys.lu.se/TOP/webmaps.html).Figures 2 to 8 were produced using Pymol (16).

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FIG. 2. Ribbon representations of the Cry4Aa fold. (A) Overall view of the Cry4Aa toxin, which is composed of three domains. Pore-forming domain I is red, putative receptor binding domain II is yellow, and C-terminal domain III is blue. The secondary structure elements of each of the three domains are labeled in panels B to D. Each individual ß-sheet is a different color. See Fig. 1B.

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FIG. 8. Comparison of the structures adopted by the three surface-exposed loops of Cry4Aa and Cry4Ba at the extremity of domain II. Domain II of Cry4Aa is cyan, and domain II of Cry4Ba is yellow. The locations of loops 1, 2, and 3 on domain II are indicated, and close-ups highlight the structural differences in these putative receptor binding regions. With the possible exception of loop 1 of Cry4Ba, which makes several crystalline intermolecular contacts (7), the conformations of the other loops are likely to be determined by intramolecular contacts, not by crystal packing interactions.

Mutagenesis of Cry4Aa. Domain II of Cry4Aa and domain II of Cry4Ba were superimposedusing the LSQKAB program from the CCP4 suite (14) and were displayedusing the O program. Loops 1, 2, and 3 of domain II of Cry4Aawere altered by site-directed mutagenesis to mimic the correspondingloops of Cry4Ba. Site-directed mutagenesis was performed usingQuickChange (Stratagene) according to the manufacturer's instructions.The mutations obtained and primers used are listed in Table1. DNA templates were purified (QIAGEN) and replicated by PCRwith the Expand long-template polymerase (Roche). The PCR productswere digested with Pfu polymerase (Stratagene) at 72°C for10 min to eliminate the single A added by the Taq polymeraseand were digested with DpnI (Stratagene) at 37°C for 4 h.The ligation products (T4 ligase; New England Biolab) were transformedinto Escherichia coli DH5 ${alpha}$ competent cells. All mutations wereconfirmed by DNA sequencing.

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TABLE 1. Sequences of primers used in site-directed mutagenesis

Toxicity assays. Three independent mosquito larvicidal assays were carried outin triplicate with 2-day-old Aedes aegypti larvae and Culexquinquefasciatus larvae (supplied by the mosquito rearing facilityof the Institute of Molecular Biology and Genetics, MahidolUniversity, Nakornpathom, Thailand), as well as Anopheles diruslarvae (supplied by the Armed Forces Research Institute of MedicalSciences, Thailand). The mosquito larvicidal activities of themutant toxins were tested by diluting the toxin inclusions inwater to obtain twofold serial dilutions with concentrationsranging from 12 to 0.125 µg/ml. One milliliter of dilutedinclusions was added to the same volume of water with eitherfive larvae of A. dirus or 10 larvae of A. aegypti or C. quinquefasciatusin each well of tissue culture plates (24-well plate; diameterof each well, 1.7 cm). Proteins extracted from E. coli JM109containing the pMEx8 vector were used as a negative control.Larval mortality was recorded after incubation at 30°C for24 h, and the concentrations of recombinant proteins that resultedin 50% mortality were calculated by a Probit method (24).

RESULTS AND DISCUSSION

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Results and Discussion

Structure refinement and quality of the model. The refinement statistics are shown in Table 2. The final modelcomprises 598 amino acid residues spanning amino acids 68 to679 of the Cry4Aa toxin mature sequence (Fig. 1), 252 watermolecules, and one methyl-2,4-pentanediol molecule from thecryoprotecting buffer (6). Overall, the electron density mapis unambiguous, and the path of the main chain is clearly definedexcept for residues 235 to 244 and 485 to 488, which were omittedfrom the final model. These segments correspond to two exposedloops connecting ${alpha}$ -helices ${alpha}$ 5 and ${alpha}$ 6 and ß-strands ß9and ß10 in domains 1 and 2, respectively. The formerloop is highly susceptible to proteolysis by trypsin-like enzymes(3). Elimination of the latter cleavage site by replacementof Arg-235 with a glutamine residue yielded a single mutantof Cry4Aa (Cry4Aa-R235Q; referred to below as Cry4Aa) that retainedtoxicity for A. aegypti larvae (8). After trypsin digestion,a 65-kDa fragment was obtained, which was crystallized (6) (Fig.1). Thus, the absence of electron density in loop ${alpha}$ 5- ${alpha}$ 6 was probablydue to conformational flexibility, not due to a nick introducedinto the polypeptide chain by proteolysis (see below).

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TABLE 2. Refinement statistics

Overall architecture. The Cry4Aa toxin is a rather compact molecule composed of threedistinct domains and has approximate overall dimensions of 120by 100 by 80 Å. Domain I is a seven-helix bundle. DomainII consists of three antiparallel ß-sheets with twoadditional short helical segments that form a ß-prismstructure. Domain III is an antiparallel ß-sandwichwith the jelly roll topology (Fig. 2).

Pore-forming domain I. Cry4Aa N-terminal domain I (residues 68 to 321) is composedof seven amphipathic helices that are all clearly defined inour final electron density map. The most hydrophobic helix, ${alpha}$ 5, is located centrally and is surrounded by the six remaininghelices. Helix ${alpha}$ 2 is interrupted by a short loop section andthus can be divided into ${alpha}$ 2 and ${alpha}$ 2b, as in Cry3Aa and Cry1Aa (29,42) (Fig. 2). Overall, the organization of domain I is reminiscentof the organization of other pore-forming proteins composedof ${alpha}$ -helices, such as colicin A (48) or hemolysin E from E. coli(64), with which Cry4Aa exhibits distant structural homology.A number of 128 residues of Cry4Aa and hemolysin E can be superimposedwith a residual root mean square deviation of 4.2 Å, givinga Z score of 5.2. Although the architecture of the pore-formingstate of a Cry toxin has not been determined yet, an "umbrellamodel" has been proposed to account for the toxicity. In thismodel, an intermediate state in the reaction pathway consistsof insertion of helices ${alpha}$ 4 and ${alpha}$ 5 into the membrane as a helicalhairpin structure, with the remaining helices lying at the membranesurface (26). This proposed mechanism is supported by the resultsof mutagenesis studies that demonstrated the crucial role ofthese two helices for the toxicity of Cry4Ba (61). It is alsoconsistent with the recent finding that a crystallized Cry4Batoxin that lacks helices 1 and 2 remains toxic (7). Insertionof a hairpin structure into the membrane, leading to pore formation,presumably follows large conformational changes in the toxin,possibly after receptor binding, proteolysis, and/or multimerization,as shown previously for Cry1Ab and Cry1Ac (4, 52, 59). The refoldingof a hydrophobic hairpin motif, primed by a decrease in thepH or contact with the cytoplasmic membrane, could also playa key role in pore formation by other bacterial toxins, includingcolicins, as well as cholera, pertussis, and anthrax toxins(12, 21, 22). In Cry4Aa domain I, a larger number of electrostaticcharges are found at the accessible surface of ${alpha}$ -helices ${alpha}$ 1, ${alpha}$ 6,and ${alpha}$ 7 than at the surface contributed by helices ${alpha}$ 3 and ${alpha}$ 4 (Fig.3). In the present water-soluble structure of Cry4Aa toxin,these electrostatic charges exposed at the surface of ${alpha}$ -helices ${alpha}$ 1, ${alpha}$ 6, and ${alpha}$ 7 are largely neutralized by opposite charges locatedat the surface of the interacting domain II (Fig. 4). Conformationalchanges of the toxin (e.g., upon receptor binding) that woulddisrupt the interface between domains I and II are likely toexpose these electrostatic charges to the solvent. Thus, theirasymmetrical distribution should influence the orientation ofthe toxin molecule as it approaches the target membrane for ${alpha}$ 4- ${alpha}$ 5 hairpin insertion. It is possible that long-range electrostaticinteractions result in an orientation of domain I with helices ${alpha}$ 4 and ${alpha}$ 5 approximately perpendicular to the lipid bilayer, aswas proposed previously by Parker et al. for colicin A (48).Proteolytic cleavage between helices ${alpha}$ 5 and ${alpha}$ 6 of Cry4Aa or Cry4Bawas proposed to trigger the conformational changes requiredto facilitate membrane insertion (3). However, prevention of ${alpha}$ 5- ${alpha}$ 6 interhelical proteolysis by replacement of Arg-203 withAla increases Cry4Ba larvicidal activity in vivo (1, 3). Likewise,deletion of a trypsin cleavage site at position 235 of the Cry4Aasequence by replacement of Arg-235 with a Gln residue does nothave an adverse effect on Cry4Aa in vivo toxicity for A. aegyptilarvae (6). In the Cry4Aa crystal structure, we found no electrondensity accounting for the segment connecting helices ${alpha}$ 5 and ${alpha}$ 6, which is thus presumably flexible. However, we cannot completelyrule out the possibility that in vivo, cleavage at this siteby gut proteases primes the toxin for membrane penetration.

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FIG. 3. Surface representation of the electrostatic potential of pore-forming domain I of Cry4Aa (calculated using Pymol [16]). Positive electrostatic potentials are blue, and negative electrostatic potentials are red. The locations of solvent-exposed ${alpha}$ -helices are indicated. The solvent-accessible surfaces of ${alpha}$ -helices ${alpha}$ 1, ${alpha}$ 6, and ${alpha}$ 7 (A) show relatively higher potential and clear charge separations (including a "basic strip") than ${alpha}$ -helices ${alpha}$ 3 and ${alpha}$ 4 (B). Panel B is a view with domain I rotated 180° along a vertical axis; this has implications for the way that domain I approaches the target cell membrane (see text).

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FIG. 4. "Open book" representation of the interfaces between domains I and II of Cry4Aa and Cry4Ba. The views were obtained by rotating each of the interacting domains approximately 90° around a vertical axis. A hydrophobic patch is visible at the interface between domains I and II. Amino acids L326, I330, Y331, V333, L334, and F336 in Cry4Aa and amino acids F287, I291, Y292, A294, L295, and V296 in Cry4Ba, which are present in this hydrophobic patch, are labeled.

For efficient insertion of the toxin into the target membrane,an ${alpha}$ 4-loop- ${alpha}$ 5 hairpin structure is required (27). Interestingly,the 15-residue ${alpha}$ 4- ${alpha}$ 5 loop of Cry4Aa has a unique structure comparedto other Cry toxins, with several proline residues located atpositions 193, 194, and 196 (Fig. 5). Moreover, cysteine residuespresent at positions 192 and 199 form a disulfide bridge, thusrestricting the flexibility of this potentially mobile segment(Fig. 1 and 5). Both the unique disulfide bridge (Cys192-Cys199)and the proline-rich motif (Pro193-Pro-Asn-Pro196) play essentialroles in Cry4Aa toxin activity, conceivably by maintaining the ${alpha}$ 4- ${alpha}$ 5 loop structural integrity, which may be required for efficientmembrane insertion of the ${alpha}$ 4- ${alpha}$ 5 transmembrane hairpin (58). Furtherstudies of the role of the ${alpha}$ 4- ${alpha}$ 5 hairpin of Cry4Aa by using mutagenesisdemonstrated that the A. aegypti larvicidal activity was completelyabolished when the strictly conserved aromatic residue Tyr-202was replaced by an aliphatic amino acid, while replacement byan aromatic side chain, phenylalanine, did not affect the toxicity(50). This is consistent with the crucial role played by thecorresponding residue Tyr-170 for the larvicidal activity ofthe Cry4Ba toxin (36). Indeed, aromatic Trp and Tyr residuestend to specifically interact with the lipid membrane outerleaflets, as was previously shown structurally for the fusionloops of class II viral envelope glycoproteins (9). A largenumber of hydrophobic residues exposed to solvent are also foundin other pore-forming toxins, including hemolysin E from E.coli (64) and aerolysin (47). These residues were proposed tointeract with hydrophobic lipid tails. A number of conservedaromatic amino acids, including Tyr-202, could interact withthe phospholipid head groups, thus anchoring the toxin nextto the membrane-water interface. A functional analysis of thechannel activities of various Cry toxins has been describedpreviously. Membrane perturbation revealed that the activatedCry4Aa toxin could form ion channels with a conductance of 127pS, a value which is comparable to the values for Cry4Ba ( $~$ 68to 127 pS) (50a) and Cry1Ca ( $~$ 120 pS) (56) but lower than thevalues for Cry1Aa ( $~$ 450 pS) (29) and Cry1Ac ( $~$ 457 pS) (56). Channelsformed by Cry4Aa are cation selective and voltage independent,like the channels induced by other Cry toxins (50a, 55). Unlikethe homologous toxin Cry4Ba, the 65-kDa activated Cry4Aa toxinwas unable to induce the release of entrapped calcein from pureliposomes (W. Pornwaroon, personal communication). The differentcharacteristics of membrane perturbation induced by Cry4Aa andCry4Ba may be related to the striking differences in the lengthand conformation of their ${alpha}$ 4- ${alpha}$ 5 membrane insertion loops.

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FIG. 5. View of the ${alpha}$ 4- ${alpha}$ 5 loop in domain I of Cry4Aa. This segment is thought to play an important role in membrane insertion (see text). At the bottom is a close-up of the region containing the ${alpha}$ 4- ${alpha}$ 5 loop indicated by the rectangle. The final electron density map is displayed at a contour of 1 ${sigma}$ . There is a disulfide bridge between Cys-192 and Cys-199.

Domain II: receptor binding domain. Domain II consists of three antiparallel ß-sheetspacked through formation of a central hydrophobic core. Bothsheet 1 comprising strands ß5, ß2, ß3,and ß4 and sheet 2 (strands ß8, ß7,ß6, and ß9) adopt a "Greek key" topology.Three ß strands, ß1, ß11, andß10, form sheet 3, which is augmented by ${alpha}$ -helix ${alpha}$ 8and a short 3₁₀ helix 8a and adopts a fold similar to that ofother known Cry protein structures (Fig. 2). The interface betweendomains I and II is composed of a mixture of salt bridges, hydrogenbonds, and van der Waals interactions. Since insertion intothe lipid bilayer presumably involves structural rearrangementsin order to engage the hairpin in the target membrane, disruptionof these interdomain interactions must occur prior to pore formation(55). In this respect, an interesting feature is the presenceof a conserved hydrophobic patch on the molecular surfaces correspondingto the domain I-domain II interface of Cry4Aa and Cry4Ba (Fig.4). Hydrophobic patches on protein surfaces are generally determinantsof protein-protein or protein-ligand interactions (43). Thebiological relevance of these hydrophobic patches of the Cry4Aaand Cry4Ba toxins requires further investigation.

A search for homologous three-dimensional structures in thePDB revealed that domain II of Cry4Aa is structurally similarto the plant lectin jacalin (53) and to Maclura pomifera agglutinin(40). The architecture shared with lectins suggests that domainII probably binds to the carbohydrate moiety of a glycoproteinreceptor of the target insect membrane. This notion is furtherreinforced by the finding that Caenorhabditis elegans resistanceto Cry5B toxicity is linked to the loss of a gene encoding agalactosyltransferase (28). Indeed, loss of this carbohydrate-modifyingenzyme could directly affect the binding of the toxin to itsreceptor(s) (28). Two proteins, aminopeptidase N and cadherin-likeprotein, have been characterized as candidate receptors forlepidopteran-specific Cry1 toxins (37, 44, 52, 62). By contrast,no receptor protein for dipteran-specific toxins has been identifiedso far. Comparison with the M. pomifera agglutinin structure(PDB code 1JOT) (40), whose interaction with a disaccharideis mediated by three aromatic amino acids, revealed that Cry4Aaalso possesses a cluster of aromatic amino acids, Tyr-341, Tyr-343,Tyr-344, and Tyr-348 in the ß1- ${alpha}$ 8 loop and Tyr-513in loop 3 (Fig. 1 and 6). These five aromatic amino acids forma potential binding site with dimensions that could accommodatea short oligosaccharide. The functional importance of this regionof domain II was further established by mutating two amino acidsin the ß1- ${alpha}$ 8 loop of Cry11A (23) and Tyr-455 in loop3 of Cry4Ba (60). A significant loss of toxicity for A. aegyptiwas observed.

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FIG. 6. View of the exposed cluster of aromatic amino acids (indicated by sticks) at the surface of domain II of Cry4Aa (only a partial view of the ${alpha}$ -carbon chain of domain II is shown). This cluster is proposed to function as a carbohydrate binding site (see text). Secondary structure elements are indicated.

Domain III. C-terminal domain III (residues 525 to 679) contains two antiparallelß-sheets that adopt a ß-sandwich fold withthe jelly roll topology. The outer sheet is composed of sixstrands, ß12, ß13b, ß16, ß22,ß18, and ß19, which are exposed to the solvent.The inner sheet, containing seven strands (ß20, ß17,ß23, ß21, ß13, ß14,and ß15), faces the other two domains (Fig. 2). DomainsII and III are associated via the intersheet connection throughhydrogen bonds and hydrophobic interactions. Superposition ofdomain III of Cry4Aa and domain III of Cry4Ba revealed closestructural similarity except for some loops exposed to the solvent.In Cry4Aa, the loops connecting ß15 to ß16and ß19 to ß20 are shorter than the loopsin Cry4Ba, and the loop connecting ß17 to ß18is longer.

Mutations in domain III of Cry1Aa toxin had an effect on bothion channel activity and membrane permeability (56, 67). DomainIII could play a role in protecting the toxin against furthercleavage by gut proteases (42). Domain swapping experimentssuggested that domain III is also involved in determining insectspecificity (17, 18, 19, 20).

A three-dimensional structural similarity search revealed thatdomain III closely resembles the N-terminal cellulose bindingdomain of a protein from the bacterium Cellulomonas fimi (33)and a xylanase from Clostridium thermocellum (15). This suggeststhat like domain II, domain III could also bind carbohydrateresidues. Although the level of amino acid sequence identitybetween domain III of Cry4Aa and the xylanase is only 11.5%,the structural similarity is quite extensive since the two polypeptidesegments can be superimposed with a residual root mean squaredeviation of 2.2 Å, giving a Z score of 12.2 (Fig. 7).Thus, one possibility is that insect specificity is determinedby protein-protein or protein-carbohydrate interactions mediatedby both domains II and III of the toxin. So far, the importanceof carbohydrates in dipteran-specific toxins has not been demonstrated.However, lectin-like domain III of the lepidopteran-specificCry1Ac toxin was shown previously to bind N-acetylgalactosamine(11, 31, 32).

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FIG. 7. Superposition of C-terminal domain III of Cry4Aa with xylanase from C. thermocellum, highlighting the common fold. Only the ${alpha}$ -carbon traces are shown (magenta for Cry4Aa and green for xylanase).

Site-directed mutagenesis of residues in domain II. Mutagenesis and loop swapping experiments with Cry toxins haveidentified regions of domain II as major determinants of insectspecificity (1, 51, 68, 69).

Like the complementarity-determining regions of immunoglobulins,three loops that have various lengths and amino acid sequencesconnect a conserved framework of ß-strands. Theseloops, which are clustered at the extremity of domain II oppositeits N and C termini (Fig. 2 and 8), connect strands ß2and ß3 (residues 372 to 379; loop 1), strands ß6and ß7 (residues 431 to 438; loop 2), and strandsß10 and ß11 (residues 511 to 514; loop 3)of domain II (42). Superposition of the corresponding segmentsof Cry4Aa and Cry4Ba revealed significant structural divergence(Fig. 8). In particular, loop 2 in Cry4Aa is six residues longerthan the corresponding loop in Cry4Ba (Fig. 8). Before the experimentalstructures were reported, Abdullah and coworkers introducedresidues from Cry4Aa into the three loops of Cry4Ba domain II.Exchanging loop 3 significantly enhanced the toxicity of Cry4Bafor Culex, while the activity against Anopheles and Aedes larvaewas maintained (1). This suggested that an important determinantof the specificity of the Cry4Aa toxin for Culex was locatedin the loop 3 region and that important determinants of thetoxicity of Cry4Ba for Anopheles and Aedes were in loops 1 and2.

Here, we used site-directed mutagenesis based on the crystalstructure to identify residues crucial for the toxicity of Cry4Aa.We selected exposed residues in the three loops and replacedthem with the structurally corresponding residues of Cry4Batoxin or performed a deletion if the corresponding segment wasshorter in Cry4Ba (e.g., loop 2). The results for the larvicidalactivities of the Cry4Aa toxin mutants are summarized in Table3.

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TABLE 3. Toxicity assays for variant Cry4Aa toxins with three species of mosquitoes

Five Cry4Aa mutants, including three deletion mutants with mutationsin loop 2 (4AL1YQDLR, 4AL1QD, 4AL2 ${Delta}$ KYLN, 4AL2 ${Delta}$ YLN, and 4AL2 ${Delta}$ LN),were expressed very poorly and could not be studied further.

The seven other mutants of Cry4Aa could be expressed in E. coliat levels comparable to the level of the wild-type toxin. Replacementof residues of Cry4Aa in loop 1 with the corresponding residuesof Cry4Ba did not dramatically alter the toxicity for larvaeof members of the three genera of insects. As many as four residues(with the amino acid sequence TTPN) of loop 1 could be replaced(mutant 4AL1YQDL), leading to only a marginal decrease (approximatelytwofold) in the toxicity of the corresponding mutant for A.dirus and C. quinquefasciatus, while full toxicity for A. aegyptilarvae was retained (Table 3).

This suggests that there are no strong structural constraintsimposed on loop 1 for the binding of Cry4Aa to its receptorsor that this loop does not participate in binding. By contrast,introduction of three residues of loop 1 of Cry4Aa into Cry4Ba(mutant 4BL1QTT) led to a severely impaired Cry4Ba toxin (1).

In Cry4Aa mutant 4AL2 ${Delta}$ KY two residues of the long loop2 weredeleted to mimic the shorter loop present in Cry4Ba. Large amountsof this protein could be expressed in E. coli, and digestionof it by trypsin yielded a pattern similar to the pattern forthe wild-type toxin (data not shown). However, the toxicityfor the three insect genera was dramatically reduced (Table3); for example, the toxicity for A. dirus was reduced about300-fold. This suggests that there is direct participation ofthis loop in receptor binding, although we cannot formally ruleout the possibility that there are some conformational changeeffects, which would alter the integrity of the protein structure.Interestingly, a single substitution within loop 2, replacementof Asn-435 by a tyrosine residue, preserved most of the toxicity,indicating that the length of the loop rather than its precisesequence is an important determinant of specificity. Likewise,replacement of Lys-514 in loop 3 by an Asn residue, as foundin Cry4Ba, resulted in an active toxin.

Interestingly, loops 2 and 3 are clustered in the vicinity ofthe ß1- ${alpha}$ 8 loop, close to the interface between domainII and domain I, whereas loop 1 is some 25 Å away (Fig.2). This region appears to be crucial for receptor binding byCry4Aa, an event which could trigger conformational changesthat lead to disruption of the interface between domains I andII and prime domain I for insertion into the host membrane.

Thus, taken together, our data suggest that different regionsof Cry4Aa and Cry4Ba are important for toxicity, possibly byusing distinct binding sites for interaction with the host receptors.While these results are consistent with the synergistic effectsof the two toxins that have been observed (49), they do notsupport approaches in which fragments of one toxin could beeasily grafted onto the other toxin to produce an engineeredCry toxin having a broadened spectrum.

However, we hope that the availability of an experimental structurefor a complete active fragment of Cry4Aa will accelerate thedevelopment of engineered Cry toxins that have increased potencyand prolonged stability. This structure should be useful ifinsect resistance to the existing Cry toxins emerges, whichseems likely. It should also stimulate further mechanistic studiesaimed at dissecting the molecular steps leading to pore formation.

ACKNOWLEDGMENTS

We are grateful for the provision of excellent beam time andexpert advice at E.S.R.F. beam line ID29 (Grenoble, France).We thank Somsri Sakdee for expert technical assistance and J.Torres for reading the manuscript.

The laboratory of J.L. is supported by grants from N.T.U. (grantRG 29/05), the Singapore Biomedical Research Council (grants03/1/21/20/291 and 02/1/22/17/043), and the Singapore NationalMedical Research Council (grant NMRC/SRG/001/2003). P.B. acknowledgessupport from the Thailand Research Fund and the National Scienceand Technology Development Agency, Thailand.

FOOTNOTES

* Corresponding author. Mailing address for Panadda Boonserm: Institute of Molecular Biology and Genetics, Mahidol University, Salaya Campus, Nakornpathom 73170, Thailand. Phone: (66) 2800 3624. Fax: (66) 2441 9906. E-mail: mbpbs{at}mahidol.ac.th. Mailing address for Julien Lescar: School of Biological Sciences, Nanyang Technological University, 60, Nanyang Drive, Singapore 637551. Phone: (65) 6316 2859. Fax: (65) 6791 3856. E-mail: julien{at}ntu.edu.sg.

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