Crystal Structures of Human Immunodeficiency Virus Type 1 (HIV-1) Neutralizing Antibody 2219 in Complex with Three Different V3 Peptides Reveal a New Binding Mode for HIV-1 Cross-Reactivity

Human monoclonal antibody 2219 is a neutralizing antibody isolatedfrom a human immunodeficiency virus type 1-infected individual.2219 was originally selected for binding to a V3 fusion proteinand can neutralize primary isolates from subtypes B, A, andF. Thus, 2219 represents a cross-reactive, human anti-V3 antibody.Fab 2219 binds to one face of the variable V3 ß-hairpin,primarily contacting conserved residues on the N-terminal ß-strandof V3, leaving the V3 crown or tip largely accessible. ThreeV3/2219 complexes reveal the antibody-bound conformations forboth the N- and C-terminal regions that flank the V3 crown andillustrate how twisting of the V3 loop alters the relative dispositionsand pairing of the amino acids in the adjacent V3 ß-strandsand how the antibody can accommodate V3 loops with differentsequences.

INTRODUCTION

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Introduction

Recent crystal structures of human immunodeficiency virus type1 (HIV-1) neutralizing antibodies have revealed how the immunesystem can utilize many different strategies to recognize thisconstantly evolving virus. Prototypic examples include the broadlyneutralizing antibody b12, which is thought to use its longcomplementarity-determining region (CDR) loops to access therecessed, but conserved, CD4 binding site (63), and antibody2G12, which capitalizes on a unique domain-swapped dimer-of-Fabconfiguration to create a multivalent binding surface to enhanceavidity for low-affinity carbohydrate epitopes (5) on the gp120silent face. Novel antibodies that block gp120 binding to itschemokine receptor have recently been shown to contain sulfatedtyrosines in their CDR loops that likely mimic sulfated tyrosinesin the chemokine receptor itself (12), whereas the anti-V3 antibody447-52D uses a long CDR H3 loop to bind V3 in a way that makesthe recognition largely sequence independent, except for interactionwith the relatively conserved GPGR crown region (72). Finally,antibody 4E10, the most broadly HIV-1-neutralizing antibodyknown, binds to a membrane-proximal epitope on gp41 and mayalso use its long CDR H3 loop to interact with the membrane(6). We report here the structure of a human anti-V3 neutralizingantibody, 2219, that shows yet another way the immune systemhas found to evoke broad recognition of multiple HIV-1 viralisolates.

The HIV-1 viral proteins gp120 and gp41 are located on the outermembrane surface of the virus, forming a trimeric assembly ofthe two noncovalently associated proteins. Antibodies that neutralizethe virus are directed against these envelope proteins. Oneof the major epitopes on gp120 is its V3 (third hypervariable)loop, a region of approximately 35 amino acids, linked by adisulfide bond at the base (Cys296-Cys331; HXB2 numbering).Although V3 is termed "hypervariable," much of the V3 loop,including the tip or crown, is fairly well conserved, with usuallyjust one or two chemically similar amino acid types found ateach position (Table 1). The V3 region is highly immunogenicand induces a spectrum of antibodies that can either be highlyspecific for a particular V3 sequence (75) or be more broadlycross-reactive and neutralize many primary isolates across severalHIV-1 subtypes (3, 27, 29, 30, 32). That broadly cross-reactiveanti-V3 antibodies are found suggests that V3 is a key epitopeto include in vaccine design.

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TABLE 1. Residues of V3 sequences by subtype^a

The V3 region impacts many different aspects of viral infectivity,largely because of its interaction with the gp120 coreceptorCCR5 (15, 60, 61) or CXCR4 (2) during viral cell fusion. Variationat particular V3 residues can affect coreceptor usage and leadto changes in cell tropism (34). During receptor binding andviral fusion, gp120 is thought to undergo several conformationalchanges, and V3 may change its conformation, location, or accessibility.Conformational flexibility in gp120 has received strong supportfrom a recent crystal structure of an unliganded simian immunodeficiencyvirus gp120 core (10, 11), in which the gp120 inner domain hassignificant structural rearrangements compared to CD4-boundHIV gp120 (47, 48). Trimer models based on these core structures(11) suggest that the V3 region alters its location relativeto the V1-V2 domain after CD4 is bound. This model is consistentwith other studies where binding of soluble CD4 to intact virionsenhances the accessibility of the V3 loop (54).

Until recently, all structural information for V3 has come fromstudies of V3 peptides or V3 peptide-antibody complexes (fora review, see reference 23). However, a recent crystal structureof a V3-containing gp120 core, in complex with CD4 and a CD4-inducedmonoclonal antibody (MAb), has revealed a long V3 that extendsabout 30 Å from its base (35) and consists of three structuraldomains: the base (residues 296 to 300 and 326 to 331), thestem (residues 301 to 305 and 321 to 325), and the tip or crown(residues 306 to 320). These structure-based domain names differslightly from previously described "functional domains" forwhich the combined base and stem regions were called the stem(14). The base and tip/crown regions consist of antiparallelß-strands forming a ß-hairpin, while theintervening stem region has a more irregular and flexible structure.In the Fab-V3 peptide structures, only the V3 tip/crown andshort sections of the stem regions are visible, but their conformationsgenerally agree with that observed in the V3-containing coregp120. V3 peptide-Fab crystal structures are available for mouseFabs 50.1 (59, 70), 59.1 (25, 26), 58.2 (70), and 83.1 (71)and for human Fab 447-52D (72). Four of these Fabs (50.1, 59.1,83.1, and 447-52D) recognize a conserved V3 structure, while58.2 recognizes a V3 conformation that differs in the GPGR regionof the tip/crown (26). Nuclear magnetic resonance (NMR) studiesof V3 in complex with Fv fragments include a IIIb V3 peptide(RKSIRIQRGPGRAFVTIG) bound to mouse MAb 0.5ß (75),where the V3 forms a hairpin with an irregular turn around GPGR.In the MN V3 complex with human Fv 447-52D (65), the peptideforms a ß-hairpin with a ${gamma}$ -turn around GPGR, whichis consistent with solid-state NMR studies (66). 447-52D hasalso been studied by NMR with a IIIb peptide, with the N-terminalside of the IIIb peptide adopting a conformation similar tothat of the MN peptide bound to 447-52D but with a differentorientation for the C-terminal strand (62). NMR studies of isolatedV3 peptides show no stable structure in solution, but transientturns exist around GPGR (7-9, 17, 18, 19, 25, 33, 36, 37, 52,64, 77, 79, 80, 84). NMR studies of peptides modified by cyclization(4, 9, 33, 38, 74, 76-78), by replacement of Ala^P316 with theconformationally restricted residue ${alpha}$ -aminoisobutyric acid (4,25), by glycosylation (36, 37, 52), through attachment to resinbeads (40), through attachment to a bacteriophage viral coatprotein (39), and through attachment to carrier proteins, suchas bovine pancreatic trypsin inhibitor (81) and MUC1 (22), allshow an increased ß-turn propensity around GPGRAF,while V3 peptides attached to filamentous bacteriophage fd viralcoat protein pVIII (39) adopt a double-turn structure similarto that observed in the Fab 59.1-peptide crystal structure (25,26).

While it is clear how broadly neutralizing MAbs that targethighly conserved regions can recognize many isolates, the natureof cross-reactivity with MAbs that bind to more-variable regionsis less clear. One such MAb, 447-52D, reacts with and neutralizesviruses from subtypes B, A, and F if these viruses possess aGPGR motif (3, 83), and the structural basis of this specificityhas been elucidated (72).

However, anti-V3 MAb 2219, which displays cross-clade neutralizingactivity (30), is less dependent on the actual motif at theV3 tip/crown. 2219, while not as broadly neutralizing as 447-52D,will neutralize a variety of primary isolates from subtypesB (BaL, SF162, JR-CSF, US1, JR-FL, 92US717, MNp, CA5, and Bx08),subtype A (CA1), and subtype F (93BR019) (28, 30). In orderto investigate the structural basis of this cross-reactivity,we have determined crystal structures for antibody 2219 as itsFab fragment in complex with three different peptides (Table2), including an unusual peptide with sequence RPRQ, ratherthan GPGR, at its tip/crown.

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TABLE 2. Sequences of V3 peptides cocrystallized with Fab 2219^a

MATERIALS AND METHODS

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Materials and Methods

Construction of the V3 fusion protein. The V3 fusion protein was cloned and expressed as previouslydescribed (44). Briefly, the V3 region of a JR-CSF viral isolate(45 amino acids; SVEINCTRPSNNTRKSIHIGPGRAFYTTGEIIGDIRQAHCNISRA)was fused to the C-terminal end of the N-terminal domain ofmurine leukemia virus gp70 (268 residues). This construct wasexpressed in CHO cells and was glycosylated at three N-linkedsites, as shown by digestion with endo-ß-N-acetylglucosaminidaseH (44).

Fab production and purification. Human monoclonal antibody 2219 {immunoglobulin G1( ${lambda}$ ) [IgG1( ${lambda}$ )]}was produced as previously reported (30). Briefly, peripheralblood cells from HIV-1-infected individuals were transformedby Epstein-Barr virus and cultured for 3 weeks, and the supernatantwas screened by enzyme-linked immunosorbent assay (ELISA) forbinding to the V3 fusion protein. Cells from positive cultureswere fused to the human/mouse heteromyeloma cell line SHM-D33and cloned at limiting dilution to monoclonality. Fab fragmentswere prepared by cleavage of the 2219 IgG with 4% papain for4 h, followed by purification on a mono S column (10/10 column;buffer A [50 mM sodium acetate, pH 4.5]; buffer B [50 mM sodiumacetate, 1 M sodium chloride, pH 4.5]) and a Superdex 200 column(16/60 column; 20 mM Tris, 100 mM sodium chloride, pH 7.4).

Binding assays. Eighteen V3 peptides were tested for antibody binding. FourV3 peptides, representing sequences of MN, SF2, NY/5, and CDC4,were purchased from Intracel, Inc. (Cambridge, MA). One peptide,D687, was synthesized by Genemed Biotechnologies, Inc. (SouthSan Francisco, CA). Peptide VI191 was synthesized by MacromolecularResources (Fort Collins, CO). The remaining peptides were synthesizedby Lawrence Loomis-Price at the H. M. Jackson Foundation (Rockville,MD) by standard solid-phase methods as described previously(82).

The binding of MAbs to V3 peptides was determined by a standardELISA as described previously (29). Briefly, ELISA plates werecoated with the V3 peptides at a concentration of 1 µg/mland left overnight at 4°C. MAbs at concentrations rangingfrom 0.003 to 10 µg/ml were added to the plate in duplicate,and antigen-bound MAbs were detected by using alkaline phosphatase-labeledgoat anti-human IgG ( ${gamma}$ specific) (Zymed Laboratories, South SanFrancisco, CA). The color was developed by adding the substrate,and the plates were read at 405 nm.

Crystallization, data collection, structure determination, refinement, and analysis. Crystals were obtained for Fab 2219 (12 mg/ml) in complex witha 5:1 molar excess of peptide RP322 (referred to as the MN peptide;subtype B, KRKRIHIGPGRAFYTTKNAbuC(acm)NH₂, where Abu refersto 2-aminobutyric acid and acm means acetamidomethylated) in40% polyethylene glycol 400 (PEG 400), 0.2 M potassium acetate.The crystals grew in tetragonal space group P4₁2₁2, with unitcell dimension a = b = 60.5 Å, and unit cell dimensionc = 275.2 Å, and with one Fab-peptide complex in the asymmetricunit. Data were collected at the Stanford Synchrotron RadiationLaboratory (SSRL) beamline 9-2 to a 2.3-Å resolution,with an overall R_sym of 8.6% and with 99.8%-complete data (seeTable 3 for data collection and refinement statistics for allthree structures). The structure was determined by molecularreplacement using as the initial model human Fab fragment NEW(Protein Data Bank [PDB] identifier [ID] 7fab), which was separatedinto variable and constant domains, and using the AMoRe packageof programs (57).

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TABLE 3. Data collection and refinement statistics

Fab 2219 was cocrystallized with a 5:1 molar excess of peptideUR29 (subtype C; NNTKKSIKIRPRQAFYATNGIIG) in 25% PEG monomethylether5000, 0.2 M disodium tartrate. The crystals belong to orthorhombicspace group P2₁2₁2₁, with unit cell dimension a = 62.9 Å,b = 94.4 Å, and c = 96.7 Å. Data were collectedto a 2.0-Å resolution at the Advanced Light Source (ALS)beamline 5.0.1, with an overall R_sym of 6.9% and completenessof 99.9%. The structure was determined by molecular replacementusing the 2219-MN peptide structure (with peptide coordinatesremoved) as the initial model.

Fab 2219 was cocrystallized with a 5:1 molar excess of peptideUG1033 (subtype A; NNTRKSIHLGPGRAFYATGDIIG; 23-mer) in 13.75%PEG 20,000, 0.05 M disodium tartrate. The crystals belong tospace group P2₁2₁2₁, with unit cell dimension a = 62.7 Å,b = 96.9 Å, and c = 97.0 Å. Data were collectedto a 2.35-Å resolution at the SSRL from beamline 11-1,with an overall R_sym of 5.7% and completeness of 98.6%. Thestructure was determined by molecular replacement using the2219-MN peptide structure (without peptide) as a model. Datawere also obtained for this particular Fab-peptide complex inseveral different-molecular-weight PEG-ion combinations (butwith the same unit cell dimensions and space group), and althoughall of the crystals diffracted to similar resolutions, theirstructures suffered from disorder in the Fab constant domain.The constant domain in the PEG 20,000 crystal form is not disordered,but B values for the entire Fab are higher than for the othertwo 2219-peptide structures (Table 3). All of the structureswere refined with CNS and Refmac, with maintenance of the same5% test set of reflections throughout. Buried surface areaswere calculated with the program MS (13), using a 1.7-Åprobe radius and standard van der Waals radii (24). Hydrogenbonds were evaluated with the program HBPLUS (55), and van derWaals contacts were evaluated with the program Contacsym (67,68). Shape correlation statistics (S_c) were calculated withthe CCP4 program Sc, version 2.0 (49).

PDB accession numbers. The coordinates and structure factors are deposited in the ProteinData Bank with PDB accession codes 2b0s (MN peptide complex),2b1a (UG1033 peptide complex), and 2b1h (UR29 peptide complex).

RESULTS

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Results

Cross-reactivity of MAb 2219. Antibody 2219 cross-reacts in an ELISA with 11 of 18 peptidesrepresenting the V3 sequences of primary HIV-1 isolates fromsubtypes A, B, and C (Table 4) and neutralizes viruses withthe V3 sequences shown in Table 5 (28, 30). The sequences ofall of the 18 peptides are different, and no pattern in theprimary sequence of the peptides that could explain which peptidewould or would not bind strongly to MAb 2219 was discernible,although Arg at position 308 and/or Gln at position 315 maybe correlated with reduced affinity (see Table 2 for residuenumbers).

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TABLE 4. Reactivities of human anti-V3 MAbs with V3 peptides tested by ELISA^a

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TABLE 5. V3 sequences of HIV-1 strains neutralized by MAb 2219^a

The interactions of MAb 2219 with three V3 peptides from virusesMN (subtype B), UR29 (subtype C), and UG1033 (subtype A) werechosen for further study because of the strong reactivity ofthe MAb with these peptides and because of the sequence diversityrepresented by these peptides. However, the relative bindingaffinities of MAb 2219 for the three peptides differ by 2 ordersof magnitude, the binding affinity being highest for UR29, intermediatefor MN, and lowest for UG1033 (Fig. 1). 2219 can completelyneutralize MN when used at 25 µg/ml (30); however, sincethe viruses from which UR29 and UG1033 were derived are notavailable, corresponding neutralization data could not be generated.Recent data have also demonstrated the ability of MAb 2219 topotently neutralize pseudoviruses carrying the V3 consensussequences of these subtypes A and C (42).

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FIG. 1. Reactivities of MAbs with V3 peptides by ELISA. The binding curves for anti-V3 MAbs 2219 and 447-52D are shown with filled squares and triangles, respectively. Data for the human anti-parvovirus B19 MAb 1418, used as a negative control, are shown as open circles. O.D., optical density; *, value obtained by extrapolation because the binding curve did not reach the saturation point; NR, not reactive.

Fab structure. Fab 2219 [human, IgG1( ${lambda}$ )] was crystallized with these three V3peptides, the sequences of which are shown in Table 2. The Fablight and heavy chains and the peptides are numbered with chainidentifiers of L, H, and P, respectively. The Fab is numberedby the standard Kabat and Wu numbering system, and the peptidesare numbered according to the HXB2 reference sequence (58).The three structures are very similar (Fig. 2) except for smallchanges in the peptide and the peptide binding site. The elbowangles for Fab 2219 bound to the MN, UR29, and UG1033 peptidesare 228°, 210°, and 211°, respectively. These large(>190°) elbow angles are common for antibodies with alambda light chain (73).

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FIG. 2. C ${alpha}$ traces of the Fab 2219-peptide complexes. (a) Fab 2219 plus MN peptide; (b) Fab 2219 plus UG1033 peptide; (c) Fab 2219 plus UR29 peptide. In all panels, the peptide is colored in red; Fab light and heavy chains in light and dark gray, respectively; and the Fab CDR loops L1 in orange, L2 in dark purple, L3 in green, H1 in light blue, H2 in pink, and H3 in yellow. Images were produced using Molscript (45), Bobscript (21), and Raster3D (56).

The Fab 2219 CDR loops (L1, L2, H1, H2) fall into canonicalclasses (1, 53) 5 ${lambda}$ , 1, 1, and 1, respectively. 2219 CDR loopL3 represents the longest L3 loop described so far and thusforms a new canonical class (Fig. 3). The 2219 L3 has four residuesinserted after L95; the next-longest L3 structure is found inhuman antibody 447-52D (72), with a 3-amino-acid insert. The2219 CDR H3 is of medium length (15 amino acids), compared tothose of other anti-HIV antibodies with very long H3 CDRs, suchas 447-52D (20 amino acids), 2F5 (22 amino acids), 58.2 (17amino acids), and b12 (18 amino acids), and has a "kinked" base,as predicted from its sequence (69).

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FIG. 3. New canonical structure for CDR L3. (a) The 2219 L3 loop (red) is compared to other L3 loops with three inserts (447-52D [salmon]), two inserts (2fb4 [blue], canonical class ${lambda}$ L3-2), and one insert (1gig, 1ind [yellow], ${lambda}$ L3-1a; 7fab [pink], ${lambda}$ L3-1b; and 1mfa [yellow], ${lambda}$ L3-1c). (b) The 2219 lambda chain L3 CDR loop has four inserts (95a to -d) and represents a new canonical structure.

Peptide structure and interactions. The three peptides bound to Fab 2219 (19, 23, and 23 amino acidslong for the MN, UR29, and UG1033 peptides, respectively) allexhibit good electron density for 16 residues (Fig. 4), withall peptides forming a ß-hairpin with a type II ß-turnaround residues P312 to P315. This well-ordered electron densityrepresents the longest stretch of interpretable V3 peptide electrondensity seen thus far in crystal structures of Fab-V3 complexes,which have so far ranged from 9 to 11 ordered amino acids (forpeptides varying in length from 16 to 24 amino acids). All ofthe hydrogen bonds or salt bridge interactions (Table 6) frompeptide to Fab are made by the N-terminal half of the peptide(P303 to P309), with one additional hydrogen bond from Arg^P315(MN and UG1033 peptides) or Arg^P312 (UR29 peptide). Althoughthe C-terminal half of the peptide (P314 to P320) is also welldefined, it makes less contact with the Fab (Table 7). C-terminalpeptide residues P314, P316, P319, and P320 make no contactwith Fab in any of the three structures, while Phe^P317 and Tyr^P318make only side chain interactions. The P315 side chain makesjust three contacts (one hydrogen bond) in the MN and UG1033complexes and no contacts in the UR29 complex. In the UR29 andUG1033 crystal structures, the C-terminal portion of the peptidecontacts a symmetry-related Fab, with residues L204 to L206forming an extended ß-sheet with the peptide; however,the C-terminal peptide conformation is the same as in the MNpeptide complex, which makes no corresponding crystal contacts.The buried molecular surface areas on Fab and peptide are 783Å² and 708 Å² (MN), 770 Å² and 667 Å²(UG1033), and 765 Å² and 630 Å² (UR29), with a totalof 213, 172, and 160 contacts made between Fab and peptidesMN, UG1033, and UR29, respectively (Table 7). The buried molecularsurface on the Fab (for the MN, UG1033, and UR29 complexes)is contributed from both heavy (62, 62, and 61%, respectively)and light (38, 38, 37%) chains, using CDR loops L1 (15, 16,15%), L2 (2, 3, 2%), L3 (20, 19, 22%), H1 (18,15, 16%), H2 (17,15, 15%), and H3 (28, 33, 30%). The corresponding buried peptidesurface involves all peptide residues except for P314, P316,P319, and P320, with the largest individual contribution fromP304 (17%, 15%, 18%) (Table 7). The peptide-Fab interface hasgood shape correlation statistics (S_c) (49) of 0.83, 0.78, and0.78 for the MN, UG1033, and UR29 complexes, similar to thosefor other Fab-V3 peptide complexes, such as 447-52D (1q1j, 0.77),59.1 (1acy, 0.80), 50.1 (1ggi, 0.79), 58.2 (1f58, 0.80), and83.1 (1nak, 0.78). At the peptide-Fab interfaces of all threestructures, there is one conserved, interfacial water molecule,stabilized by hydrogen bonds to P304O, H95O, and H33N.

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FIG. 4. F_obs-F_calc electron density for V3 peptides bound to Fab 2219. (a) MN peptide; (b) UG1033 peptide; (c) UR29 peptide. Electron density is contoured at 1.5 ${sigma}$ .

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TABLE 6. Hydrogen bonding and salt bridge distances between Fab 2219 and different V3 peptides and intrapeptide hydrogen bonds within each V3 peptide^a

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TABLE 7. Total van der Waals and hydrogen bond contact with Fab 2219 and buried surface areas of the V3 peptide

The peptides in the three different complexes share almost identicalbackbone conformations, but the UR29 peptide with its unusualArg^P312Pro^P313Arg^P314Gln^P315 crown sequence uses different residuepositions to contact Fab than the other peptides (Fig. 5), causingthe UR29 backbone to deviate slightly in this region. UR29 Arg^P312forms a hydrogen bond with Asn^L31 from Fab, while Arg^P315 inthe MN and UG1033 peptides makes the comparable hydrogen bond(Fig. 6). Arg^P314 in UR29 projects out into the solvent, andGln^P315 points towards Phe^P317 but has no interaction with Fab.

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FIG. 5. Stereoview of three peptides bound to Fab 2219. The peptides (MN [yellow], UR29 [pink], and UG1033 [cyan]) were superimposed using only their respective Fab coordinates. Arg^P315 (MN and UG1033) and Arg^P312 make comparable interactions with the Fab fragment. Note the slight movement of Phe^P317 in response to the Ile $->$ Leu mutation at P309 in the UG1033 structure.

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FIG. 6. Specific binding interactions between V3 peptides and Fab 2219. (a) 2219 with MN peptide; (b) 2219 with UG1033 peptide; (c) 2219 with UR29 peptide. The UR29 peptide has the unusual RPRQ crown sequence and uses the Arg^P312 side chain flexibility to make hydrogen bond interactions comparable to those of Arg^P315 in the other two complexes. The UG1033 peptide has an IleP309Leu mutation, and the longer Leu side chain pushes the Phe^P317 side chain from its position in the other two complexes to an unfavored rotamer with weak electron density.

A more subtle conformational change is seen in the UG1033 peptide,where a seemingly conservative change from Ile to Leu at positionP309 causes the Phe^P317 side chain to alter its preferred rotamerconformation by about 50° (the ${chi}$ 1 torsion angle equals –66°and –57° in the MN and UR29 complexes and –110°in the UG1033 complex) to avoid close contact with the longerLeu side chain (Fig. 4 and 6). Electron density is weak forthe UG1033 Phe side chain, suggesting that it may also be somewhatdisordered.

Conserved peptide conformation. The peptides bound to 2219 share structural homology with V3peptides bound to mouse Fabs 50.1, 59.1, and 83.1; human Fab447-52D; and the V3 region in the V3-containing gp120 core.The isolated N-terminal (amino acids 303 to 312) or C-terminal(amino acids 313 to 320) regions of 2219-bound V3 peptides overlapwell with the corresponding regions from all peptides and V3-containinggp120 core. However, a difference in the ${psi}$ angle for Ile^P309in the 2219-bound peptides causes the relative disposition ofthe N- and C-terminal halves of the 2219 peptides to be distortedor twisted, compared to the disposition of the 447-52D and V3-containinggp120 core structures (Fig. 7). Thus, the isolated N- and C-terminalhalves overlap well, but the peptide in its entirety does not.A comparison of the 2219 MN peptide dihedral angles and thoseof a V3 peptide bound to 447-52D (PDB ID 1q1j) and the V3-containinggp120 core (PDB ID 2b4c) show that, with the exception of deviationsat the extreme N and C termini and the twist at Ile^P309, thepeptides are very similar (Table 8). The strand twist resultsin an $~$ 180° flip of the His^P308 carbonyl oxygen and all residuesN-terminal to that oxygen. The change in relative orientationsof the N and C strands also alters the intrastrand hydrogenbonding ladder. In the V3-containing gp120 core, two hydrogenbonds are made in the V3 tip or crown (Gly^P312N to Arg^P315Oand Gly^P312O to Arg^P315N), while in the 2219-bound V3 peptide,the Gly^P312O to Arg^P315N hydrogen bond is retained, but newhydrogen bonds are formed between Ile^P307N to Phe^P317O, Ile^P307Oto Phe^P317N, and Ile^P309N to Arg^P315O (Fig. 7).

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FIG.7. V3 peptides bound to 2219 and 447-52D and the corresponding region from the V3-containing gp120 core. The 2219 V3 peptide (MN) (a), 447-52D peptide (MN) (b), and V3 tip from the V3-containing gp120 core (JR-FL) (c) are shown in approximately equivalent orientations, with hydrogen bonds shown as dotted black lines. A twist in the main-chain torsion angle around Ile^P309 results in different relative orientations of the N- and C-terminal strands in the 2219 structure (a) so that in the 2219-bound V3, residues Ile^P309, Ile^P307, Phe^P317, and Tyr^P318 occupy the same face of the ß-hairpin, but in the other two V3 loop structures bound to 447-52D and in the V3-containing gp120 core, these residues would be on opposite faces (Table 8).

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TABLE 8. Main chain torsion angles for V3 peptides bound to Fabs 2219 and 447-52D and the V3 region in the V3-containing gp120 core

The C-terminal portion of the 2219-bound peptide contacts theFab fragment through two side chains (Phe^P317 and Tyr^P318) butmakes no backbone contacts. This strand has structural homologyto the corresponding region on the intact gp120-V3 structure(35) (Table 8 and Fig. 7) and also is consistent with the weakelectron density observed for the 447-52D C terminus (describedin reference 72 but not included in the PDB submission). Interestingly,none of the V3 conformations that bound to 2219 or 447-52D and/orthat are bound in gp120-V3 have the double turn seen in 59.1(25, 26), although V3 bound to mouse Fab 83.1 has what appearsto correspond to the start site of this double turn (71).

2219 binds to the UR29 peptide with an affinity 2 orders ofmagnitude higher than to the MN or UG1033 peptides (Fig. 1).Analyses of the structures do not give a clear rationale forthis difference in binding affinity, as the buried molecularsurface area, the buried hydrophobic molecular surface area,the shape complementarity to the surface, and the numbers ofcontacts and hydrogen bonds are all very similar for the threeFab-peptide complexes. Actually, slightly fewer contacts, smallersurface areas, and a slightly lower shape correlation statisticare observed for the more strongly binding UR29 peptide complex.There are some differences in intrapeptide hydrogen bondingdue to sequence differences in the three peptides (Table 6),the most striking around Gln^P315 in UR29. Small differencesin the UR29 backbone conformation (Fig. 6) cause the loss oftwo intrapeptide hydrogen bonds (P309N to P315O and P312N toP315O) found in MN and UG1033, but Gln^P315 then makes two differentintrapeptide hydrogen bonds not found in the two other peptides.Gln^P315OE1 makes a hydrogen bond to Ile^P309N (3.10 Å),and Gln^P315NE2 is about 3.5 Å from the center of the Phe^P317phenyl ring, a reasonable distance for an aromatic hydrogenbond (Fig. 6) (50). Thus, although the numbers of intrapeptidehydrogen bonds in the three peptides are similar (5, 6, and6 in the MN, UG1033, and UR29 peptides, respectively) it ispossible that different intrapeptide hydrogen bonding interactionsmay serve to better stabilize the UR29 peptide in solution,thus lowering the entropic penalty for binding. However, asseen in many other systems, it is often difficult to directlycorrelate the structural results with binding affinities (18,20, 51).

DISCUSSION

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Discussion

The human neutralizing MAb 2219 was studied to investigate thestructural basis for cross-reactivity with a variable epitope,the V3 loop of the HIV-1 envelope glycoprotein gp120. 2219 bindsto different V3 peptides (Table 4) and neutralizes viruses fromHIV-1 subtypes B, A, and F (Table 5) (30). These results demonstratethat a single antibody, raised against a variable region ofthe virus, can bind to peptides with different viral sequencesand can neutralize different viral isolates, suggesting thatvaccine constructs that can elicit such antibodies may be ableto induce a broadly effective immune response.

Examination of the interactions made between the three differentV3 peptides and 2219 help to explain the reactivity of the Fabfragment for some of the different peptides tested by ELISAin Table 4. For example, V3 residues P303 to P306 make a significantnumber of hydrogen bond and van der Waals contacts but are solventexposed, so that alteration of these side chains may not abolishbinding. In contrast, residues P307 and P309 are buried in hydrophobicpockets in the antigen combining site and are probably restrictedto small, hydrophobic residues, such as Ile, Leu, or Val, toattain high affinity. Residues most often found at position307 include Ile, Val, Thr, and Met (Table 1), while at position309 Ile, Leu, Phe, and Met are found most frequently (Table1). One peptide (12233, subtype C) that reacts with MAb 2219(Table 4) has the larger, Met residue at P307; computer graphicsmodeling in which Ile^P307 is replaced with a Met shows thatthe Met side chain can be accommodated with little or no adjustmentto the Fab complex. Fab 2219 reactivity is decreased for peptideswith Arg at position 308 and Gln at position 315 (Table 4).His^P308 points out of the combining site in the 2219-peptidestructures and interacts with several residues from the longH3 CDR loop. As good reactivity is observed with peptides containingHis, Tyr, Ala, and Lys at position 308, it is not obvious whyreplacement with Arg (about the same length and charge as aLys) would severely reduce affinity, although the bulkier Argside chain might be a tight fit in the 2219 combining site.At position 315, Arg^P315 in the MN and UG1033 peptide complexstructures makes a hydrogen bond to Asn^L31 (Table 6). Computermodeling in which Arg^P315 is replaced with a Gln suggests thatGln could easily make the corresponding hydrogen bond, albeita longer one (3.0 Å compared to $~$ 2.2 Å), with littlerearrangement of the peptide or Fab, but it is possible thata longer, hence weaker, hydrogen bond at this position wouldreduce affinity.

2219 is able to recognize the unusual V3 crown sequence of UR29largely because of its mode of binding, where the antibody bindsprimarily to one face of V3, with the crown largely free fromcontact (Fig. 8). In addition, the UR29 crown sequence (RPRQ)allows the antibody to maintain its interaction between Asn^L31and an Arg from the peptide, in which the Arg corresponds toP315 in the MN and UG1033 peptides but to P312 in UR29. In contrast,the broadly reactive antibody 447-52D cannot bind peptide UR29(Fig. 1). Examination of the interactions between 447-52D andits bound V3 peptide with an MN sequence (72) shows that conversionof GPGR to RPRQ would likely cause Arg^P314 to clash with 447-52DArg^H50 or Asp^H58. V3 binds 447-52D with its crown region buriedin a pocket but with the remaining side chain positions accessibleto solvent (Fig. 8). This mode of binding allows 447-52D torecognize many different V3 sequences (83) but would preventit from accommodating large side chains at position 314. TheV3 face binding mode used by 2219 has not been seen previouslyfor the other anti-V3 antibodies, most of which (59.1, 58.2,83.1) bind around the crown/tip region. The most similar bindingmode is that of the MN-specific antibody 50.1, which binds thesame face of V3, but only to the N-terminal strand.

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FIG. 8. Comparison of modes of binding of the two V3 antibodies 2219 and 447-52D. (a) 2219 bound to V3 peptide (MN), with the peptide in yellow, the light chain in pink, and the heavy chain in blue. The N- and C-terminal regions of V3 contact Fab, but crown residues Gly^P314 and Arg^P315 are largely free from contact with Fab. (b) 447-52D bound to V3 peptide (MN) with the color scheme shown in panel a. In this complex, V3 binds with its crown region buried in the antibody combining site and with the N-terminal side bound to the H3 loop via main-chain hydrogen bonds, leaving the N-terminal side chains accessible to solvent. Thus, 447-52D can tolerate changes in the N-terminal side chain positions but not in the GPGR region.

While most of the binding and neutralization data can be illuminatedby the crystal structure results, there still remain some unansweredquestions. For example, 447-52D neutralizes GPGR- but not GPGQ-containingviral isolates (83), but the data in Table 4 indicate that 447-52Dcan still bind to several GPGQ-containing V3 peptides, oftenbetter than 2219. Yet, the crystal structure shows that 447-52Dbinds to GPGR via a salt bridge interaction from Asp^H95 to Arg^P315,while 2219 recognizes the same Arg^P315, but with a hydrogenbond, suggesting that 2219 would be tolerant of noncharged residues(such as Gln) (Table 4). These results suggest that the V3 regionsof GPGR viral isolates may differ subtly in conformation fromthose of the GPGQ viral isolates, and this notion is supportedby the fact that viruses bearing V3 loops containing the GPGQmotif induce a profile of anti-V3 antibodies in humans differentfrom that of viruses bearing GPGR (31, 43).

Small structural changes in the V3 region, such as the changein a single torsion angle in the 2219-bound V3, can lead tolarge overall differences when the V3 structures are compared.Although all seven of the crystallographically determined V3region structures share significant structural homology, theindividual N- and C-terminal strands that look very similarmay differ when analyzed in combination with each other (Fig.7). It may be that V3 maintains the secondary structure of itsN- and C-terminal strands, but by twisting the loop these strandscan move with respect to one another, thus placing differentsets of residues on the faces of the V3 ß-hairpin.Nevertheless, given the similarity of many of the structuresderived from crystallographic, NMR, and functional studies,the picture that emerges is one of a dynamic V3 structure witha conserved base and tip but with a flexible stem that assumespreferred alternative conformations that are influenced by itssequence, its environment in the context of gp120, and its rolein the interaction with coreceptor CCR5 or CXCR4.

The selection of neutralizing MAbs may be more effective witha V3 fusion protein than with linear V3 peptides (30, 44). TheV3 region in the fusion peptide is likely more ordered or restrictedthan in linear V3 peptides, and given the presence of the disulfidebond at its base and the correctly placed carbohydrate moieties,the fusion protein may better represent the native V3 structure(41). Undoubtedly, a successful V3-based vaccine will have tomimic one or a range of V3 conformations found on intact virusand also induce antibodies that can tolerate some sequence variabilitywithin the V3 loop. The 447-52D and 2219 structures have showntwo distinctly different ways to address this problem, throughprimary main-chain interactions between V3 and the CDR H3 ofantibody (447-52D) or by binding to a conserved face of theß-hairpin that allows variation in the crown. As moreneutralizing and nonneutralizing V3 antibody structures aredetermined, the definition of the requirements for broad neutralizationby V3 antibodies can be improved and applied to vaccine designefforts.

ACKNOWLEDGMENTS

We thank Sharon Ferguson and Constance Williams for excellenttechnical assistance and SSRL Beamline 11-1 and ALS Beamline5.0.2 for synchotron beamtime.

We gratefully acknowledge support by NIH grants GM-46192 (I.A.W.and R.L.S.), AI36085, AI27742, and HL 59725 (S.Z.-P. and M.K.G.);a grant from the Department of Veterans Affairs (S.Z.-P.); anda grant from the International AIDS Vaccine Initiative (IAVI)Neutralizing Antibody Consortium (I.A.W.).

This is manuscript 17762-MB from the Scripps Research Institute.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Biology, The Scripps Research Institute, 10550 N. Torrey Pines Road, La Jolla, CA 92037. Phone: (858) 784-9706. Fax: (858) 784-2980. E-mail for Robyn L. Stanfield: robyn{at}scripps.edu. E-mail for Ian A. Wilson: wilson{at}scripps.edu.

REFERENCES

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