Rational design of cytotoxic T-cell inhibitors.

This study describes the use of the CD8/major histocompatibility complex (MHC) class I crystal structure as a template for the de novo design of low-molecular-weight surface mimetics. The analogs were designed from a local surface region on the CD8 alpha-chain directly adjacent to the bound MHC class I, to block the protein associations in the T-cell activation cluster that occur upon stimulation of the cytotoxic T lymphocytes (CTLs). One small conformationally restrained peptide showed dose-dependent inhibition of a primary allogeneic CTL assay while having no effect on the CD4-dependent mixed lymphocyte reaction (MLR). The analog's activity could be modulated through subtle changes in its side chain composition. Administration of the analog prevented CD8-dependent clearance of a murine retrovirus in BALB/c mice. In C57BL/6 mice challenged with the same retrovirus, the analog selectively inhibited the antiviral CTL responses without affecting the ability of the CTLs to generate robust allogeneic responses.

Structure and function of procollagen C-proteinase (mTolloid) domains determined by protease digestion, circular dichroism, binding to procollagen type I, and computer modeling.

Procollagen C-proteinase-2 (pCP-2, mTld) is derived from the longest splicing variant of the gene encoding bone morphogenetic protein 1 (BMP-1). The variants have identical amino terminal signal peptides, prodomains and astacin-like protease domains. However, they differ in the length of their carboxy terminal part, which in pCP-2 has the composition CUB1, CUB2, EGF-like1, CUB3, EGF-like2, CUB4, CUB5, and C-tail. In the shorter form, pCP-1 (i.e., BMP-1), the sequence ends after the CUB3-domain. Using a combination of mutagenesis and structural approaches, we have investigated the structure and function of subfragments of pCP-2. The full-length latent recombinant enzyme and its N-terminally truncated form lacking the prodomain were tested for their enzymic activity. The intact protein showed only partial processing of procollagen type I, whereas the truncated form expressed enzymic activity indistinguishable from its native counterpart purified from chick embryo tendons. These results clearly demonstrated that the prodomain is required for the latency of the enzyme but not for its correct folding. Limited proteolysis of the recombinant protein with alpha-chymotrypsin produced four discrete fragments revealing the location of cleavage sites between the repetitive CUB/EGF domains. The results provide evidence that the CUB sequences form independently folded modules that are stabilized by two pairs of internal disulfide bridges. The modules are linked to each other by more flexible, hinge-like peptides. Solid-phase binding assays with isolated CUB domains and immobilized procollagen type I demonstrated that the first three but not the last two CUB domains specifically bound to the substrate. To define putative sites for CUB-CUB or CUB-substrate interactions, we generated molecular models for pCP-2 CUB domains. The models were obtained using as a template the structure of CUB domain in zona pellucida adhesion protein PSP-I/PSP-II from porcine sperm. The predicted conformations for homology models were, subsequently, confirmed by circular dichroism spectroscopy of polypeptide domains isolated following limited proteolysis with alpha-chymotrypsin.

Domain 5 of high molecular weight kininogen (kininostatin) down-regulates endothelial cell proliferation and migration and inhibits angiogenesis.

We have demonstrated that high molecular weight kininogen (HK) binds specifically on endothelial cells to domain 2/3 of the urokinase receptor (uPAR). Inhibition by vitronectin suggests that kallikrein-cleaved HK (HKa) is antiadhesive. Plasma kallikrein bound to HK cleaves prourokinase to urokinase, initiating cell-associated fibrinolysis. We postulated that HK cell binding domains would inhibit angiogenesis. We found that recombinant domain 5 (D5) inhibited endothelial cell migration toward vitronectin 85% at 0.27 microM with an IC(50) (concentration to yield 50% inhibition) = 0.12 microM. A D5 peptide, G486-K502, showed an IC(50) = 0.2 microM, but a 25-mer peptide from a D3 cell binding domain only inhibited migration 10% at 139 microM (IC(50) > 50 microM). D6 exhibited weaker inhibitory activity (IC(50) = 0.50 microM). D5 also potently inhibited endothelial cell proliferation with an IC(50) = 30 nM, while D3 and D6 were inactive. Using deletion mutants of D5, we localized the smallest region for full activity to H441-D474. To further map the active region, we created a molecular homology model of D5 and designed a series of peptides displaying surface loops. Peptide 440-455 was the most potent (IC(50) = 100 nM) in inhibiting proliferation but did not inhibit migration. D5 inhibited angiogenesis stimulated by fibroblast growth factor FGF2 (97%) in a chicken chorioallantoic membrane assay at 270 nM, and peptide 400-455 was also inhibitory (79%). HK D5 (for which we suggest the designation, "kininostatin") is a potent inhibitor of endothelial cell migration and proliferation in vitro and of angiogenesis in vivo. (Blood. 2000;95:543-550)

A synthetic mimetic of CD4 is able to suppress disease in a rodent model of immune colitis.

CD4+ mucosal T cells mediate the intestinal inflammation in Crohn's disease and may serve as an important target for immune intervention. Here we assessed the therapeutic effect of a synthetic mimetic of CD4 designed to mimic both the sequence and conformation of the complementarity-determining region 3 of murine CD4 V1 domain (rD-mPGPtide) in a mouse colitis model using immunization with 2,4,6-trinitrobenzene sulfonic acid (TNB). i.v. administration of the rD-mPGPtide but not control scrambled peptide could suppress severe inflammation in the chronic colitis mouse model. After treatment with the rD-mPGPtide, a striking improvement of diarrhea and acute wasting disease was observed with decreased mortality. Serum anti-TNB antibody titers, CD45RBlowCD4+ T cells in the lamina propria and IFN-gamma mRNA expression in the mucosa were significantly decreased with the rD-mPGPtide treatment. Anti-CD4 antibody also suppressed disease by depletion of CD45RBhighCD4+ T cells in the colonic mucosa. The observation that the synthetically engineered analogue of murine CD4 inhibits inflammation in a rodent disease model by different mechanisms than anti-CD4 antibody suggests that a human version of this peptide has potential therapeutic utility in CD4+ mucosal T cell-mediated intestinal inflammation in Crohn's disease.

Coagulation factor IX residues G4-Q11 mediate its interaction with a shared factor IX/IXa binding site on activated platelets but not the assembly of the functional factor X activating complex.

High-affinity, specific factor IX/IXa binding to platelets is mediated at least in part by amino acids (G4-Q11) exposed on the surface of the gamma-carboxyglutamic acid (Gla) domain. Rationally designed, conformationally constrained synthetic peptides were screened for their capacity to inhibit factor IXa binding to platelets. Each of these peptides (G4-Q11, S3-L6, and F9-Q11) acted alone to inhibit factor IXa binding to approximately 50% of the 500-600 sites/platelet with Ki values of 2.9 nM (G4-Q11), 24 nM (S3-L6), and 240 nM (F9-Q11), compared with native factor IXa (Ki approximately 2.5 nM). The two peptides S3-L6 and F9-Q11 added together at equimolar concentration demonstrated approximately 50-fold synergism (Ki = 2.4 nM). Although both factor IX and the Gla peptide (G4-Q11) displaced 100% of bound factor IX and approximately 50% of bound factor IXa, factor IX was ineffective (at > 1000-fold molar excess) and the Gla domain peptide (G4-Q11) was relatively ineffective (Ki = 165 microM) in inhibiting platelet receptor-mediated factor X activation by factor IXa. We conclude that the Gla domain (G4-Q11) of factor IXa contains two conformationally constrained loop structures that mediate binding of factor IX/IXa to a shared site on activated human platelets which is separate and distinct from the site used by the enzyme, factor IXa, for assembly of the factor X activating complex.

A structure-based approach to designing synthetic CD8alpha peptides that can inhibit cytotoxic T-lymphocyte responses.

CD8 molecules function as co-receptors on cytotoxic T lymphocytes (CTLs), interacting with a nonpolymorphic region of the major histocompatibility complex (MHC) class I a3 domain on antigen-presenting cells. Analogues were designed from a structural model of the mouse CD8a molecule to identify surfaces involved in CD8 function. Peptides were screened for in vitro biological activity on alloreactive CTLs, and analogue SC4 (p54-59) was found to be inhibitory during both the generation and effector stages. SC4 was also able to significantly prolong skin allograft survival across a MHC class I barrier. Thus, such CD8 analogues may have therapeutic potential as immunoregulators of CTL immune responses.

Peptide analogs that inhibit IgE-Fc epsilon RI alpha interactions ameliorate the development of lethal graft-versus-host disease.

Significant increases in serum levels of IgE have often been observed in allogeneic bone marrow transplantation patients and have generally been thought to be diagnostic of graft-versus-host disease (GVHD), rather than an agent involved in the pathogenesis of the disease. Experimental murine GVHD models have also indicated associations of hyper-IgE activity, yet the role of IgE in GVHD pathogenesis has never been tested directly. In the current study, we have tried to address this issue by using recently developed peptide analog antagonists for the interaction of IgE with the Fc epsilon RI receptor, which is necessary for triggering mast cells and other cell types when cross-linked by antigens. A synthetic cyclized 13-amino acid peptide was previously designed from the modeled C-C' loop region of the Fc epsilon RI alpha-chain and was found to act as a competitive inhibitor of IgE-Fc epsilon RI alpha binding. The peptide was generated in two forms, a cyclic L-(L-IgEtide) and retro D-amino acid composition (rDIgEtide), the latter to increase resistance to protease degradation for in vivo applications. These two inhibitor peptides were then used to test the hypothesis that IgE could be involved in the pathogenesis of acute GVHD, in the B10.D2-->DBA/2 (900 cGy) strain combination, with GVHD directed to minor histocompatibility antigens. Both peptides demonstrated significant inhibition of the development of lethal GVHD, supporting the involvement of IgE at some level of disease pathogenesis.

A CD4-CDR3 peptide analog inhibits both primary and secondary autoreactive CD4+ T cell responses in experimental allergic encephalomyelitis.

A structure-based design approach was used to develop a cyclized peptide analog of the murine CD4-CDR3-like region as a potential inhibitor of autoimmune CD4+ T cells responsible for the pathogenesis of experimental allergic encephalomyelitis (EAE). Our results indicate that this peptide, referred to as rD-mPGPtide, is able to significantly inhibit the clinical and pathologic symptoms of EAE in the SJL mouse model when administered on day 12 of induction. The optimum effective dosage range for the peptide, injected i.v., was between 0.125 and 0.5 mg and dosages of as high as 5 mg had no observable toxic effects. Treated mice had normal levels of lymphocytes less than 2 wk later and exhibited normal in vitro primary responses to alloantigen and secondary responses to keyhole limpet hemocyanin Ag. The specificity of the rD-mPGPtide treatment for autoreactive T cells was demonstrated by inhibiting proteolipid protein (p139-151)-induced EAE and finding that the lymph node T cells from these mice had suppressed responses to this Ag, but normal responses to alloantigen or other nominal Ag. Importantly, rD-mPGPtide was found to be effective on secondary T cell responses in an EAE rechallenge situation and was able to establish conditions for long-term resistance to further Ag exposure. Analysis of the cytokine profile of responding T cells during late effector stages of disease revealed that the levels of IFN-gamma and IL-4 are significantly reduced in rD-mPGPtide-treated mice. These results strongly suggest that the administration of a CD4-CDR3 peptide analog is an effective therapeutic approach for the inhibition of the CD4+ T cell-mediated autoimmune response in EAE.

Identification of a human CD4-CDR3-like surface involved in CD4+ T cell function.

The CD4 molecule is expressed on the surface of helper T cells. This molecule contains four tandem external immunoglobulin-like domains (D1-D4), a transmembrane domain, and a cytoplasmic tail. Through the use of molecular modeling techniques, peptide analogs of the CDR3-like region of the human CD4 molecule, analog hPGP, a cyclized peptide 13 amino acids long, was synthesized and tested for its ability to inhibit proliferation in human mixed lymphocyte reactions. A conservative amino acid substitution was made at position 5 (D --> N) to increase its activity and designated hPGP(N). A series of alanine substitution peptides were synthesized based on the sequence of hPGP(N) to determine the importance of each residue to the peptide's function. The substitutions of amino acids in positions 3, 7, and 8 had essentially no effect on the inhibitory activity of hPGP(N), while substitutions of amino acids in positions 4 and 6 increased its inhibitory effect. Alanine substitutions of amino acids in positions 2, 5, and 9 dramatically decreased the inhibitory effect of analog hPGP(N). Molecular modeling of the native CD4-CDR3-like domain suggested that the residues corresponding to positions 2, 5, and 9 of the peptide formed a contiguous surface representing the active site.

Structure based design and characterization of peptides that inhibit IgE binding to its high-affinity receptor.

We have designed synthetic peptide inhibitors of the interaction between IgE and its high affinity receptor, Fc epsilon RI. The structure of the second domain of CD2 was used as a modelling template for the second alpha-chain domain of Fc epsilon RI, the C-C' loop of which has been implicated in the interaction with IgE. An L-amino acid peptide and a retro-enantiomeric D-amino acid peptide were designed to mimic the conformation of the C-C' region. Both peptides were cyclized by disulphide bond formation between terminal cysteine residues, and show mirror image symmetry by circular dichroism analysis. The C-C' peptide mimics act as competitive inhibitors of IgE binding. The cyclic L- and retro D-peptides exhibited KDs of approximately 3 microM and 11 microM, respectively, for IgE. Further, the peptides inhibit IgE-mediated mast cell degranulation, an in vitro model of an allergic response.

Thrombin-induced platelet aggregation is inhibited by the heptapeptide Leu271-Ala277 of domain 3 in the heavy chain of high molecular weight kininogen.

The ability of kininogens to modulate thrombin-induced aggregation of human platelets has been assigned to domain 3 (D3) in the common heavy chain coded for by exons 7, 8, and 9 of kininogen gene. We expressed each of the exons 7, 8, and 9, and various combinations as glutathione S-transferase fusion proteins in Escherichia coli. Each of the exon products 7 (Lys236-Gln292), 9 (Val293-Gly328), and 8 (Gln329-Met357), and their combinations were evaluated for the ability to inhibit thrombin induced platelet aggregation. Only products containing exon 7 inhibited platelet aggregation induced by thrombin with an IC50 of > 20 microM. A deletion mutant of exon 7 product, polypeptide 7A product (Lys236-Lys270) did not block thrombin-induced platelet aggregation, while 7B product (Thr255-Gln292) and 7C product (Leu271-Gln292) inhibited aggregation. These findings indicated that the inhibitory activity is localized to residues Leu271-Gln292. Peptides Phe279-Ile283 and Phe281-Gln292 did not block thrombin, and Asn275-Phe279 had only minimal inhibitory activity. A heptapeptide Leu271-Ala277 inhibited thrombin-induced aggregation of platelets with an IC50 of 65 microM. The effect is specific for the activation of platelets by thrombin but not ADP or collagen. No evidence for a thrombin-kininogen complex was found, and neither HK nor its derivatives directly inhibited thrombin activity. Knowledge of the critical sequence of kininogen should allow design of compounds that can modulate thrombin activation of platelets.

Stabile D-peptide analog of insulin-like growth factor-1 inhibits smooth muscle cell proliferation after carotid ballooning injury in the rat.

Restenosis after angioplasty is believed to result from stimulation of smooth muscle cells (SMC) by various growth-promoting factors as a consequence of endothelial injury. In this study we have tested the hypothesis that insulin-like growth factor-1 (IGF-1)/IGF-1 receptor (IGF-1R) interaction is a rate-limiting step for SMC replication by blocking this interaction with a synthetic D-amino acid peptide structurally resembling the D-domain of IGF-1. After rat carotid artery denudation, semiquantitative PCR analysis demonstrated a significant elevation of IGF-1, platelet-derived growth factor B, transforming growth factor beta 1, and epidermal growth factor mRNAs 10 days after endothelial injury, concomitantly with the induction of intimal SMC proliferation and intimal thickening. Administration of 10-30 micrograms.kg-1.day-1 of D-analog of IGF-1, devoid of proteolytic degradation in body fluids, reduced intimal SMC replication by 60-70%. The peptide also inhibited [3H]TdR incorporation and [3H]glycine incorporation in cultured SMCs by 60-80%, whereas a "scrambled" control peptide consisting of the same amino acids had no effect. The results suggest that IGF-1/IGF-1R interaction is a rate-limiting step for SMC replication. Blocking of this interaction with stabile D-peptide analog of IGF-1 at the level of IGF-1R may offer an entirely new approach for the prophylaxis and treatment of restenosis after cardiac revascularization procedures.

Identification and characterization of a binding site for platelets in the Apple 3 domain of coagulation factor XI.

Activated platelets expose a specific, reversible high affinity (Kdapp congruent to 10 nM) binding site (n congruent to 1500 sites/platelet) for factor XI that requires the presence of high molecular weight kininogen (HK) and ZnCl2 (Greengard, J. S., Heeb, M. J., Ersdal, E., Walsh, P. N., and Griffin, J. H. (1986) Biochemistry 25, 3884-3890). Synthetic, conformationally constrained peptides from four tandem repeat (Apple) domains were tested for their capacity to inhibit 125I-factor XI binding to platelets. A peptide from the Apple 3 (A3) domain (Asn235-Arg266) inhibits factor XI binding to platelets in the presence of HK (42 nM), CaCl2 (2 mM), and ZnCl2 (25 microM), with a Ki congruent to 10 nM which is identical to the Kd for factor XI binding to platelets. A peptide from the A1 domain (Phe56-Ser86) partially inhibits factor XI binding to platelets (Ki congruent to 6 microM) by inhibiting factor XI binding to HK, whereas peptides from the A2 and A4 domains have no effect. Using computer modeling for rational design, conformationally constrained peptides were synthesized (Pro229-Gln233, Thr241-Leu246, and Ser248-Ser261) each of which acted alone and synergistically when added together to inhibit factor XI binding to platelets. Finally, the 125I-labeled A3 domain peptide (Asn235-Arg266) was found to bind to thrombin-activated platelets in a specific, reversible, and saturable manner. Thus, the sequence of amino acids Asn235-Arg266 of the A3 domain of factor XI comprises a contact surface for interaction with a platelet receptor.

Binding of high-molecular-mass kininogen to the Apple 1 domain of factor XI is mediated in part by Val64 and Ile77.

We have previously demonstrated the presence of a binding site for high-molecular-mass kininogen (HK), spanning residues Val59-Lys83, in the first Apple (A1) domain in the heavy-chain region of factor XI. We have now prepared conformationally constrained synthetic peptides and recombinant A1 domain (rA1) constructs to identify the specific amino acid residues that constitute the HK-binding site. Expression of the A1 domain (Glu1-Ser90) was achieved in a bacterial expression system following PCR amplification of the A1 domain from factor XI cDNA and ligation into an expression plasmid. The rA1 inhibited factor XI binding to HK [Ki approximately (2-3) x 10(-7) M] in a manner indistinguishable from purified factor XI, indicating that all the information necessary for binding HK is contained within the A1 domain. To identify specific amino acid residues involved in binding HK, conformationally constrained peptides were synthesized containing conservative amino acid substitutions at residues suspected to contain side chains involved in binding, including Val64-->Ala, Glu66-->Ala, Arg73-->Ala and Ile77-->Ala. Because normal results were obtained with all peptides with the exception of Val64-->Ala and Ile77-->Ala, which failed to compete normally with factor XI for binding to HK, we prepared two mutant rA1 domains (Val64-->Ala and Ile77-->Ala) by PCR-based site-directed mutagenesis, both of which exhibited diminished capacity to inhibit factor XI binding to HK. Competition studies with prekallikrein (PK) and a PK-dependent synthetic peptide suggested that PK and factor XI have a common surface in the A1 domain for binding HK of which Val64 is a part. We conclude that the binding of factor XI to HK is mediated at least in part by Val64 and Ile77 in the A1 domain of factor XI.

High-affinity, specific factor IXa binding to platelets is mediated in part by residues 3-11.

To identify the amino acids in the Gla domain that mediate factor IXa binding to human platelets, we have used chimeric molecules and point mutations in the Gla domain of recombinant factor IX, based on molecular modeling using the coordinates of the Gla domain of bovine prothrombin, which reveals two surface structures whose sequences differ among factor IX, factor X, and factor VII. Binding to thrombin-activated platelets of factor IXa in the presence of factor VIIIa (2 units/mL) and factor X (1.5 microM) revealed a stoichiometry of approximately 550 sites per platelet with a Kd of approximately 0.65 nM compared with a Kd of approximately 2.5 nM in the absence of factor VIIIa and factor X. In contrast, mutations of factor IX to factor X residues at positions 4 and 5 or at positions 9, 10, and 11 results in decreases in the number of sites and affinity of factor IXa binding in the presence or absence of factor VIIIa and factor X. A chimera consisting of the Gla domain of factor VII with factor IX residues at positions 33, 34, 35, 39, and 40 displayed abnormal factor IXa binding and a decreased Vmax and a normal Km for factor X activation, and the replacement of amino acid residues 3-10 with those of factor IX restored normal binding and factor X activation kinetics to this chimeric protein.(ABSTRACT TRUNCATED AT 250 WORDS)

A rationally designed CD4 analogue inhibits experimental allergic encephalomyelitis.

Experimental allergic encephalomyelitis (EAE) is an acute inflammatory autoimmune disease of the central nervous system that can be elicited in rodents and is the major animal model for the study of multiple sclerosis (MS). The pathogenesis of both EAE and MS directly involves the CD4+ helper T-cell subset. Anti-CD4 monoclonal antibodies inhibit the development of EAE in rodents, and are currently being used in human clinical trials for MS. We report here that similar therapeutic effects can be achieved in mice using a small (rationally designed) synthetic analogue of the CD4 protein surface. It greatly inhibits both clinical incidence and severity of EAE with a single injection, but does so without depletion of the CD4+ subset and without the inherent immunogenicity of antibody. Furthermore, this analogue is capable of exerting its effects on disease even after the onset of symptoms.

Contiguous binding and inhibitory sites on kininogens required for the inhibition of platelet calpain.

Both high molecular weight kininogen (HK) and low molecular weight kininogens (LK) are potent tight binding inhibitors of platelet calpain (Ki = 2 nM), but the molecular basis for the inhibitory function is not well delineated. The amino acid sequences of the calpain inhibitory domain 2 from human and rat HK were compared for homology with the noninhibitory domains from human and rat domain 3 and from domain 2 of rat T-kininogen, and two areas of nonconserved differences were detected. Computer three-dimensional models were constructed on a template built using the x-ray crystallographic data for cystatin, an evolutionary precursor of HK. Two nonconserved regions in the calpain inhibitory domains flank the highly conserved motif QVVAG to form a continuous surface for interaction with cysteine proteases. Three peptide sequences, components of the modeled surface, were chosen for synthesis from HK D-2: VHPISTQSPDLE (peptide 146-156, NH2-terminal), CTDNAYIDIQLRIASFSQNC (peptide 229-248, COOH-terminal), and CQRQVVAGLNFRIC (185-189, central) containing QVVAG. This last peptide differs from the natural sequence by substitutions of A185C and T195C. Peptides 185-198 and 229-248 were folded by air oxidation of their cysteine residues and then tested for their ability to inhibit calpain and papain. The folded peptide 229-248 inhibited calpain with an IC50 35 microM and unfolding reduced this effect. The folded peptide 185-198 did not inhibit calpain, but when preincubated with calpain, could block the inhibition by HK indicating a probable enzyme binding site. Peptide 146-157 did not inhibit calpain but could inhibit papain with an IC50 of 20 microM. We have thus defined separate binding and inhibitory sequences on HK which form a contiguous surface for thiol protease interactions.

Towards a structure of the HIV-1 envelope glycoprotein gp120: an immunochemical approach.

The HIV-1 surface glycoprotein gp120 binds CD4 in the initial state of virus-cell fusion. The extensive glycosylation of gp120 has thus far precluded definition of its structure by crystallographic methods. As an initial approach to a gp120 structure, the surface topology was mapped using antibodies. First, the regions of gp120 that are accessible on the surface of the native molecule, and those that are internal but exposed after denaturation, are identified. Second, epitopes for antibodies that recognize complex surface structures comprising segments of different domains are identified. Third, we define how mutations in one domain of gp120 influence the binding of antibodies to defined epitopes on other domains. These latter approaches enable us to start to understand the inter-domain interactions that contribute to the overall structure of the gp120 molecule. Information from these studies is being used to model the structures of individual gp120 domains, and the way in which these interact in the folded protein.

Immunochemical analysis of the gp120 surface glycoprotein of human immunodeficiency virus type 1: probing the structure of the C4 and V4 domains and the interaction of the C4 domain with the V3 loop.

We have probed the structure of the C4 and V3 domains of human immunodeficiency virus type 1 gp120 by immunochemical techniques. Monoclonal antibodies (MAbs) recognizing an exposed gp120 sequence, (E/K)VGKAMYAPP, in C4 were differentially sensitive to denaturation of gp120, implying a conformational component to some of the epitopes. The MAbs recognizing conformation-sensitive C4 structures failed to bind to a gp120 mutant with an alteration in the sequence of the V3 loop, and their binding to gp120 was inhibited by both V3 and C4 MAbs. This implies an interaction between the V3 and C4 regions of gp120, which is supported by the observation that the binding of some MAbs to the V3 loop was often enhanced by amino acid changes in an around the C4 region.