The 24‐amino‐acid peptide RP135 (NNTRKSIRIQRGPGRAFVTIGKIG) corresponds in its amino acid sequence to the principal neutralizing determinant of the human immunodeficiency virus type‐1, IIIB isolate (HIV‐1IIIB, residues 308– 331 of the envelope glycoprotein gp120). In order to map the antigenic determinant recognized by 0.5β, the complex of RP135 with an anti‐gp120 HIV neutralizing antibody, 0.5β, which cross reacts with the peptide, was studied by using two‐dimensional NMR spectros‐copy. A combination of homonuclear Hartmann Hahn two‐dimensional experiment and rotating‐frame Overhauser enhancement spectroscopy of the Fab/peptide complex measured in H2O was used to eliminate the resonances of the Fab and the tightly bound peptide residues and to obtain sequential assignments for those parts of the peptide which retain considerable mobility upon binding. In this manner, a total of 14 residues (Ser6–Thrl9) were shown to be part of the antigenic determinant recognized by the antibody 0.5β. Lys5 and Ile20 were found to retain considerable mobility in the bound peptide while their amide protons undergo significant change in chemical shift upon binding. This observation suggests that these two residues are at the boundaries of the determinant recognized by the antibody. Competitive binding experiments using truncated peptides strongly support the NMR observations.
The principal neutralizing determinant (PND) of human immunodeficiency virus type 1 (HIV-1) is located in the third hypervariable region (V3) of the virus envelope glycoprotein gp120. The conformation of a V3 peptide of HIV-1IIIB bound to the Fab fragment of an anti-gp120 HIV neutralizing antibody, 0.5beta, was studied by 1H NMR spectroscopy. This 18-residue peptide represents the epitope recognized by 0.5beta and encompasses most of the PND. The slow off-rate of the peptide prevents the observation of peptide/Fab interactions as well as intramolecular interactions within the bound peptide by transferred nuclear Overhauser enhancement (TRNOE). To detect and assign interactions within the bound peptide in the 52 kDa complex, NOESY difference spectra were measured using three strategies: (a) deuteration of peptide residues, (b) Arg two head right arrow Lys replacements, and (c) truncation of the peptide antigen. Each difference spectrum was calculated between NOESY spectra measured for two Fab complexes in which the bound peptides differed in their deuteration or in their sequence. The difference spectra revealed numerous interactions between the N-terminus of the epitope (Arg-4, Lys-5, Ser-6, Ile-7, and Ile-9) and its C-terminus (Phe-17, Val-18, Thr-19, and Ile-20). The assigned NOE interactions within the bound peptide were translated into distance restraints that were used to calculate the conformation of the bound peptide by the hybrid distance geometry/simulated annealing method. A total of 39 long-range (residues i - j >> 4), 14 short-range, and 69 intraresidue NOE interactions within the bound peptide have been assigned. Twelve structures without NOE constraint violations were obtained, having a 1.6 A rms deviation for the backbone atoms. The peptide forms a 10-residue loop, while the two segments flanking this loop, KSI and VTI, interact extensively with each other and possibly form antiparallel beta-strands. This loop conformation could be observed due to the unusual large size (17 residues) of the antigenic determinant recognized by 0.5beta.
The 24-amino-acid peptide RP135 (NNTRKSIRIQRGPGRAFVTIGKIG) corresponds in its amino acid sequence to the principal neutralizing determinant of the human immunodeficiency virus type-1, IIIB isolate (HIV-1IIIB, residues 308-331 of the envelope glycoprotein gp120). In order to map the antigenic determinant recognized by 0.5 beta, the complex of RP135 with an anti-gp120 HIV neutralizing antibody, 0.5 beta, which cross reacts with the peptide, was studied by using two-dimensional NMR spectroscopy. A combination of homonuclear Hartmann Hahn two-dimensional experiment and roating-frame Overhauser enhancement spectroscopy of the Fab/peptide complex measured in H2O was used to eliminate the resonances of the Fab and the tightly bound peptide residues and to obtain sequential assignments for those parts of the peptide which retain considerable mobility upon binding. In this manner, a total of 14 residues (Ser6-Thr19) were shown to be part of the antigenic determinant recognized by the antibody 0.5 beta. Lys5 and Ile20 were found to retain considerable mobility in the bound peptide while their amide protons undergo significant change in chemical shift upon binding. This observation suggests that these two residues are at the boundaries of the determinant recognized by the antibody. Competitive binding experiments using truncated peptides strongly support the NMR observations.
To increase our understanding of the molecular basis for antibody specificity and for the cross-reactivity of anti-peptide antibodies with native proteins it is important to study the three-dimensional structure of antibody complexes with their peptide antigens. For this purpose it may not be necessary to solve the structure of the whole antibody complex but rather to concentrate on elucidating the combining site structure, the interactions of the antibody with its antigen and the bound peptide conformation. We have developed an NMR methodology based on two-dimensional difference spectrum measurements which extract the information concerning antibody-peptide interactions and intramolecular interactions in the bound ligand from the crowded and unresolved spectrum of the Fab complex. These measurements yield restraints on interproton distances in the complex which are used to dock the peptide into calculated models for the antibodies' combining sites. Comparison of the interactions of three antibodies against a cholera toxin peptide (CTP3), which differ in their cross-reactivity with the toxin, yields information about the size and conformation of antigenic determinants recognized by antibodies, the structure of their combining sites and relationships between antibodies' primary structure, and their interactions with peptide antigens.
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