Structure/antigenicity relationship of cyclic and linear peptides mimicking the V3 loop of HIV2 envelope glycoprotein.

We report the structure and antigenicity of the third variable region (V3) of the HIV2 envelope glycoprotein by the use of linear and cyclic peptides. To this end, a peptide mimicking this region was synthesized and purified, both as an iodoacetamidated linear peptide and a disulphide-bridged cyclic peptide. The cross-reactivity of three monoclonal antibodies (mAbs) produced against the envelope glycoprotein gp140 with the linear and cyclic peptides was tested with ELISA. The results showed that the cyclic peptide is a better ligand for the 3 mAbs 125-F, 125-J and 125-K. The avidity of the mAb/peptide interaction was further analysed by determining the concentration of linear or cyclic peptide leading to 50% inhibition of mAb-peptide complex formation (K0.5). The K0.5 value of mAb 125-F, which displayed the best reactivity with gp140, was estimated to be 5 times higher for the linear (K0.5 = 1.5 x 10(-6) M) than for the cyclic peptide (K0.5 = 3 x 10(-7) M). This indicates a higher affinity of mAb 125-F for the cyclic peptide. mAb 125-J, which exhibited a lower avidity for the gp140 compared to mAb 125-F, had a similar affinity for the cyclic and the linear peptides (K0.5 = 3 x 10(-7) M). mAb 125-K had the lowest reactivity with gp140 and its binding to adsorbed peptide could not be inhibited by the soluble linear or cyclic peptide used up to 10(-5) M. These results suggest that cyclic peptides may have a higher propensity for adopting a native-like structure for the peptide/antibody interaction. Nuclear magnetic resonance experiments at 25 degrees C in phosphate buffer pH 5.4, however, showed that neither peptide displayed a well-defined structure.

A conserved sequence region of scorpion toxins rendered immunogenic induces broadly cross-reactive, neutralizing antibodies.

Scorpion toxins constitute a family of proteins with a high degree of sequence diversity but a common mode of action. Neutralization of the toxic effects of scorpion stings by serotherapy is limited due to the various serotypes expressed by these proteins. We explored the possibility of raising antibodies to conserved parts of the toxins which could recognize several members of the family. We established the variability profile of a set of 25 scorpion toxin sequences, then evaluated systematically by peptide-scanning methods the antigenicity of one scorpion toxin. The most conserved regions were generally very poorly antigenic. One exception was the N-terminal region, which is both conserved and antigenic. Antibodies were raised in rabbits against an eight-residue synthetic peptide mimicking the N-terminal region. These peptide antibodies were cross-reactive with several scorpion toxins belonging to different serotypes and neutralized both the pharmacological effects (binding to rat brain synaptosomes) and the biological activity (toxicity in mice) of the parent toxin. The molecular model of the toxin indicates that antibody binding to residues 1-8 probably either masks some residue(s) of the N-terminus critical for the biological activity or overlaps with the epitope previously defined by neutralizing monoclonal antibody. These findings could open the way for new therapeutic strategies for the medical care of envenomations.

The antigenic structure of a scorpion toxin.

Scorpion toxins constitute a family of homologous proteins that exert potent pharmacological effects on ion channels. These proteins are immunogenic and constitute a good model for investigation of the molecular basis of antigenicity. In the first part of this article we summarize the results we have obtained in recent years concerning the location of the main antigenic regions of a model toxin, toxin II of the North African scorpion Androctonus australis Hector. Then, thanks to the recently available atomic coordinates of this toxin, we analyzed the relationships between the structural features of the protein and the location of the antigenic regions: we found that antigenic regions are located at exposed parts of the molecular surface, i.e. in reverse turns and the alpha-helix. These surface parts also correspond to segments of the polypeptide chain which are most accessible to a large spherical probe modelizing an antibody molecule. Finally, we obtained a general idea of what could be the main discontinuous antigenic determinants by looking for the neighboring relationships between the most exposed residues of the protein.

Immunochemistry of scorpion toxins. Synthesis and antigenic properties of a model of a loop region specific to alpha-toxins.

A region of the toxin II of the scorpion Androctonus australis Hector, possessing a loop structure, is shown to be antigenic. Some clear hints for the probable antigenic character of this region were obtained by the protruding properties of the loop region, as assessed by accessibility computations using atomic coordinates of the toxin and Lee-Richards algorithm. A synthetic replica of the loop region was obtained in a linear and cyclised form. Within the total anti-toxin antibody population, we have found and isolated those that recognize the model peptides. A high affinity binding of these specific antibodies to the parent toxin was demonstrated, affording experimental evidence for the antigenic properties of the loop region.

Photoaffinity labeling of ANF receptor in cultured brain neurones.

A monoiodo derivative of rat atrial natriuretic factor (rANF) was shown to specifically bind to rat brain neurones in culture with low binding site capacity (10-20 fmoles per mg of protein) and high affinity (Kd = 50-100 pM). Several analogs of both rat and human ANF competed with 125I-rANF. No change in the number of binding sites was detected upon morphological differentiation of neurones in vitro. Finally a photoreactive derivative of 125I-rANF was prepared and photoaffinity labeling experiments carried out on cultured neurones. After reduction of disulfide bridges, a single band of Mr 60,000 was specifically labeled whereas without reduction, two labeled components of Mr 60,000 and 117,000 were detected.

Reduction and reoxidation of the neurotoxin II from the scorpion Androctonus australis Hector.

Reoxidation of the totally reduced scorpion neurotoxin II from Androctonus australis Hector (four disulfide bridges) has been investigated. The totally reduced toxin was highly insoluble in neutral and alkaline conditions, which prevented the use of the usual air oxidation process for renaturation. We tested a new method in which the reduced molecules were first solubilized in 10% (v/v) acetic acid and then oxidized by air through dialysis against a series of buffers with a slow pH gradient from 2.2 to 7.0 or 8.0. In this system, up to 95% of the protein was recovered in solution. Addition of reduced and oxidized glutathione accelerated refolding and also permitted a better recovery of fully active peptide as measured by both toxicity to mice and ability to displace 125I radiolabeled toxin II from its binding site on rat brain synaptosomal fractions. The reoxidation reaction could also be monitored directly by high pressure liquid chromatography. A strong effect of guanidine hydrochloride concentration as well as the temperature was observed both on the solubility of the reoxidation intermediates and on the refolding pathway. Finally, the method used, i.e. dialysis reoxidation with a pH gradient from 2.2 to 8.0 in 0.1 M sodium phosphate, 0.1 M sodium chloride, 20 mM guanidine hydrochloride, 1 mM oxidized and reduced glutathione allowed regeneration in high yield (70%) of a reoxidized toxin form indistinguishable from the native toxin. A minor stable and inactive molecular species (about 30%) showing a difference in mobility by electrophoresis was also detected.