Taghi Manshouri

Biological activities of rabbit antibodies against synthetic human thyrotropin receptor peptides representing thyrotropin binding regions

Recently, we have shown that the thyrotropin (TSH) binding regions of human thyrotropin receptor (TSHR) reside in two areas within residues 12-44 and 308-344. Serial antisera were raised against four overlapping synthetic peptides representing these two regions of TSHR (peptides 12-30, 24-44, 308-328, and 324-344) and were investigated for their ability to stimulate or block the cultured porcine thyroid cells. In addition, serum concentrations of triiodothyronine (T3) and thyroxine (T4) in serial sera obtained from each rabbit were examined. It was shown that residues of 12-30 and 324-344 of TSHR, respectively, are the site (at least a part of the site) where stimulating (TSAb) and blocking type (TSBAb) immunoglobulins are directed.

The regions of alpha-neurotoxin binding on the extracellular part of the alpha-subunit of human acetylcholine receptor.

A set of 18 synthetic uniform overlapping peptides spanning the entire extracellular part (residues 1–210) of the α-subunit of human acetylcholine receptor were studied for their binding activity of125I-labeled α-bungarotoxin and cobratoxin. A major toxin-binding region was found to reside within peptide α122–138. In addition, low-binding activities were obtained with peptides α34–49 and α194–210. It is concluded that the region within residues α122–138 constitutes a universal major toxin-binding region for acetylcholine receptor of various species.

Synthesis of tolerogenic monomethoxypolyethylene glycol and polyvinyl alcohol conjugates of peptides

Recent studies from this laboratory showed that tolerogenic peptide conjugates are very effective reagents for obtaining epitope-specific immunosuppression of antibody responses to immunopathogenic sites on multideterminant complex protein antigens. This paper describes the procedure for synthesis of well-defined conjugates of peptides to monomethoxypoly-ethylene glycol (mPEG) or to polyvinyl alcohol (PVA). The first step involves succinylation of the hydroxyl groups on the polymers by reaction with succinic anhydride. The polymer is then coupled via the carboxyl of the succinyl group to the α-NH2 of the completed peptide on the synthetic resin, while maintaining intact all the side-chain protecting groups on the peptide. The mPEG or PVA-peptide conjugates are cleaved from the resin and purified by standard procedures. This method results in the preparation of conjugates in which one molecule of tolerogenic polymer is coupled to the N-terminal of an otherwise unaltered peptide molecule.

Mapping by synthetic peptides of the binding sites for acetylcholine receptor on α-bungarotoxin

A set of seven peptides constituting the various loops and most of the surface areas of α-bungarotoxin (BgTX) was synthesized. In appropriate peptides, the cyclical (by a disulfide bond) monomers were prepared. In all cases, the peptides were purified and characterized. The ability of these peptides to bindTorpedo californica acetylcholine receptor (AChR) was studied by radiometric adsorbent titrations. Three regions, represented by peptides 1–16, 26–41, and 45–59, were able to bind125I-labeled AChR and, conversely,125I-labeled peptides were bound by AChR. In these regions, residues Ile-1, Val-2, Trp-28 and/or Lys-38, and one or all of the three residues Ala-45, Ala-46, and Thr-47, are essential contact residues in the binding of BgTX to receptor. Other synthetic regions of BgTX showed little or no AChR-binding activity. The specificity of AChR binding to peptides 1–16, 26–41, and 45–59 was confirmed by inhibition with unlabeled BgTX. It is concluded that BgTX has three main AChR-binding regions (loop I with N-terminal extension and loops II and III extended toward the N-terminal by residues 45–47).

A novel peptide mimicking the interaction of α-neurotoxins with acetylcholine receptor

A peptide corresponding to residues 26–41 of α-bungarotoxin, and closed by a disulfide bond between two cysteine residues at the amino and C terminal ends of the peptide, was synthesized and the monomeric form was purified. The peptide, which represents the exposed part of the long central loop of the toxin molecule, was examined for binding to acetylcholine receptor. The peptide was shown by radiometric titrations to bind radiolabeled receptor, and radiolabeled peptide was bound by receptor. The specificity of the binding was confirmed by inhibition with the parent toxin. A synthetic analog of the peptide in which Trp-28 was replaced by glycine had very little (10%) of the original activity. Succinylation of the amino groups of the peptide resulted in virtually complete (98%) loss of the binding activity. These results indicate that a shortened loop peptide corresponding to the region 26–41 of α-bungarotoxin exhibits binding activities mimicking those of the parent molecule. In this region, Trp-28, and one or both of Lys-26 and Lys-38, are essential contact residues in the binding to receptor.

Antibody and T-cell recognition of α-bungarotoxin and its synthetic loop-peptides

Peptides representing the loops and surface regions of α-bungarotoxin (BgTX) and control peptide analogs in which these sequences were randomized were synthesized and used to map the recognition profiles of the antibodies and T-cells obtained after BgTX immunization. Also, the abilities of anti-peptide antibodies and T-cells to recognize the immunizing peptide and BgTX were determined. Three regions of BgTX were immunodominant by both rabbit and mouse anti-BgTX antibodies. These regions resided within loops L1 (residues 3–16), L2 (residues 26–41) and the C-terminal tail (residues 66–74) of the toxin. The regions recognized by BgTX-primed T-lymphocytes were mapped in five mouse strains: C57BL6(H-2b), Balbc (H-2d), CBA (H-2k), C3HHe (H-2k) and SJL (H-2s). The H-2b and H-2d haplotypes were high responders to BgTX, while the H-2k and H-2s were intermediate responders. The T-cell recognition profile of the peptides varied with the haplotype, consistent with Ir gene control of the responses to the individual regions. The submolecular specificities of antibodies and T-cells were compared in three of the mouse strains (C57BL6, Balbc and SJL). In a given mouse strain, there were regions that were strongly recognized by both antibodies and T-cells as well as regions that were predominantly recognized either by antibodies or by T-cells. The peptides were used as immunogens in their free form (i.e. without coupling to any carrier) in two of the mouse strains, Balbc and SJL. In both mouse strains, the peptides gave strong antibody responses. Antibodies against peptide L2 showed the highest binding to intact BgTX. Antibodies against the other peptides exhibited lower binding activity to the intact toxin, and this activity was dependent on the peptide and the mouse strain. The response of peptide-primed T-cells to a given immunizing peptide was not related to whether this region was immunodominant with BgTX-primed T-cells. The ability of peptide-primed T-cells to recognize the intact toxin varied with the peptide and was dependent on the host strain. These results indicate that anti-peptide antibody and T-cell responses are also under genetic control and that their ability to cross-react with the parent toxin is not only dependent on the conformational exposure of the correlate region in intact BgTX.

Recognition of inter-transmembrane regions of acetylcholine receptor α subunit by antibodies, T cells and neurotoxins: implications for membrane-subunit organization

Three regions of the α chain of Torpedo californica acetylcholine receptor (AChR), corresponding to residues α262–276, α388–408 and α427–437 were synthesized, purified and characterized. The first two peptides have been proposed to occupy inter‐transmembrane regions while the third represented the C‐terminal segment, proposed by various models to be either extracellular or intracellular. Peptide α388–408 stimulated a good response in the AChR‐primed T cells of H‐2s haplotype mice, a low response in the H‐2q haplotype and no response in the H‐2b haplotype. Peptide α427–437 stimulated AChR‐primed T cells of the H‐2s haplotype, but caused no response in the q and b haplotypes. Peptide α262–276 evoked no in vitro stimulation in any of the s, q or b haplotypes. In antibody binding studies, peptide α388–408 bound antibodies raised against free AChR or against membrane‐bound AChR. The other two peptides showed little or no binding activity. Further, peptide α388–408 bound specifically both 125‐I‐labelled bungarotoxin and cobratoxin, while the other two peptides had no binding activity. These results were consistent with only one of the models for subunit organization with‐in the membrane.