Immunochemistry of sperm whale myoglobin. XV. Accurate delineation of the single antigenic reactive region in sequence 1-55 of myoglobin by chemical derivatives of the peptide carrying the region: conclusions relating to antigenic structures of proteins

Use of immunoadsorbents for the study of antibody binding to sperm whale myoglobin and its synthetic antigenic sites

Conditions for preparing immunoadsorbents of sperm-whale myoglobin and its five synthetic antigenic sites and for desorption of radiolabeled antibodies from the immunoadsorbents were studied. In immunoadsorbent titration studies, the sum of the amounts of antibodies bound in the plateau (maximum binding) by the adsorbents of the five sites accounted quantitatively for the entire (100%) antibody response to sperm-whale myoglobin.

Enzymic and immunochemical properties of lysozyme. X. Conformation, enzymic activity and immunochemistry of lysozyme reduced at two carboxyl groups

Reduction of lysozyme by diborane, followed by air oxidation of the reduced disulfides and chromatography on CM-cellulose, yielded a homogeneous derivative. In the derivative, the carboxyl groups of aspartic acid 119 and the end-chain leucine residue were reduced to their corresponding alcohols. Correct re-forming of the disulfide bonds was demonstrated by peptide mapping of the tryptic hydrolysates of the derivative and lysozyme without breaking the disulfide bonds, followed by identification of the disulfide-containing peptides. Correct disulfide pairing in the two-disulfide peptide in the tryptic hydrolysate was established from its immunochemical behavior. Preparations of the two-disulfide fragment from lysozyme and derivative had equal inhibitory activities (26 or 32%) of the reaction of lysozyme with two homologous antisera. In ORD measurements, lysozyme and the derivative had equal rotatory powers at neutral pH. However, the bo value for the derivative decreased by about 10%. Below pH 6.4 and above pH 8.0, the derivative was less rotatory than native lysozyme. In CD measurements at neutral pH, the negative ellipticity bands at 220 and 208 nm showed little or no decrease in the derivative relative to the native protein. Although conformational differences between the derivative and its parent protein were almost undetectable by ORD and CD measurements, they were readily detected by chemical monitoring of the conformation. In the derivative, both accessibility to tryptic hydrolysis and reducibility of the disulfide bonds increased markedly. The enzymic activity of the derivative was decreased but retained the same pH optimum. With antisera to lysozyme or antisera to the derivative, lysozyme and its derivative possessed equal antigenic reactivities. The immunochemical findings further confirm the correct refolding of the disulfides. Also, they indicate that aspartic acid 119 and the C-terminal leucine residue are not part of an antigenic reactive region in lysozyme.