Induction of human B cell differentiation by Fc region activators. I. Identification of an active tetrapeptide

Synthetic peptides comprising defined sequences of CH-2 and CH-3 domains of human IgG1 induce prostaglandin E2 production from human peripheral blood mononuclear cells

Synthetic peptides Y48 and Y75 comprising sequences at exposed sites within the CH-2 and CH-3 domains of human IgG1 at a concentration of 10(-5) M, increase PGE2 production by human peripheral blood mononuclear cell (PBMC) cultures. An increase of leukocyte migration inhibitory factor (LMIF) production in PBMC cultures--as a result of synthetic peptide treatment--was also observed. This LMIF activity, to some extent, is attributed to the PGE2 production by the cells; the inhibition of leukocyte migration being abolished by the presence of indomethacine or antibody to PGE2.

Effect of human IgG1 peptides on the antigen-specific antibody response of mice in vivo

The effect of synthetic peptides--corresponding to the amino acid sequences 289-301 (Y48) and 293-301 (Y91) within the CH-2 domain in the human IgG1 was studied on the oxazolone-specific primary and secondary antibody response isotype distribution and on the sheep erythrocyte (SRBC)-specific primary IgM response. High responder (Balb/c) and low responder (C57Bl/6) mice to oxazolone hapten were treated intraperitoneally with various doses of peptides simultaneously with the first and second contact sensitization. The relative levels of oxazolone-specific IgM, IgG3, IgG1, IgG2a and IgG2b antibodies were determined by a solid phase radioimmunoassay. Y48 and Y91 peptides in a dose range of 10(-5) - 10(-8) M/animal enhanced the oxazolone-specific antibody response. This effect was more striking under suboptimal conditions: using smaller antigen dose for sensitization, cyclophosphamide pretreatment or using genetically low responder mice. SRBC-specific primary IgM response was enhanced by Y91 peptide, Y48 was ineffective.

Suppression of human B lymphocyte activation by beta-endorphin

The effects of beta-endorphin (beta-E) and contained peptides were investigated for their ability to regulate Staphylococcus aureus (SAC)-induced immunoglobulin secretion by human B lymphocytes. Co-culture of beta-E with SAC-stimulated peripheral blood-derived mononuclear cells, under serum-containing or serum-free conditions, resulted in a dose-dependent inhibition of immunoglobulin-secreting cell (ISC) formation. When the same cultures were assessed for class-specific Ig formation it was found that IgG-ISC were suppressed to a greater extent that IgA-ISC or IgM-ISC. In contrast to these results, beta-E was found to be unable to suppress SAC-induced lymphocyte proliferation. To map the suppressive activity associated with beta-E, truncated peptides based on the beta-E sequence were assessed for biological activity. The results indicated that peptides containing the N-terminal region of beta-E suppressed ISC formation. Moreover, methionine-enkephalin (beta-E 61-65) was found to be effective in suppressing ISC formation. beta-E-mediated suppression of IgG-specific ISC formation appears to involve classical receptor-ligand interaction as evidenced by the ability of naloxone to block suppression of ISC formation.