CD22-Binding Peptides Derived from Anti-CD22 Ligand Blocking Antibodies Retain the Targeting and Cell Killing Properties of the Parent Antibodies and May Serve as a Drug Delivery Vehicle

Abstract

CD22 is a B-cell specific membrane glycoprotein that mediates homotypic and heterotypic cell adhesion; it also regulates B-cell receptor (BCR)-mediated signals. Monoclonal antibodies (mAb) directed at the ligand binding domain of CD22 initiate CD22-mediated signal transduction and apoptosis in B-cell lymphomas (NHL). Amino acid analysis of the complimentary determining regions (CDRs) of six different anti-CD22 ligand blocking mAb revealed a high level of sequence conservation. The heavy chain CDRs 1, 2, and 3 are 85, 40, and 38% conserved, respectively; light chain CDRs 1, 2, and 3, are 95, 90 and 90% conserved, respectively. Based on these conserved sequences, five peptides were designed and synthesized. Only the sequence derived from heavy chain CDR2 (Peptide 5) demonstrated significant B-cell binding. Peptide 5 bound to both malignant and primary B-cells with very little T-cell binding. The affinity had a Km of 5 × 10−6 M. Peptide 5 mediated killing of several NHL cell lines to a degree similar to that of the parent mAb (HB22.7). Peptide 5’s loop structure was shown to be crucial for B-cell binding and ligand blocking. Mutational analysis revealed that most Peptide 5 amino acids were critical for B cell binding. Using a CD22 transfected COS cell line, we demonstrated CD22-specific binding and CD22 ligand blocking to a degree similar to HB22.7. Finally Peptide 5 was used as a vehicle to deliver a pro-apoptotic peptide into NHL cells. Peptide 5 was fused to a BH3 death domain-containing peptide which demonstrated more effective NHL cell killing than the parent peptide.