It is based on reversible occlusion of the antigen recognition sites of mAbs through fusion with recombinant antigen fragments via a flexible linker that can be cleaved by tumor-associated proteases including MMP-9. adverse events have been described for many antibody therapeutics due to inadvertent antigen recognition in normal tissues. In the case of epidermal growth factor receptor (EGFR) antagonistic mAbs, dose-limiting toxicities are thought to be due to engagement of the receptor by the therapeutic antibody in normal Azelnidipine tissues (reviewed in refs. 2 and 3). The Erb tyrosine kinase family includes four members, of which EGFR and ErbB2/Her2 are frequently deregulated in solid tumors and are significant interest as therapeutic targets. MAbs to both antigens are GDF2 used to treat various epithelial cancers. However, EGFR antagonistic mAbs, including cetuximab,4 matuzumab,5 and the fully human panitumumab,6,7 can cause dose-limiting adverse events affecting primarily the skin and gastrointestinal system.8 A similar side effect profile is observed for small molecule inhibitors of the EGFR kinase.9 To address this problem, we have developed and tested a new design to create antibody prodrugs (Fig. 1). It is based on reversible occlusion of the antigen recognition sites of mAbs through fusion with recombinant antigen fragments via a flexible linker that can be cleaved by tumor-associated proteases including MMP-9. In the tumor microenvironment, such occluded mAbs can be activated by severing the linker and releasing the tethered antigenic epitope. We propose that these occluded antibodies be termed masked and their activated counterparts unmasked. This design was tested using two EGFR antagonistic antibodies. Open in a separate window Figure 1 Antibody prodrug concept. (A) For proof-of-principle, EGFR domain III was fused to an scFv of C225 and of 425. Point mutations in EGFR domain III favor a heterodimer. In the tumor, protease cleavage is expected to release the epitope, enabling binding of the antibody to its native. (B) Schematic view of the overall design to generate IgGs that are masked and do not bind antigen in normal tissues. Cross-masking permits the simultaneous delivery of two antibodies that synergize or target two separate tumor-associated antigens. Results and Discussion Masked anti-EGFR antibody fragments were generated by cloning mutated domain III of the soluble EGFR (sEGFRdIII) N-terminus to a cleavable linker followed by single chain variable fragment (scFv) versions of the anti-EGFR antibodies matuzumab (mAb425 or 425) and cetuximab (mAbC225 or C225) (Fig. 2A). The mutations in each construct were designed to reduce the affinity for the attached antibody and, thus, facilitate dissociation after linker cleavage. Constructs were produced without point mutations as well. To enable proteolytic cleavage, we included a metalloprotease 9 (MMP-9) substrate cleavage site in the linker, VPLSLYS.10 MMP-9 is frequently overexpressed in epithelial malignancies in which EGFR blockade may have therapeutic benefit.11C13 Open in a separate window Figure 2 Design, production and characterization of cross-masked 425/C225 scFvs. (A) Topology of masked scFv constructs, indicating point mutations in EGFRdIII for either mask. The linker sequence used in both constructs is shown in bold. (B) By size exclusion chromatography, the individual masked scFvs are monomeric, whereas the admixture Azelnidipine of C225 and 425 cross-masked scFv is consistent with a heterodimeric complex. (C) Specific cleavage of cross-masked heterodimeric Azelnidipine scFvs and individual masked scFvs Azelnidipine by MMP-9, as determined by SDS-PA GE. To address potential geometric problems of epitope association with the scFv and taking into 34.7 consideration that affinity decreases as a function of linker length,14 we designed a linker that was significantly longer than the minimal required distance. The serine-glycine rich Azelnidipine linker consists of 12 and 19 residues flanking an MMP-9 sequence, producing an end-to-end length of approximately 133 ?. Crystal structures revealed that the distance between the C-terminus of sEGFRdIII and the N-terminus of the antibody light chains is >35.1 ? for C225,15 and.