Antibodies play a central role in immunity by forming an interface with the innate immune system and, typically, mediate proinflammatory activity. We describe a novel posttranslational modification that leads to anti-inflammatory activity of antibodies of immunoglobulin G, isotype 4 (IgG4). IgG4 antibodies are dynamic molecules that exchange Fab arms by swapping a heavy chain and attached light chain (half-molecule) with a heavy-light chain pair from another molecule, which results in bispecific antibodies. Mutagenesis studies revealed that the third constant domain is critical for this activity. The impact of IgG4 Fab arm exchange was confirmed in vivo in a rhesus monkey model with experimental autoimmune myasthenia gravis. IgG4 Fab arm exchange is suggested to be an important biological mechanism that provides the basis for the anti-inflammatory activity attributed to IgG4 antibodies.
We have previously defined a panel of fully human CD20 mAb. Most of these were unexpectedly efficient in their ability to recruit C1q to the surface of CD20-positive cells and mediate tumor lysis via activation of the classical pathway of complement. This complement-dependent cytotoxicity (CDC) potency appeared to relate to the unusually slow off-rate of these human Abs. However, we now present epitope-mapping data, which indicates that all human mAb bind a novel region of CD20 that may influence CDC potency. Epitope mapping, using both mutagenesis studies and overlapping 15-mer peptides of the extracellular loops of CD20, defined the amino acids required for binding by an extensive panel of mouse and human mAb. Binding by rituximab and mouse CD20 mAb, had an absolute requirement for alanine and proline at positions 170 and 172, respectively, within the large extracellular loop of CD20. Surprisingly, however, all of the human CD20 mAb recognize a completely novel epitope located N-terminally of this motif, also including the small extracellular loop of CD20. Thus, although off-rate may influence biological activity of mAb, another critical factor for determining CDC potency by CD20 mAb appears to be the region of the target molecule they recognize. We conclude that recognition of the novel epitope cooperates with slow off-rate in determining the activity of CD20 Ab in activation of complement and induction of tumor cell lysis.
The CD38 molecule, with its high expression on Multiple Myeloma (MM), is considered a suitable target for antibody therapy of MM. We developed daratumumab (DARA), a human CD38 monoclonal antibody (mAb) with direct and Fc-mediated cell killing activity. DARA induces killing of tumor cells, mainly via complement-dependent cytotoxicity (CDC), antibody-dependent cell-mediated cytotoxicity (ADCC) (de Weers M. J Immunol 2011), and antibody-dependent cellular phagocytosis (ADCP) by macrophages (both murine and human). In addition, DARA induces apoptosis upon secondary cross-linking and modulates CD38 enzymatic function. DARA is currently in phase I, II and III clinical evaluation in patients with MM. Besides DARA, several other anti-CD38 mAb are in development; SAR650894 (SAR; clone 38SB19; Sanofi-Aventis) for MM and other CD38+ hematological malignancies, MOR03087 (MOR; Morphosys) for relapsed/refractory MM and Ab79 (Millenium/Takeda) which is in preclinical development. Similar mechanisms of action (MoA) are described for these mAb; nevertheless direct comparison studies would be critical for differentiation among these antibodies. . In this study, the efficacy of these anti-CD38 mAb was directly compared to DARA with respect to binding, apoptosis, CD38 ectoenzyme activity, and the induction of ADCC, ADCP and CDC. Surrogate antibodies of MOR, SAR and Ab79 were generated on the basis of protein sequences, as published in their corresponding patents families, and were attached to the backbone of DARA. Binding to CD38 expressing Daudi tumor cells was assessed by flow cytomery. All CD38 antibodies showed similar EC50 (~0.1 µg/mL) and maximal binding, except MOR which showed a lower apparent affinity (~0.3 µg/mL). Previously, CD38 amino acid residues Q272 and S274 were reported as critical for DARA binding. ELISA analyses using CD38 point mutants revealed MOR, SAR and Ab79 not to be affected by mutation of these residues. All CD38 mAb were equally potent in inducing ADCC of Daudi cells (40-60% lysis, 0.02 µg/mL), in classic Cr51-release ADCC assay using human PBMC effector cells (E:T ratio 100:1). Important differences were observed with respect to induction of CDC. SAR was unable to induce CDC in Daudi cells at concentrations up to 30 µg/mL, while DARA induced more than 80% lysis at concentrations above 1 µg/mL. Ab79 and MOR induced CDC, yet maximum lysis was 50% and 20%, respectively. Evaluation of Annexin V/propidium iodide (AnnV/PI) staining and activation of caspase-3 showed that only SAR induced AnnV/PI+ in Ramos cells (~40%) after 48 h exposure without Fc crosslinking, but did not activate caspase-3. In the presence of Fc crosslinking antibodies, all anti-CD38 mAb induced AnnV/PI+, caspase-3 mediated apoptosis. In enzyme activity assays using purified CD38 protein, SAR inhibited generation of cGDPR (indicative of the combined CD38 cyclase activity generating fluorescent cGDPR and hydrolase activity converting cGDPR into GDPR)more effectively than DARA (~70% vs. ~20% inhibition at 30 µg/mL). Ab79 had a modest effect on CD38 enzyme activity (~10% inhibition). MOR did not affect CD38 enzyme activity at all. The capacity to induce ADCP was only tested for DARA, MOR and Ab79 using mouse macrophages (mφ) as effector cells and Daudi target cells. mφ, isolated and matured from bone marrow cells, and calcein-AM labelled target cells (E:T ratio 1:1) were cultured in the presence of 0.0006-5 µg/mL antibody for 4 h. Non-phagocytosed target cells and mφ were collected and ADCP was evaluated by flow cytometry. All CD38 mAb induced mφ-mediated phagocytosis, as observed by a concentration dependent increase in the number of double positive mφ and killing of target cells. Ab79 was as effective as DARA (EC50 ~0.01 µg/mL) in ADCP induction, whereas MOR was less effective (EC50 0.04 µg/mL). In summary, DARA and surrogate mAb of MOR, SAR and Ab79 showed similar binding to cells and induced similar amounts of ADCC. Differences between these mAb involved the ability to directly induce apoptosis, to inhibit the enzymatic activity of CD38 and to induce ADCP. The most striking difference was observed for the ability to induce CDC, the MoA which is currently believed the most important mechanism of MM cell killing in the clinic. DARA efficiently induced high levels of CDC at low concentrations, whereas the other CD38 mAb were unable or less capable to induce CDC. Disclosures Lammerts van Bueren: Genmab: Employment, warrents Other. Jakobs:Genmab: Employment, warrents Other. Kaldenhoven:Genmab: Employment, warrents Other. Roza:Genmab: Employment, warrents Other. Hiddingh:Genmab: Employment. Meesters:Genmab: Employment, warrents Other. Voorhorst:Genmab: Employment, warrents Other. Gresnigt:Genmab: Employment, warrents Other. Wiegman:Genmab: Employment, warrents Other. Ortiz Buijsse:Genmab: Employment, warrents Other. Andringa:Genmab: Employment, warrents Other. Overdijk:Genmab: Employment, warrents Other. Doshi:Janssen R&D: Employment. Sasser:Janssen R&D: Employment. de Weers:Genmab: Employment, warrents Other. Parren:Genmab: Employment, inventor on patents regarding daratumumab Patents & Royalties, stock and warrents Other.
A bispecific antibody (BsAb) targeting the epidermal growth factor receptor (EGFR) and mesenchymal–epithelial transition factor (MET) pathways represents a novel approach to overcome resistance to targeted therapies in patients with non–small cell lung cancer. In this study, we sequentially screened a panel of BsAbs in a combinatorial approach to select the optimal bispecific molecule. The BsAbs were derived from different EGFR and MET parental monoclonal antibodies. Initially, molecules were screened for EGFR and MET binding on tumor cell lines and lack of agonistic activity toward MET. Hits were identified and further screened based on their potential to induce untoward cell proliferation and cross-phosphorylation of EGFR by MET via receptor colocalization in the absence of ligand. After the final step, we selected the EGFR and MET arms for the lead BsAb and added low fucose Fc engineering to generate amivantamab (JNJ-61186372). The crystal structure of the anti-MET Fab of amivantamab bound to MET was solved, and the interaction between the two molecules in atomic details was elucidated. Amivantamab antagonized the hepatocyte growth factor (HGF)-induced signaling by binding to MET Sema domain and thereby blocking HGF β-chain—Sema engagement. The amivantamab EGFR epitope was mapped to EGFR domain III and residues K443, K465, I467, and S468. Furthermore, amivantamab showed superior antitumor activity over small molecule EGFR and MET inhibitors in the HCC827-HGF in vivo model. Based on its unique mode of action, amivantamab may provide benefit to patients with malignancies associated with aberrant EGFR and MET signaling.
A recombinant, fully human monoclonal antibody with antitumor activity constructed from phage-displayed antibody fragments
A single-chain Fv antibody fragment specific for the tumor-associated Ep-CAM molecule was isolated from a semisynthetic phage display library and converted into an intact, fully human IgG1 monoclonal antibody (huMab). The purified huMab had an affinity of 5 nM and effectively mediated tumor cell killing in in vitro and in vivo assays. These experiments show that nonimmunized phage antibody display libraries can be used to obtain high-affinity, functional, and clinically applicable huMabs directed against a tumor-associated antigen.
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