In vivo and in vitro activity of an immunoglobulin Fc fragment (Fcab) with engineered Her-2/neu binding sites.

Antigen-binding Fc fragments (Fcabs) are a new unique class of immunotherapeutics. They are small (50 kD) fully functional antibody alternatives that bind antigen and elicit effector functions such as antibody-dependent cytotoxicity (ADCC) and complement-dependent cytotoxicity. Since Fcabs carry the natural FcRn binding site of antibodies, they have very favorable pharmacokinetics. We showed recently that Fcab H10-03-6 is a high-affinity binder of Her-2/neu (ErbB2/neu) mediating killing of Her-2/neu-overexpressing tumor cells in the presence of immune effector cells, strongly suggesting that the mechanism of killing is due to ADCC. The present study further confirms ADCC as the mechanism by which H10-03-6 mediates tumor cell killing, since H10-03-6 was shown to interact simultaneously with Her-2/neu and the Fc receptor CD16a. The epitope recognized by H10-03-6 overlaps with that of the clinically used monoclonal antibody trastuzumab. However, unlike trastuzumab, Fcab H10-03-6 did not inhibit proliferation of human tumor cells in vitro even under conditions favoring Her-2/neu crosslinking. Treatment of mice harboring human BT-474 cell xenograft tumors with Fcab H10-03-6 led to statistically significant retardation of tumor growth. For the first time, in vivo properties of an Fcab are presented, supporting the view that Fcabs could become highly efficacious immunotherapeutics for human use.

Directed evolution of Her2/neu-binding IgG1-Fc for improved stability and resistance to aggregation by using yeast surface display.

An Fcab (Fc antigen binding) is a crystallizable fragment of IgG having C-terminal structural loops of CH3 domains engineered for antigen binding. Since introduction of novel binding sites might impair the immunoglobulin fold, repairing strategies are needed for improving the biophysical properties of promising binders without decreasing affinity to the antigen. Here, a directed evolution protocol was developed and applied for stabilization of a Her2/neu-binding Fcab. Distinct loop regions of the parental binder were softly randomized by parsimonious mutagenesis, followed by heat incubation of the yeast displayed protein library and selection for retained antigen binding. Selected Fcabs were expressed solubly in Pichia pastoris and human embryonic kidney 293 cells and characterized. Fcab clones that retained their affinity to Her2/neu but exhibited a significantly increased conformational stability and resistance to aggregation could be evolved. Moreover, we demonstrate that simultaneous selection for binding to the antigen and to structurally specific ligands (FcγRI and an antibody directed against the CH2 domain) yields even more stable Fcabs. To sum up, this study presents a very potent and generally applicable method for improving the fold and stability of antibodies, antibody fragments and alternative binding scaffolds.

Significant impact of single N-glycan residues on the biological activity of Fc-based antibody-like fragments.

Recent studies have demonstrated that IgG-Fc fragments (Fcabs) can be engineered to form antigen-binding sites with antibody properties. Thus they may serve as an attractive alternative to conventional antibodies in therapeutic applications. The critical influence of Fc glycosylation on effector functions of IgGs is well documented; however, whether this applies to Fcabs is not known. Here we used human cells, wild type, and glycoengineered plants to generate four different glycoforms of H10-03-6, an Fcab with engineered HER2/neu-binding sites. Plant-derived H10-03-6 differed in the presence/absence of single oligosaccharide residues, i.e., core fucose and xylose, and terminal galactose. All of the glycoforms had similar binding to HER2/neu expressed on human tumor cells. By contrast, glycoforms that lacked core oligosaccharide modifications (i.e., core α1,3-fucose and ß1,2-xylose) showed significantly enhanced binding to the Fcγ receptor IIIa, irrespective of whether plant or human expression systems were used. Consistent with this finding, plant-derived H10-03-6 glycoforms lacking core N-glycan residues mediated higher antibody-dependent cellular cytotoxicity against human tumor cells. No alteration in γ-receptor binding and antibody-dependent cellular cytotoxicity activity was observed upon decoration of N-glycans by terminal galactose. The results point to a significant impact of distinct N-glycan residues on effector functions of Fcabs. Moreover, the outcomes imply that the effector functions mediated by H10-03-6 can be optimized by altering the N-glycosylation profile. Biasing vaccine-induced immune responses toward optimal Fc glycosylation patterns could result in improved vaccine efficacy.

Correlation between CD16a binding and immuno effector functionality of an antigen specific immunoglobulin Fc fragment (Fcab).

Antigen binding immunoglobulin Fc fragments (Fcab) are generated by engineering loop regions in the CH3 domain of human IgG1 Fc. Variants of an Fcab specific for Her-2 were designed to display either enhanced (S239D:A330L:I332E) or diminished (L234A:L235A) binding affinities to the Fc receptor CD16a based on mutations described previously. The two mutant Fcab proteins demonstrated the expected modulation of CD16a binding. Interaction with recombinant or cell surface expressed Her-2 was unaffected in both mutants compared to the parental Fcab. Binding affinities for CD16a correlated with the ADCC-potencies of the Fcab variants. Additional studies indicated that the L234A:L235A variant Fcab had equivalent structural features as the unmodified Fcab since their DSC profiles were similar and antigen binding after re-folding upon partial heat denaturation had not changed. Introduction of the S239D:A330L:I332E mutations resulted in a significant reduction of the CH2 domain melting temperature, a moderate decrease of the thermal transition of the CH3 domain and lower antigen binding after thermal stress compared to the parental Fcab. We conclude that the known correlation between CD16a binding affinity and ADCC potency is also valid in Fcab proteins and that antigen specific Fcab molecules can be further engineered for fine tuning of immuno effector functions.

Analysis of lysine clipping of a humanized Lewis-Y specific IgG antibody and its relation to Fc-mediated effector function.

During the analytical characterization of the humanized Lewis-Y specific monoclonal antibody IGN311 (IgG1/kappa) used for passive anti-cancer therapy in humans, isoelectric focusing (IEF) experiments revealed that IGN311 batches produced in serum-containing and serum-free medium, respectively, displayed different banding patterns. The additional bands in the IEF pattern correlated with additional peaks observed by subsequent cation exchange (CEX)-HPLC analysis. Since the IEF pattern is one of the specification criteria in the quality control of monoclonal antibodies and a non-matching pattern may be indicative for lot-to-lot inconsistency, this phenomenon was investigated in detail. First, we investigated whether a difference in antibody glycosylation was the cause for the observed charge heterogeneity. De-N-glycosylation experiments demonstrated that charge heterogeneity observed in the IEF pattern is not a consequence of glycosylation. In contrast, sample treatment by carboxypeptidase B, removing the carboxy-terminal lysine residues from the two heavy chains of the antibody, resulted in reduced charge heterogeneity eliminating the two most basic bands observed in IEF. These data were supported by reversed phase HPLC-MALDI-TOF-MS analysis of enzymatically cleaved peptides of the antibody as well as by carboxy-terminal sequencing of the heavy chains. It was demonstrated that the differences in the IEF banding pattern were due to lysine clipping occurring during the production of the antibody. The antibody batch produced under serum-free conditions was less affected by lysine clipping. Both antibody variants--clipped and unclipped--elicited the same potency in a complement dependent cytotoxicity (CDC) assay demonstrating that lysine clipping of IGN311 does not impair Fc-mediated effector functions.