Stephen G. McCarthy

Correlations between pharmacokinetics of IgG antibodies in primates vs. FcRn-transgenic mice reveal a rodent model with predictive capabilities

Transgenic mice expressing human neonatal Fc receptor (FcRn) instead of mouse FcRn are available for IgG antibody pharmacokinetic (PK) studies. Given the interest in a rodent model that offers reliable predictions of antibody PK in monkeys and humans, we set out to test whether the PK of IgG antibodies in such mice correlated with the PK of the same antibodies in primates. We began by using a single research antibody to study the influence of: (1) different transgenic mouse lines that differ in FcRn transgene expression; (2) homozygous vs. hemizygous FcRn transgenic mice; (3) the presence vs. absence of coinjected high-dose human intravenous immunoglobulin (IVIG), and (4) the presence vs. absence of coinjected high-dose human serum albumin (HSA). Results of those studies suggested that use of hemizygous Tg32 mice (Tg32 hemi) not treated with IVIG or HSA offered potential as a predictive model for PK in humans. Mouse PK studies were then done under those conditions with a panel of test antibodies whose PK in mice and primates is not significantly affected by target binding, and for which monkey or human PK data were readily available. Results from the studies revealed significant correlations between terminal half-life or clearance values observed in the mice and the corresponding values reported in humans. A significant relationship in clearance values between mice and monkeys was also observed. These correlations suggest that the Tg32 hemi mouse model, which is both convenient and cost-effective, can offer value in predicting antibody half-life and clearance in primates.

Engineered Protease-resistant Antibodies with Selectable Cell-killing Functions

Background: Proteases can cleave human IgG1 antibodies, resulting in loss of cell-killing functions. Results: Mutation of the lower hinge of IgG1 confers protease resistance but disrupts Fc effector functions. Conclusion: Compensating mutations in the CH2 domain can selectively restore Fc effector functions on a protease-resistant backbone. Significance: Protease-resistant antibodies may be desirable for microenvironments with high protease content and/or when selected cell-killing functions are needed. Molecularly engineered antibodies with fit-for-purpose properties will differentiate next generation antibody therapeutics from traditional IgG1 scaffolds. One requirement for engineering the most appropriate properties for a particular therapeutic area is an understanding of the intricacies of the target microenvironment in which the antibody is expected to function. Our group and others have demonstrated that proteases secreted by invasive tumors and pathological microorganisms are capable of cleaving human IgG1, the most commonly adopted isotype among monoclonal antibody therapeutics. Specific cleavage in the lower hinge of IgG1 results in a loss of Fc-mediated cell-killing functions without a concomitant loss of antigen binding capability or circulating antibody half-life. Proteolytic cleavage in the hinge region by tumor-associated or microbial proteases is postulated as a means of evading host immune responses, and antibodies engineered with potent cell-killing functions that are also resistant to hinge proteolysis are of interest. Mutation of the lower hinge region of an IgG1 resulted in protease resistance but also resulted in a profound loss of Fc-mediated cell-killing functions. In the present study, we demonstrate that specific mutations of the CH2 domain in conjunction with lower hinge mutations can restore and sometimes enhance cell-killing functions while still retaining protease resistance. By identifying mutations that can restore either complement- or Fcγ receptor-mediated functions on a protease-resistant scaffold, we were able to generate a novel protease-resistant platform with selective cell-killing functionality.

Functional optimization of agonistic antibodies to OX40 receptor with novel Fc mutations to promote antibody multimerization

ABSTRACT Immunostimulatory receptors belonging to the tumor necrosis factor receptor (TNFR) superfamily are emerging as promising targets for cancer immunotherapies. To optimize the agonism of therapeutic antibodies to these receptors, Fc engineering of antibodies was applied to facilitate the clustering of cell surface TNFRs to activate downstream signaling pathways. One engineering strategy is to identify Fc mutations that facilitate antibody multimerization on the cell surface directly. From the analyses of the crystal packing of IgG1 structures, we identified a novel set of Fc mutations, T437R and K248E, that facilitated antibody multimerization upon binding to antigens on cell surface. In a NF-κB reporter assay, the engineered T437R/K248E mutations could facilitate enhanced agonism of an anti-OX40 antibody without the dependence on FcγRIIB crosslinking. Nonetheless, the presence of cells expressing FcγRIIB could facilitate a boost of the agonism of the engineered antibody with mutations on IgG1 Fc, but not on the silent IgG2σ Fc. The Fc engineered antibody also showed enhanced effector functions, including antibody-dependent cell-meditated cytotoxicity, antibody-dependent cellular phagocytosis, and complement-dependent cytotoxicity, depending on the IgG subtypes. Also, the engineered antibodies showed normal FcRn binding and pharmacokinetic profiles in mice. In summary, this study elucidated a novel Fc engineering approach to promote antibody multimerization on a cell surface, which could enhance agonism and improve effector function for anti-TNFR antibodies as well as other therapeutic antibodies.

Functional, Biophysical, and Structural Characterization of Human IgG1 and IgG4 Fc Variants with Ablated Immune Functionality

Engineering of fragment crystallizable (Fc) domains of therapeutic immunoglobulin (IgG) antibodies to eliminate their immune effector functions while retaining other Fc characteristics has numerous applications, including blocking antigens on Fc gamma (Fcγ) receptor-expressing immune cells. We previously reported on a human IgG2 variant termed IgG2σ with barely detectable activity in antibody-dependent cellular cytotoxicity, phagocytosis, complement activity, and Fcγ receptor binding assays. Here, we extend that work to IgG1 and IgG4 antibodies, alternative subtypes which may offer advantages over IgG2 antibodies. In several in vitro and in vivo assays, the IgG1σ and IgG4σ variants showed equal or even lower Fc-related activities than the corresponding IgG2σ variant. In particular, IgG1σ and IgG4σ variants demonstrate complete lack of effector function as measured by antibody-dependent cellular cytotoxicity, complement-dependent cytotoxicity, antibody-dependent cellular phagocytosis, and in vivo T-cell activation. The IgG1σ and IgG4σ variants showed acceptable solubility and stability, and typical human IgG1 pharmacokinetic profiles in human FcRn-transgenic mice and cynomolgus monkeys. In silico T-cell epitope analyses predict a lack of immunogenicity in humans. Finally, crystal structures and simulations of the IgG1σ and IgG4σ Fc domains can explain the lack of Fc-mediated immune functions. These variants show promise for use in those therapeutic antibodies and Fc fusions for which the Fc domain should be immunologically “silent”.