Binding, Neutralization and Internalization of the Interleukin-13 Antibody, Lebrikizumab.

INTRODUCTION: IL-13 is the primary upregulated cytokine in atopic dermatitis (AD) skin and is the pathogenic mediator driving AD pathophysiology. Lebrikizumab, tralokinumab and cendakimab are therapeutic monoclonal antibodies (mAb) that target IL-13. METHODS: We undertook studies to compare in vitro binding affinities and cell-based functional activities of lebrikizumab, tralokinumab and cendakimab. RESULTS: Lebrikizumab bound IL-13 with higher affinity (as determined using surface plasma resonance) and slower off-rate. It was more potent in neutralizing IL-13-induced effects in STAT6 reporter and primary dermal fibroblast periostin secretion assays than either tralokinumab or cendakimab. Live imaging confocal microscopy was employed to determine the mAb effects on IL-13 internalization into cells via the decoy receptor IL-13Rα2, using A375 and HaCaT cells. The results showed that only the IL-13/lebrikizumab complex was internalized and co-localized with lysosomes, whereas IL-13/tralokinumab or IL-13/cendakimab complexes did not internalize. CONCLUSION: Lebrikizumab is a potent, neutralizing high-affinity antibody with a slow disassociation rate from IL-13. Additionally, lebrikizumab does not interfere with IL-13 clearance. Lebrikizumab has a different mode of action to both tralokinumab and cendakimab, possibly contributing to the clinical efficacy observed by lebrikizumab in Ph2b/3 AD studies.

Investigation of Immune Responses to Oxidation, Deamidation, And Isomerization in Therapeutic Antibodies using Preclinical Immunogenicity Risk Assessment Assays.

Product- and process- related critical quality attributes have the potential to impact pharmacokinetics, immunogenicity, potency, and safety of biotherapeutics. Among these critical quality attributes are chemical degradations, specifically oxidation, deamidation, and isomerization. These degradations can be induced by stressors such as light, pH, or temperature; they can also occur naturally under normal conditions. The immunogenicity risk of chemical degradations, particularly in the absence of aggregation, has not been thoroughly understood. In this study, model antibodies with known labile residues were stressed to induce each of the three chemical degradation classes. Aggregate-free and chemically modified antibody species were fractionalized and characterized, followed by testing in standardized and qualified preclinical immunogenicity risk assessment assays for dendritic cell internalization and presentation, monocyte activation, and pre-existing reactivity. Preclinical immunogenicity risk was assessed holistically in vitro based on changes in innate activation risk, CD4 T cell risk, and B cell risk compared to corresponding native antibody. The results of this study suggest an overall moderate increase in immune activation potential for the antibody with isomerization, with only slight increases observed in oxidized and deamidated antibodies. These findings could lend understanding to the immunogenicity risk of chemical degradations in therapeutic antibodies and therefore inform optimization engineering at particular labile residues and risk assessment under the Quality by Design framework.

Probing the structural requirements of non-electrophilic naphthalene-based Nrf2 activators.

Activation of the transcription factor Nrf2 has been posited to be a promising therapeutic strategy in a number of inflammatory and oxidative stress diseases due to its regulation of detoxifying enzymes. In this work, we have developed a comprehensive structure-activity relationship around a known, naphthalene-based non-electrophilic activator of Nrf2, and we report highly potent non-electrophilic activators of Nrf2. Computational docking analysis of a subset of the compound series demonstrates the importance of water molecule displacement for affinity, and the X-ray structure of di-amide 12e supports the computational analysis. One of the best compounds, acid 16b, has an IC50 of 61 nM in a fluorescence anisotropy assay and a Kd of 120 nM in a surface plasmon resonance assay. Additionally, we demonstrate that the ethyl ester of 16b is an efficacious inducer of Nrf2 target genes, exhibiting ex vivo efficacy similar to the well-known electrophilic activator, sulforaphane.