Determining ADCC Activity of Antibody-Based Therapeutic Molecules using Two Bioluminescent Reporter-Based Bioassays.

Antibody Fc effector function is one of the main mechanisms of action (MoA) for therapeutic monoclonal antibodies. Measurement of antibody-dependent cellular cytotoxicity (ADCC) is critical for understanding the Fc effector function during monoclonal antibody development. This article covers two cell-based ADCC bioassays which can quantitatively measure the antibody potency in ADCC. Basic Protocol 1 describes the ADCC reporter bioassay using engineered ADCC effector cells which measures the FcγRIIIa-mediated luciferase reporter activation upon the binding of antibody-coated target cells. Basic Protocol 2 describes the PBMC ADCC bioassay using primary peripheral blood mononuclear cells (PBMC) as effector cells and engineered HiBiT target cells in an assay that measures the release of HiBiT from target cells upon antibody-mediated target lysis. Optimization of several key assay parameters including cell handling, effector:target (E:T) ratios, assay plate, and plate reader requirement, and how these parameters impact assay performance are discussed. © 2021 Promega Corporation. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: ADCC reporter bioassay using engineered ADCC bioassay effector cells Basic Protocol 2: PBMC ADCC bioassay using primary PBMC and engineered HiBiT target cells.

Development of a robust reporter-based ADCC assay with frozen, thaw-and-use cells to measure Fc effector function of therapeutic antibodies.

Antibody-dependent cell-mediated cytotoxicity (ADCC) is one of the main mechanisms of action for many therapeutic antibodies. Classic ADCC assays measure antibody-dependent target cell cytotoxicity induced by primary effector cells that are isolated from human blood. They suffer from high assay variability due to the genetic and immune-status-mediated variation from blood donors. Here we report the development of a robust reporter-based ADCC assay that uses an engineered Jurkat stable cell line as the source of effector cells. These engineered effector cells were further developed as frozen, thaw-and-use format that can be plated for assay immediately after thaw. We demonstrate that frozen, thaw-and-use Jurkat effector cells showed appropriate Fc effector function similar to fresh cells from continuous culture, with added benefits of convenience and consistency. This robust assay is able to measure antibody potency for several therapeutic antibodies targeted to hematopoietic or solid tumors. The assay can distinguish effector functions for different antibody IgG isotypes in two antibody model systems: anti-CD20 and anti-EGFR. It is able to detect changes in ADCC biological activity for heat-stressed rituximab and trastuzumab, demonstrating that it possesses proper stability-indicting property. When compared with a classic PBMC-based ADCC assay, the ADCC reporter assay showed better assay precision and similar correlation of antibody glycosylation with ADCC biological activity for a panel of glyco-modified trastuzumab mixtures. Together these data demonstrate that this robust ADCC reporter assay meets the requirement of a potency bioassay that can quantify antibody Fc effector function in ADCC mechanism of action during drug discovery and development.

Luciferase Reporter Assay System for Deciphering GPCR Pathways.

The G protein coupled receptors (GPCR) represent the target class for nearly half of the current therapeutic drugs and remain to be the focus of drug discovery efforts. The complexity of receptor signaling continues to evolve. It is now known that many GPCRs are coupled to multiple G-proteins, which lead to regulation of respective signaling pathways downstream. Deciphering this receptor coupling will aid our understanding of the GPCR function and ultimately developing drug candidates. Here, we report the development of four homogenous bioluminescent reporter assays using improved destabilized luciferases and various response elements: CRE, NFAT-RE, SRE, and SRF-RE. These assays allowed measurement of major GPCR pathways including cAMP production, intracellular Ca(2+) mobilizations, ERK/MAPK activ-ity, and small G protein RhoA activity, respectively using the same reporter assay format. We showed that we can decipher G protein activation profiles for exogenous m(3) muscarinic receptor and endogenous ß(2)-adrenergic receptors in HEK293 cells by using these four reporter assays. Furthermore, we demonstrated that these assays can be readily used for potency rankings of agonists and antagonists, and for high throughput screening.