Mass spectrometry study on SARS-CoV-2 recombinant vaccine with comprehensive separation techniques to characterize complex heterogeneity.

SARS-CoV-2, the causative agent of COVID-19, has imposed a major public health threat, which needs effective therapeutics and vaccination strategies. Several potential candidate vaccines being rapidly developed are in clinical evaluation and recombinant vaccine has gained much attention thanks to its potential for greater response predictability, improved efficacy, rapid development and reduced side effects. Recombinant vaccines are designed and manufactured using bacterial, yeast cells or mammalian cells. A small piece of DNA is taken from the virus or bacterium against which we want to protect and inserted into the manufacturing cells. Due to the extremely complex heterogeneity of SARS-CoV-2 recombinant vaccine, single technology platform cannot achieve thorough and accurate characterization of such difficult proteins so integrating comprehensive technologies is essential. This study illustrates an innovative workflow employing multiple separation techniques tandem high-resolution mass spectrometry for comprehensive and in-depth characterization of SARS-CoV-2 recombinant vaccine, including ultra-high performance liquid chromatography (UHPLC), ion exchange chromatography (IEX) and imaged capillary isoelectric focusing (icIEF). The integrated methodology focuses on the importance of cutting-edge icIEF-MS online coupling and icIEF fractionation applied to revealing the heterogeneity secret of SARS-CoV-2 recombinant vaccine.

Using capillary electrophoresis sodium dodecyl sulfate (CE-SDS) and liquid chromatograph mass spectrometry (LC-MS) to identify glycosylated heavy chain heterogeneity in the anti-VEGFR-2 monoclonal antibody.

The size variant, which can be measured by capillary electrophoresis sodium dodecyl sulfate (CE-SDS), is a critical quality attribute of monoclonal antibodies (mAbs). The CE-SDS size heterogeneity can hardly be identified by tandem mass spectrometry, which is an intractable obstacle of mAb development and quality control across the industry. We analyzed the purity of an anti-vascular endothelial growth factor receptor 2 (VEGFR-2) mAb, an antagonist of the human VEGFR-2, through reduced CE-SDS and observed glycosylated heavy chain heterogeneity. The heterogeneity has potential impact on safety, efficacy, and stability of drugs for clinical use. Therefore, it should be characterized so as to evaluate its potential risk. In order to identify the heterogeneity, we used mass spectrometry to confirm that the molecular size heterogeneity was not due to peptide bond cleavage in the heavy chain. Subsequently, we employed mass-spectrometry-glycosylation profiling and CE-SDS analysis of various glycosidase-treated samples, in addition to the preparation of mAb references with different glycoforms. Ultimately, we demonstrated that the heavy chain heterogeneity was induced by different levels of galactosylation modifications which will potentially impact the efficacy of antibody drugs (i.e., complement-dependent cytotoxicity). In this study, potential risk caused by heavy chain size heterogeneity was evaluated, which addressed the obstacle of mAb development and quality control. Therefore, this study offers a feasible approach for the investigation and identification of heavy chain heterogeneity in reduced CE-SDS, providing a novel strategy for mAb quality control and evaluation.

Antibody-Drug Conjugate Overview: a State-of-the-art Manufacturing Process and Control Strategy.

Antibody-drug conjugates (ADCs) comprise an antibody, linker, and drug, which direct their highly potent small molecule drugs to target tumor cells via specific binding between the antibody and surface antigens. The antibody, linker, and drug should be properly designed or selected to achieve the desired efficacy while minimizing off-target toxicity. With a unique and complex structure, there is inherent heterogeneity introduced by product-related variations and the manufacturing process. Here this review primarily covers recent key advances in ADC history, clinical development status, molecule design, manufacturing processes, and quality control. The manufacturing process, especially the conjugation process, should be carefully developed, characterized, validated, and controlled throughout its lifecycle. Quality control is another key element to ensure product quality and patient safety. A patient-centric strategy has been well recognized and adopted by the pharmaceutical industry for therapeutic proteins, and has been successfully implemented for ADCs as well, to ensure that ADC products maintain their quality until the end of their shelf life. Deep product understanding and process knowledge defines attribute testing strategies (ATS). Quality by design (QbD) is a powerful approach for process and product development, and for defining an overall control strategy. Finally, we summarize the current challenges on ADC development and provide some perspectives that may help to give related directions and trigger more cross-functional research to surmount those challenges.

A novel alternative for pyrogen detection based on a transgenic cell line.

Pyrogen, often as a contaminant, is a key indicator affecting the safety of almost all parenteral drugs (including biologicals, chemicals, traditional Chinese medicines and medical devices). It has become a goal to completely replace the in vivo rabbit pyrogen test by using the in vitro pyrogen test based on the promoted 'reduction, replacement and refinement' principle, which has been highly considered by regulatory agencies from different countries. We used NF-κB, a central signalling molecule mediating inflammatory responses, as a pyrogenic marker and the monocyte line THP-1 transfected with a luciferase reporter gene regulated by NF-κB as an in vitro model to detect pyrogens by measuring the intensity of a fluorescence signal. Here, we show that this test can quantitatively and sensitively detect endotoxin (lipopolysaccharide from different strains) and nonendotoxin (lipoteichoic acid, zymosan, peptidoglycan, lectin and glucan), has good stability in terms of NF-κB activity and cell phenotypes at 39 cell passages and can be applied to detect pyrogens in biologicals (group A & C meningococcal polysaccharide vaccine; basiliximab; rabies vaccine (Vero cells) for human use, freeze-dried; Japanese encephalitis vaccine (Vero cells), inactivated; insulin aspart injection; human albumin; recombinant human erythropoietin injection (CHO Cell)). The within-laboratory reproducibility of the test in three independent laboratories was 85%, 80% and 80% and the interlaboratory reproducibility among laboratories was 83.3%, 95.6% and 86.7%. The sensitivity (true positive rate) and specificity (true negative rate) of the test were 89.9% and 90.9%, respectively. In summary, the test provides a novel alternative for pyrogen detection.

Comparability strategy and demonstration for post-approval production cell line change of a bevacizumab biosimilar IBI305.

High-producing cell line could improve the affordability and availability of biotherapeutic products. A post-approval production cell line change, low-titer CHO-K1S to high-titer CHO-K1SV GS-KO, was performed for a China marketed bevacizumab biosimilar IBI305. Currently, there is no regulatory guideline specifically addressing the requirements for comparability study of post-approval cell line change, which is generally regarded as the most complex process change for biological products. Following the quality by design principle and risk assessment, an extensive analytical characterization and three-way comparison was performed by using a panel of advanced analytical methods. Orthogonal and state-of-the-art techniques including nuclear magnetic resonance and high-resolution mass spectrometry were applied to mitigate the potential uncertainties of higher-order structures and to exclude any new sequence variants, scrambled disulfide bonds, glycan moiety and undesired process-related impurities such as host cell proteins. Nonclinical and clinical pharmacokinetics (PK) studies were conducted subsequently to further confirm the comparability. The results demonstrated that the post-change IBI305 was analytically comparable to the pre-change one and similar to the reference product in physicochemical and biological properties, as well as the degradation behaviors in accelerated stability and forced degradation studies. The comparability was further confirmed by comparable PK, pharmacodynamics, toxicological and immunogenicity profiles of nonclinical and clinical studies. The comparability strategy presented here might extend to cell line changes of other post-approval biological products, and particularly set a precedent in China for post-approval cell line change of commercialized biosimilars.

Development of a novel bispecific antibody GR1801 for rabies.

Rabies is a zoonotic viral disease characterized by an almost 100% fatality rate once symptoms appear. However, it can be prevented through timely postexposure prophylaxis (PEP). Currently, there is a growing trend to replace polyclonal rabies immune globulin (RIG) with monoclonal antibodies (mAbs) in rabies PEP. In this study, we developed a human bispecific antibody, GR1801, by combining two mAbs, A2 and B353, which target distinct epitopes. GR1801 is an asymmetric immunoglobulin G1 molecule, with one arm (A2 targeting epitope III) in fragment antigen-binding (Fab) form and the other arm (B353 targeting epitope I) in single-chain variable fragment (scFv) form, constructed using Knobs-into-Holes technology. GR1801 demonstrated the ability to neutralize 90 naturally occurring rabies virus (RABV) glycoprotein antigenic variants, 21 pseudotyped, and 18 live street RABVs, exhibiting broad-spectrum neutralizing activity. In vivo, GR1801 provided protection equivalent to that of human RIG in golden hamsters challenged with lethal RABV. In conclusion, these findings demonstrate the neutralization potency and breadth of GR1801, which can be a promising candidate drug for rabies PEP, and a comprehensive testing against a broad spectrum of Chinese prevalent RABVs will be investigated in great detail in the future for the in vitro and in vivo studies.

Establishing a novel and sensitive assay for bioactivity determination of anti-CD25 antibodies.

Anti-CD25 antibodies have been approved for renal transplantation and has been used prior to and during transplantation by the Food and Drug Administration (FDA). However, no reported bioassays have been reflected the mechanism of action (MOA) of anti-CD25 antibodies. Here, we describe the development and validation of a reporter gene assay (RGA) based on the engineered C8166-STAT5RE-Luc cells expressing endogenous IL-2 receptors and a STAT5-inducible element-driven firefly luciferase in C8166 cell lines. The RGA was fully validated according to the International Conference on the Harmonization of Technical Requirements for the Registration of Pharmaceuticals for the Human Use-Q2 (ICH-Q2). After optimization, the assay showed excellent specificity, linearity, accuracy, precision, and robustness. Due to the MOA relatedness and the excellent assay performance, the RGA is suitable for exploring the critical quality attributes (CQAs), release inspection, comparability and stability of anti-CD25 mAbs.

Validation of an HPLC-CAD Method for Determination of Lipid Content in LNP-Encapsulated COVID-19 mRNA Vaccines.

Lipid nanoparticles (LNPs) are widely used as delivery systems for mRNA vaccines. The stability and bilayer fluidity of LNPs are determined by the properties and contents of the various lipids used in the formulation system, and the delivery efficiency of LNPs largely depends on the lipid composition. For the quality control of such vaccines, here we developed and validated an HPLC-CAD method to identify and determine the contents of four lipids in an LNP-encapsulated COVID-19 mRNA vaccine to support lipid analysis for the development of new drugs and vaccines.

Method validation of a bridging immunoassay in combination with acid-dissociation and bead treatment for detection of anti-drug antibody.

Anti-drug antibody (ADA) positivity is correlated with disease relapse risk when treated with monoclonal antibody (mAb) therapeutics. ADA evaluation can assist with interpreting pharmacokinetic, pharmacological, and toxicology results. Here, we established an ADA assay based on two steps of acid dissociation combined with a bridging immunoassay to provide a comprehensive validation strategy. The three-tiered sample analysis process included screening, confirmation, and titration assays using therapeutic HLX26 (targeting lymphocyte activation gene-3 [LAG-3]) as an example. The cut points were determined by testing 50 individual normal human serum samples, including screening cut point (SCP) (SNR: 1.08), confirmatory cut point (CCP) (% inhibition: 12.65), and titration cut point (TCP) (sample-to-noise ratio [SNR]: 1.17). The assay sensitivity, low positive control (LPC), and high positive control (HPC) titer acceptable range were also set up as 33.0 ng/mL, 41.0 ng/mL, and 320-1280, respectively. After full validation, both the intra-assay and inter-assay precision testing passed with coefficient of variations (CVs) < 20%. The assay enabled excellent drug tolerance up to 768.0 µg/mL at the HPC level and 291.0 µg/mL at the LPC level, while the tolerance of target interference was up to 74.0 ng/mL of soluble LAG3. Moreover, no false-positive results were observed in the presence of 5% hemolyzed serum samples and 150 mg/dL of triglyceride in the serum samples, no hook effect was observed, and the stability performed normally under room temperature for 24 h, 2-8 °C for 7 d, and six freeze/thaw cycles. In summary, this ADA assay is feasible and could be used for evaluating the immunogenicity of HLX26 in clinical trials.

Mass Spectrometry-Based Charge Heterogeneity Characterization of Therapeutic mAbs with Imaged Capillary Isoelectric Focusing and Ion-Exchange Chromatography as Separation Techniques.

Imaged capillary isoelectric focusing (icIEF) and ion-exchange chromatography (IEX) are two essential techniques that are routinely used for charge variant analysis of therapeutic monoclonal antibodies (mAbs) during their development and in quality control. These two techniques that separate mAb charge variants based on different mechanisms and IEX have been developed as front-end separation techniques for online mass spectrometry (MS) detection, which is robust for intact protein identification. Recently, an innovative, coupled icIEF-MS technology has been constructed for protein charge variant analysis in our laboratory. In this study, icIEF-MS developed and strong cation exchange (SCX)-MS were optimized for charge heterogeneity characterization of a diverse of mAbs and their results were compared based on methodological validation. It was found that icIEF-MS outperformed SCX-MS in this study by demonstrating outstanding sensitivity, low carryover effect, accurate protein identification, and higher separation resolution although SCX-MS contributed to higher analysis throughput. Ultimately, integrating our novel icIEF-HRMS analysis with the more common SCX-MS can provide a promising and comprehensive strategy for accelerating the development of complex protein therapeutics.

Fingerprinting trimeric SARS-CoV-2 RBD by capillary isoelectric focusing with whole-column imaging detection.

Because the spike (S) protein of the severe acute respiratory syndrome coronavirus (SARS-CoV) is the immunodominant antigen, the S protein and its receptor-binding domain (RBD) are both targets currently to be genetically engineered for designing the broad-spectrum vaccine. In theory, the expressed protein exists as a set of variants that are roughly the same but slightly different, which depends on the protein expression system. The variants can be phenotypically manifested as charge heterogeneity. Here, we attempted to depict the charge heterogeneity of the trimeric SARS-CoV-2 RBD by using capillary isoelectric focusing with whole-column imaging detection (cIEF-WCID). In its nature form, the electropherogram fingerprints of the trimeric RBD were presented under optimized experimental conditions. The peaks of matrix buffers can be fully distinguishable from peaks of trimeric RBD. The isoelectric point (pI) was determined to be within a range of 6.67-9.54 covering the theoretical pI of 9.02. The fingerprints of three batches of trimeric RBDs are completely the same, with the intra-batch and batch-to-batch relative standard deviations (RSDs) of both pI values and area percentage of each peak no more than 1.0%, indicating that the production process is stable and this method can be used to surveillance the batch-to-batch consistency. The fingerprint remained unchanged after incubating at 37 °C for 7 d and oxidizing by 0.015% H2O2. In addition, the fingerprint was destroyed when adjusting the pH value to higher than 10.0 but still stable when the pH was lower than 4.0. In summary, the cIEF-WCID fingerprint can be used for the identification, batch-to-batch consistency evaluation, and stability study of the trimeric SARS-CoV-2 RBD, as part of a quality control strategy during the potential vaccine production.

Development of a reporter gene assay for antibody dependent cellular cytotoxicity activity determination of anti-rabies virus glycoprotein antibodies.

Rabies is a viral disease that is nearly 100% fatal once clinical signs and symptoms develop. Post-exposure prophylaxis can efficiently prevent rabies, and antibody (Ab) induction by vaccination or passive immunization of human rabies immunoglobulin (HRIG) or monoclonal antibodies (mAbs) play an integral role in prevention against rabies. In addition to their capacity to neutralize viruses, antibodies exert their antiviral effects by antibody-dependent cellular cytotoxicity (ADCC), which plays an important role in antiviral immunity and clearance of viral infections. For antibodies against rabies virus (RABV), evaluation of ADCC activity was neglected. Here, we developed a robust cell-based reporter gene assay (RGA) for the determination of the ADCC activity of anti-RABV antibodies using CVS-N2c-293 cells, which stably express the glycoprotein (G) of RABV strain CVS-N2c as target cells, and Jurkat cells, which stably express FcγRⅢa and nuclear factor of activated T cells (NFAT) reporter gene as effector cells (Jurkat/NFAT-luc/FcγRⅢa cells). The experimental parameters were carefully optimized, and the established ADCC assay was systematically validated according to the International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use (ICH) Q2 guideline. We also evaluated the ADCC activity of anti-RABV antibodies, including mAbs, HRIG, and vaccine induced antisera, and found that all test antibodies exhibited ADCC activity with varied strengths. The established RGA provides a novel method for evaluating the ADCC of anti-RABV antibodies.

Interlaboratory Co-validation of a UPLC-ToF MS MAM Method for Truncations of a Fc Fusion Protein.

BACKGROUND: Peptide-Fc fusion proteins are inherently heterogeneous and complex molecules. Protein post-translational modifications (PTMs) or truncation can arise during manufacturing or product storage. Some of these product attributes could potentially impact the efficacy or safety of the bio-molecule and are thus classified as critical quality attributes (CQAs). These CQAs should be controlled in order to ensure manufacturing and quality consistency. METHODS: A subunit UPLC-ToF MS based MAM method was developed for identity test and quantitatively monitored two critical quality attributes (CQAs) resulting from two truncations of that fusion protein (fragment 1 and 2). Three independent laboratories are involved in the method validation according to ICH Q2(R1), ICH Q6B, FDA and NMPA guidance. RESULTS: This developed method fully meets the pre-defined analytical target profile (ATP), including specificity, accuracy, precision, quantitation limit, linearity, range and robustness. Three independent labs co-validate a UPLC-ToF MS based MAM method for protein drug QC release and stability testing. CONCLUSION: The experimental design of method validation can be a reference for LC-HRMS-based subunit MAM methods that have been widely used in the characterization of antibodies, ADCs and other protein-based biologics. This work paves the way for implementing MAM in QC with more targeted control of product quality.

Identification of a monoclonal antibody clipping variant by cross-validation using capillary electrophoresis - sodium dodecyl sulfate, capillary zone electrophoresis - mass spectrometry and capillary isoelectric focusing - mass spectrometry.

Critical quality attributes (CQAs) of recombinant monoclonal antibody therapeutics are constantly monitored throughout the life cycle of drug development and manufacturing. In the past few decades, numerous analytical techniques have been developed for the characterization of CQAs. In this regard, non-reduced and reduced capillary electrophoresis - sodium dodecyl sulfate (CE-SDS) methods have been widely adopted by the biopharmaceutical industry for the evaluation of size-related heterogeneities in biologics. In this work we demonstrate that, with recent development of capillary electrophoresis - mass spectrometry (CE-MS) technologies, a clipping variant of bevacizumab may be identified directly by both capillary zone electrophoresis - mass spectrometry (CZE-MS) and capillary isoelectric focusing - mass spectrometry (cIEF-MS) approaches, providing a powerful addition to the traditional CE-SDS analysis workflow. In this novel workflow, linear regression between the mobility and molecular weight first results in an approximate size range of this variant. The intact masses of all species in the bevacizumab are then obtained, after deconvolution of all features identified in the CZE-MS analysis. Subsequent  CZE-MS analysis of the subunits of bevacizumab leads to the confirmation of a clipped heavy chain. Furthermore, cIEF-MS of the intact bevacizumab confirms the existence of this clipping variant. The cross-validation between CE-SDS, CZE-MS, and cIEF-MS, creates a comprehensive roadmap for monoclonal antibody size variants profiling. These CE-based analytical techniques are complementary to each other, leading to orthogonal verification for size heterogeneity characterization.

Finger printing human norovirus-like particles by capillary isoelectric focusing with whole column imaging detection.

Owing to the limitation of in vitro culture of human noroviruses (HuNoVs), the development of HuNoV vaccines has to depend on the self-assembling virus-like particles (VLPs) with capsid protein expression. The heterogeneity of artificial VLPs exert an impact on the immunogenicity, and should be considered as one of the factors in vaccine evaluation. In this study, we biochemically finger print the HuNoV VLPs with different genogroups, genotypes and sub-genotypes which constitute for a candidate vaccine, by using capillary isoelectric focusing with whole column imaging detection (cIEF-WCID). The electropherograms of GI.1, GII.3, GII.4 and GII.17 VLPs in fluorescence signal were described in the monomer VP1 forms after degenerated by 8 M urea. The four HuNoV VLPs showed different properties in electropherogram finger prints. The finger prints were also reproducible within a certain concentration range (approx. 150 ∼ 20 ug/ml). This method can also tell the changes of pI finger-print patterns when the expired HoNoV VLPs were tested. In conclusion, cIEF-WCID shows great promise for evaluating the production consistency of HuNoV VLP vaccine.

Quality comparability assessment of a SARS-CoV-2-neutralizing antibody across transient, mini-pool-derived and single-clone CHO cells.

The emergence of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has triggered a serious public health crisis worldwide, and considering the novelty of the disease, preventative and therapeutic measures alike are urgently needed. To accelerate such efforts, the development of JS016, a neutralizing monoclonal antibody directed against the SARS-CoV-2 spike protein, was expedited from a typical 12- to 18-month period to a 4-month period. During this process, transient Chinese hamster ovary cell lines are used to support preclinical, investigational new drug-enabling toxicology research, and early Chemistry, Manufacturing and Controls development; mini-pool materials to supply Phase 1 clinical trials; and a single-clone working cell bank for late-stage and pivotal clinical trials were successively adopted. Moreover, key process performance and product quality investigations using a series of orthogonal and state-of-the-art techniques were conducted to demonstrate the comparability of products manufactured using these three processes, and the results indicated that, despite observed variations in process performance, the primary and high-order structures, purity and impurity profiles, biological and immunological functions, and degradation behaviors under stress conditions were largely comparable. The study suggests that, in particular situations, this strategy can be adopted to accelerate the development of therapeutic biopharmaceuticals and their access to patients.

A platform method for charge heterogeneity characterization of fusion proteins by icIEF.

The charge heterogeneity of fusion proteins can vary dramatically compared with more traditional biopharmaceuticals like monoclonal antibodies, making the characterization of fusion proteins a challenge. A single platform method suitable for the analysis of multiple fusion proteins would reduce method development and streamline production workflows. Here, we develop a platform method to characterize the charge heterogeneity of a variety of fusion protein therapeutics using imaged capillary isoelectric focusing (icIEF). We describe the development of the platform method, and analyze 9 fusion protein therapeutics. The results are reproducible in peak group area percentage and apparent pI determination. We compare the platform icIEF method to traditional slab gel IEF, which is still used in many laboratories for the analysis of fusion proteins. The peak patterns obtained from the icIEF method is comparable to the band patterns of the gel IEF. The platform method can also be used as the starting point if further optimization is needed even when high resolution is required. The platform method described in this study can be applied as an identity and purity assay for fusion proteins in the biopharmaceutical industry.

Subvisible Particle Analysis of 17 Monoclonal Antibodies Approved in China Using Flow Imaging and Light Obscuration.

In the study, subvisible particles in 205 samples from 17 commercial mAb drug products approved in China were analyzed using light obscuration (LO) and flow imaging microscopy (FIM) methods. For each method, a total 633 tests (runs) were performed. In the tests, samples in state of lyophilized powder or syringe package had significantly higher particle concentrations. It was confirmed by analyzing the 205 drug product samples that FIM particle counts are generally higher than LO counts. The cause of the higher counts of FIM method than LO counts was examined by looking into the contribution of proteinaceous, translucent particles in the samples. The data of the study showed that the number of proteinaceous, translucent particles was a factor in the elevated counts of FIM method compared to LO method.

Development and validation of a reporter gene assay to determine the bioactivity of anti-CTLA-4 monoclonal antibodies.

CTLA-4 is an important immune checkpoint for the regulation of T cell activation, and anti-CTLA-4 monoclonal antibodies (mAbs) are being developed as mono- or combination therapy for various tumors with reliable clinical efficacy. Ipilimumab is the first approved inhibitor of immune checkpoint, and many other anti-CTLA-4 mAbs, including ipilimumab biosimilars, are in different stages of clinical trials. However, due to the immunomodulating nature of the mAbs targeting CTLA-4, mode of action (MoA) and cell-based bioassay to determine their bioactivities as the lot release or stability test has been a great challenge to quality control laboratories. In this study, we have developed and validated a reporter gene assay (RGA), in which two kinds of cell lines were engineered to measure the bioactivity of anti-CTLA-4 mAbs. Raji cells were stably transfected with the membrane-anchored anti-CD3 single chain antibody fragment (scFv) as antigen-presenting cells (APCs, Raji-CD3scFv cells), while Jurkat cells were stably transfected with CTLA-4 with Y201V mutation and NFAT controlled luciferase as the effector cells (Jurkat-CTLA-4-NFAT-luc cells). The ligation of CD80/CD86 on the APCs with CTLA-4 could reduce the luciferase expression accompanied with the activation of effector cells, while the anti-CTLA-4 mAb could reverse the reduction, which resulted in good dose response curve to determine its bioactivity. After optimizing various assay conditions, we performed full validation according to ICH-Q2 (R1), which demonstrated the excellent specificity, accuracy, precision, linearity, and the cell passage stability. The satisfied performance characteristics render the RGA a good bioassay in the bioactivity determination of anti-CTLA-4 mAbs, as applied in characterization, batch release control, stability study, and biosimilar assessment.

Development of a novel reporter gene assay to evaluate antibody-dependent cellular phagocytosis for anti-CD20 therapeutic antibodies.

More than 100 monoclonal antibodies (mAbs) have been approved by FDA. The mechanism of action (MoA) involves in neutralization of a specific target via the Fab region and Fc effector functions through Fc region, while the latter include complement-dependent cytotoxicity (CDC), antibody-dependent cell-mediated cytotoxicity (ADCC) and antibody-dependent cellular phagocytosis (ADCP). ADCP has been recognized one of the most important MoAs, especially for anti-cancer mAbs in recent years. However, traditional bioassays measuring ADCP always introduced primary macrophages and flow cytometry, which are difficult to handle and highly variable. In this study, we engineered a monoclonal Jurkat/NFAT/CD32a-FcεRIγ effector cell line that stably expresses CD32a-FcεRIγ chimeric receptor and NFAT-controlled luciferase. The corresponding mAb could bind with the membrane antigens on the target cells with its Fab fragment and CD32a-FcεRIγ on the effector cells with its Fc fragment, leading to the crosslinking of CD32a-FcεRIγ and the resultant expression of subsequent NFAT-controlled luciferase, which represents the bioactivity of ADCP based on the MoA of the mAb. With rituximab as the model mAb, Raji cells as the target cells, and Jurkat/NFAT/CD32a-FcεRIγ cells as the effector cells, we adopted the strategy of Design of Experiment (DoE) to optimize the bioassay. Then we fully validated the established bioassay according to ICH-Q2(R1), which proved the good assay performance characteristics of the bioassay, including specificity, accuracy, precision, linearity, stability and robustness. This RGA can be applied to evaluate the -ADCP bioactivity for anti-CD20 mAbs in lot release, stability testing as well as biosimilar comparability. The engineered cells may also potentially be used to evaluate the ADCP bioactivity of mAbs with other targets.