High-Resolution IMS-MS to Assign Additional Disulfide Bridge Pairing in Complementarity-Determining Regions of an IgG4 Monoclonal Antibody.

Monoclonal antibodies (mAbs) have taken on an increasing importance for the treatment of various diseases, including cancers and immunological disorders. Disulfide bonds play a pivotal role in therapeutic antibody structure and activity relationships. Disulfide connectivity and cysteine-related variants are considered as critical quality attributes that must be monitored during mAb manufacturing and storage, as non-native disulfide bridges and aggregates might be responsible for loss of biological function and immunogenicity. The presence of cysteine residues in the complementarity-determining regions (CDRs) is rare in human antibodies but may be critical for the antigen-binding or deleterious for therapeutic antibody development. Consequently, in-depth characterization of their disulfide network is a prerequisite for mAb developability assessment. Mass spectrometry (MS) techniques represent powerful tools for accurate identification of disulfide connectivity. We report here on the MS-based characterization of an IgG4 comprising two additional cysteine residues in the CDR of its light chain. Classical bottom-up approaches after trypsin digestion first allowed identification of a dipeptide containing two disulfide bridges. To further investigate the conformational heterogeneity of the disulfide-bridged dipeptide, we performed ion mobility spectrometry-mass spectrometry (IMS-MS) experiments. Our results highlight benefits of high resolution IMS-MS to tackle the conformational landscape of disulfide peptides generated after trypsin digestion of a humanized IgG4 mAb under development. By comparing arrival time distributions of the mAb-collected and synthetic peptides, cyclic IMS afforded unambiguous assessment of disulfide bonds. In addition to classical peptide mapping, qualitative high-resolution IMS-MS can be of great interest to identify disulfide bonds within therapeutic mAbs.

Fast Afucosylation Profiling of Glycoengineered Antibody Subunits by Middle-Up Mass Spectrometry.

Middle-up LC-MS antibody characterization workflows using reduction or IdeS digestion for a focused assessment of N-glycan profiling of three representative glycoengineered monoclonal antibodies (mAbs), namely, obinutuzumab (GlycomAb technology, Glycart/Roche), benralizumab (Potelligent Technology, BioWa, Kyowa Kirin) and mAb B (kifunensine) and compared to mAb A, produced in a common CHO cell line. In addition, EndoS or EndoS2 enzyme are used for quantitative determination of Fc-glycan core afucosylation and high mannose for these antibodies, as requested by health authorities for Fc-competent therapeutics mAbs critical quality attributes (CQAs).

Middle Level IM-MS and CIU Experiments for Improved Therapeutic Immunoglobulin Subclass Fingerprinting.

Most of the current FDA and EMA approved therapeutic monoclonal antibodies (mAbs) are based on humanized or human IgG1, 2, or 4 subclasses and engineered variants. On the structural side, these subclasses are characterized by specific interchain disulfide bridge connections. Different analytical techniques have been reported to assess intact IgGs subclasses, with recently special interest in native ion mobility (IM) and collision induced unfolding (CIU) mass spectrometry (MS). However, these two techniques exhibit significant limitations to differentiate mAb subclasses at the intact level. In the present work, we aimed at developing a unique IM-MS-based approach for the characterization of mAb subclasses at the middle level. Upon IdeS-digestion, the unfolding patterns of the F(ab')2 and Fc domains were simultaneously analyzed in a single run to provide deeper structural insights of the mAb scaffold. The unfolding patterns associated with the F(ab')2 domains are completely different in terms of unfolding energies and number of transitions. Thereby, F(ab')2 regions are the diagnostic domain to provide specific unfolding signatures to differentiate IgG subclasses and provide more confident subclass categorization than CIU on intact mAbs. In addition, the potential of middle-level CIU was evaluated through the characterization of eculizumab, a hybrid therapeutic IgG2/4 mAb. The unfolding signatures of both domains were allowed to corroborate, within a single run, the hybrid nature of eculizumab as well as specific subclass domain assignments to the F(ab')2 and Fc regions. Altogether, our results confirm the suitability of middle-level CIU of F(ab')2 domains for subclass categorization of canonical and more complex new generation engineered antibodies and related products.

Drug Loading and Distribution of ADCs After Reduction or IdeS Digestion and Reduction.

High-resolution native mass spectrometry (MS) provides accurate mass measurements (within 30 ppm) of intact ADCs and can also yield drug load distribution (DLD) and average drug to antibody ratio (DAR) in parallel with hydrophobic interaction chromatography (HIC). Native MS is furthermore unique in its ability to simultaneously detect covalent and noncovalent species in a mixture and for HIC peak identity assessment offline or online.As an orthogonal method described in this chapter, LC-MS following ADC reduction or IdeS (Fabricator) digestion and reduction can also be used to measure the DLD of light chain and Fd fragments for hinge native cysteine residues such as brentuximab vedotin. Both methods allow also the measurement of average DAR for both monomeric and multimeric species. In addition, the Fc fragments can be analyzed in the same run, providing a complete glycoprofile and the demonstration or absence of additional conjugation of this subdomain involved in FcRn and Fc-gammaR binding.

Native Mass Spectrometry, Ion Mobility, and Collision-Induced Unfolding for Conformational Characterization of IgG4 Monoclonal Antibodies.

Although the majority of FDA and EMA approved therapeutic monoclonal antibodies (mAbs) are IgG1, the number of IgG4-based formats reaching the market is increasing. IgG4 differs from other mAb isotypes by its specificity to form half mAbs that recombine into bispecific (bsAbs) molecules, through a process termed fab-arm exchange (FAE). We report here the complementarity of native mass spectrometry (MS), ion mobility (IM), and collision-induced unfolding (CIU) experiments for the structural characterization of members of the IgG4 subfamily (wild-type (wt), hinge-stabilized (hs, S228P mutation), and the resulting bsAb IgG4s). Native MS allows confirming/invalidating the occurrence of FAE as a function of these different types of IgG4. While IM-MS was unable to distinguish iso-cross-section IgG4 species, CIU experiments provide unique specific structural signatures of each individual IgG4 based on their specific unfolding pathways. Common CIU features of IgG4 formats include the observation of three conformational states and two transitions. In addition, CIU experiments demonstrated that S228P mutation stabilizes gas phase conformations of hsIgG4, in agreement with increased stability related to more rigid hinge regions. CIU patterns also appear to be more informative than IM-MS for bsAb structural characterization, unfolding signature of the bsAb being intermediate to the ones of the former parent wt-IgG4s, highlighting that bsAb CIU profiles keep the memory of their origins. Altogether, our results demonstrate that CIU patterns can serve as mAb specific structural signatures and are mature to be included in MS-based analytical workflows for conformational/structural characterization of mAb formats in early development phases and for multiple attribute monitoring.

Monoclonal antibody N-glycosylation profiling using capillary electrophoresis - Mass spectrometry: Assessment and method validation.

Characterization of therapeutic proteins represents a major challenge for analytical sciences due to their heterogeneity caused by post-translational modifications (PTM). Among these PTM, glycosylation which is possibly the most prominent, require comprehensive identification because of their major influence on protein structure and effector functions of monoclonal antibodies (mAbs). As a consequence, glycosylation profiling must be deeply characterized. For this application, several analytical methods such as separation-based or MS-based methods, were evaluated. However, no CE-ESI-MS approach has been assessed and validated. Here, we illustrate how the use of CE-ESI-MS method permits the comprehensive characterization of mAbs N-glycosylation at the glycopeptide level to perform relative quantitation of N-glycan species. Validation of the CE-ESI-MS method in terms of robustness and reproducibility was demonstrated through the relative quantitation of glycosylation profiles for ten different mAbs produced in different cell lines. Glycosylation patterns obtained for each mAbs were compared to Hydrophilic Interaction Chromatography of 2-aminobenzamide labelled glycans with fluorescence detector (HILIC-FD) analysis considered as a reference method. Very similar glycoprofiling were obtained with the CE-ESI-MS and HILIC-FD demonstrating the attractiveness of CE-ESI-MS method to characterize and quantify the glycosylation heterogeneity of a wide range of therapeutic mAbs with high accuracy and precision.

Epitope characterization of anti-JAM-A antibodies using orthogonal mass spectrometry and surface plasmon resonance approaches.

Junctional adhesion molecule-A (JAM-A) is an adherens and tight junction protein expressed by endothelial and epithelial cells and associated with cancer progression. We present here the extensive characterization of immune complexes involving JAM-A antigen and three monoclonal antibodies (mAbs), including hz6F4-2, a humanized version of anti-tumoral 6F4 mAb identified by a functional and proteomic approach in our laboratory. A specific workflow that combines orthogonal approaches has been designed to determine binding stoichiometries along with JAM-A epitope mapping determination at high resolution for these three mAbs. Native mass spectrometry experiments revealed different binding stoichiometries and affinities, with two molecules of JAM-A being able to bind to hz6F4-2 and F11 Fab, while only one JAM-A was bound to J10.4. Surface plasmon resonance indirect competitive binding assays suggested epitopes located in close proximity for hz6F4-2 and F11. Finally, hydrogen-deuterium exchange mass spectrometry was used to precisely identify epitopes for all mAbs. The results obtained by orthogonal biophysical approaches showed a clear correlation between the determined epitopes and JAM-A binding characteristics, allowing the basis for molecular recognition of JAM-A by hz6F4-2 to be definitively established for the first time. Taken together, our results highlight the power of MS-based structural approaches for epitope mapping and mAb conformational characterization.

Protocols for the analytical characterization of therapeutic monoclonal antibodies. I - Non-denaturing chromatographic techniques.

Size-, charge- and hydrophobicity-related variants of a biopharmaceutical product have to be deeply characterized for batch consistency and for the assessment of immunogenicity and safety effects. Size exclusion chromatography (SEC) and ion exchange chromatography (IEX) are considered as the gold standard for the analysis of high molecular weight species (HMWS) and charge-related variants, respectively. Hydrophobic interaction chromatography (HIC) has drawn renewed attention to monitor the small drug payload distribution in the cysteine-linked antibody-drug conjugates (ADC). These three chromatographic techniques, namely SEC, HIC and IEX, are historical, non-denaturing and robust approaches widely used for the characterization of biopharmaceutical proteins. Despite the broad spectrum of monoclonal antibodies (mAbs) structures, isoelectric points (pIs) and hydrophobicities, generic protocols can be applied to separate their size-, charge- and hydrophobicity-related variants, using the last generation of chromatographic columns and appropriate mobile phase conditions. Straightforward protocols are described in this manuscript with representative chromatograms of ten distinct Food and Drug Administration (FDA) and European Medicines Agency (EMA) approved therapeutic mAb products to illustrate the performance of the SEC, IEX and HIC methods.

Insights from native mass spectrometry approaches for top- and middle- level characterization of site-specific antibody-drug conjugates.

Antibody-drug conjugates (ADCs) have emerged as a family of compounds with promise as efficient immunotherapies. First-generation ADCs were generated mostly via reactions on either lysine side-chain amines or cysteine thiol groups after reduction of the interchain disulfide bonds, resulting in heterogeneous populations with a variable number of drug loads per antibody. To control the position and the number of drug loads, new conjugation strategies aiming at the generation of more homogeneous site-specific conjugates have been developed. We report here the first multi-level characterization of a site-specific ADC by state-of-the-art mass spectrometry (MS) methods, including native MS and its hyphenation to ion mobility (IM-MS). We demonstrate the versatility of native MS methodologies for site-specific ADC analysis, with the unique ability to provide several critical quality attributes within one single run, along with a direct snapshot of ADC homogeneity/heterogeneity without extensive data interpretation. The capabilities of native IM-MS to directly access site-specific ADC conformational information are also highlighted. Finally, the potential of these techniques for assessing an ADC's heterogeneity/homogeneity is illustrated by comparing the analytical characterization of a site-specific DAR4 ADC to that of first-generation ADCs. Altogether, our results highlight the compatibility, versatility, and benefits of native MS approaches for the analytical characterization of all types of ADCs, including site-specific conjugates. Thus, we envision integrating native MS and IM-MS approaches, even in their latest state-of-the-art forms, into workflows that benchmark bioconjugation strategies.

Development of a fast workflow to screen the charge variants of therapeutic antibodies.

Chemical or enzymatic modifications of therapeutic monoclonal antibodies (mAbs) having high risk towards safety and efficacy are defined as critical quality attributes (CQAs). During therapeutic mAbs process development, a variety of analytical techniques have to be used for the thorough characterization and quantitative monitoring of CQAs. This paper describes the development of a rapid analytical platform to assess and rank charge variants of mAbs. The workflow is first based on a cation exchange chromatography (CEX) comparative analysis of intact IgGs versus F(ab)'2 and Fc sub-domains generated by IdeS digestion. This analytical procedure was validated with FDA and EMA approved mAbs. Then, functional assays and peptide mapping can be performed in a second instance. This approach can be used during the early stage of drug research and development to screen lead molecules and select optimized candidates (best clone, best formulation) which could be "easily" developed (OptimAbs).

Cutting-edge mass spectrometry methods for the multi-level structural characterization of antibody-drug conjugates.

Antibody drug conjugates (ADCs) are highly cytotoxic drugs covalently attached via conditionally stable linkers to monoclonal antibodies (mAbs) and are among the most promising next-generation empowered biologics for cancer treatment. ADCs are more complex than naked mAbs, as the heterogeneity of the conjugates adds to the inherent microvariability of the biomolecules. The development and optimization of ADCs rely on improving their analytical and bioanalytical characterization by assessing several critical quality attributes, namely the distribution and position of the drug, the amount of naked antibody, the average drug to antibody ratio, and the residual drug-linker and related product proportions. Here brentuximab vedotin (Adcetris) and trastuzumab emtansine (Kadcyla), the first and gold-standard hinge-cysteine and lysine drug conjugates, respectively, were chosen to develop new mass spectrometry (MS) methods and to improve multiple-level structural assessment protocols.

Characterization of the N-terminal heterogeneities of monoclonal antibodies using in-gel charge derivatization of α-amines and LC-MS/MS.

The bioproduction of recombinant monoclonal antibodies results in complex mixtures of a main isoform and numerous macro- and microvariants. Monoclonal antibodies therefore present different levels of heterogeneities ranging from primary sequence variants to post-translational modifications. Among these heterogeneities, the truncation and fragmentation of the primary amino-acid sequence result in shorter or cleaved polypeptide chains while the incomplete processing of the signal peptide produces N-terminal elongated polypeptide chains. Here, we present an in-gel protein N-terminal chemical derivatization method using (N-succinimidyloxycarbonylmethyl)-tris(2,4,6-trimethoxyphenyl)phosphonium bromide (TMPP). This chemical tag enhances the detection by mass spectrometry of the N-terminal positions of proteins and allows their unambiguous assignment without altering the identification of internal digestion peptides. This method adds just one step to the classical peptide mapping workflow. Using this in-gel N-TOP (N-terminal oriented proteomics) strategy, the N-terminal sequence heterogeneities of several monoclonal antibodies, among which are minor unexpected proteoforms, were successfully detected and characterized.

Cutting-edge mass spectrometry characterization of originator, biosimilar and biobetter antibodies.

The approval process for antibody biosimilars relies primarily on comprehensive analytical data to establish comparability and high similarity with the originator. Mass spectrometry (MS) in combination with liquid chromatography (LC) and electrophoretic methods are the corner stone for comparability and biosimilarity evaluation. In this special feature we report head-to-head comparison of trastuzumab and cetuximab with corresponding biosimilar and biobetter candidates based on cutting-edge mass spectrometry techniques such as native MS and ion-mobility MS at different levels (top, middle and bottom). In addition, we discuss the advantages and the limitations of sample preparation and enzymatic digestion, middle-up and -down strategies and the use of hydrogen/deuterium exchange followed by MS (HDX-MS). Last but not least, emerging separation methods combined to MS such as capillary zone electrophoresis-tandem MS (CESI-MS/MS), electron transfer dissociation (ETD), top down-sequencing (TDS) and high-resolution MS (HR-MS) that complete the panel of state-of-the-art MS-based options for comparability and biosimilarity evaluation are presented.

Native mass spectrometry and ion mobility characterization of trastuzumab emtansine, a lysine-linked antibody drug conjugate.

Antibody-drug conjugates (ADCs) are biochemotherapeutics consisting of a cytotoxic chemical drug linked covalently to a monoclonal antibody. Two main classes of ADCs, namely cysteine and lysine conjugates, are currently available on the market or involved in clinical trials. The complex structure and heterogeneity of ADCs makes their biophysical characterization challenging. For cysteine conjugates, hydrophobic interaction chromatography is the gold standard technique for studying drug distribution, the naked antibody content, and the average drug to antibody ratio (DAR). For lysine ADC conjugates on the other hand, which are not amenable to hydrophobic interaction chromatography because of their higher heterogeneity, denaturing mass spectrometry (MS) and UV/Vis spectroscopy are the most powerful approaches. We report here the use of native MS and ion mobility (IM-MS) for the characterization of trastuzumab emtansine (T-DM1, Kadcyla(®)). This lysine conjugate is currently being considered for the treatment of human epidermal growth factor receptor 2 (HER2)-positive breast cancer, and combines the anti-HER2 antibody trastuzumab (Herceptin(®)), with the cytotoxic microtubule-inhibiting maytansine derivative, DM1. We show that native MS combined with high-resolution measurements and/or charge reduction is beneficial in terms of the accurate values it provides of the average DAR and the drug load profiles. The use of spectral deconvolution is discussed in detail. We report furthermore the use of native IM-MS to directly determine DAR distribution profiles and average DAR values, as well as a molecular modeling investigation of positional isomers in T-DM1.

Innovative native MS methodologies for antibody drug conjugate characterization: High resolution native MS and IM-MS for average DAR and DAR distribution assessment.

Antibody drug conjugates (ADCs) are macromolecules composed of cytotoxic drugs covalently attached via a conditionally stable linker to monoclonal antibodies (mAbs). ADCs are among the most promising next generation of empowered mAbs foreseen to treat cancers. Compared to naked mAbs, ADCs have an increased level of complexity as the heterogeneity of conjugation cumulates with the inherent microvariability of the biomolecule. An increasing need underlying ADC's development and optimization is to improve its analytical and bioanalytical characterization by assessing three main ADC quality attributes: drug distribution, amount of naked antibody, and average drug to antibody ratio (DAR). Here, the analytical potential of native mass spectrometry (MS) and native ion mobility MS (IM-MS) is compared to hydrophobic interaction chromatography (HIC), the reference method for quality control of interchain cysteinyl-linked ADCs. Brentuximab vedotin, first in class and gold standard, was chosen for a proof of principle. High resolution native MS provided accurate mass measurement (<30 ppm) of intact ADCs together with average DAR and drug distribution, confirming the unique ability of native MS for simultaneous detection of mixtures of covalent and noncovalent products. Native IM-MS was next used for the first time to characterize an ADC. IM-MS evidenced ADC multiple drug loading, collisional cross sections measurement of each payload species attesting slight conformational changes. A semiquantitative interpretation of IM-MS data was developed to directly extrapolate average DAR and DAR distribution. Additionally, HIC fractions were collected and analyzed by native MS and IM-MS, assessing the interpretation of each HIC peak. Altogether, our results illustrate how native MS and IM-MS can rapidly assess ADC structural heterogeneity and how easily these methods can be implemented into MS workflows for in-depth ADC analytical characterization.

Antibody-drug conjugate model fast characterization by LC-MS following IdeS proteolytic digestion.

Here we report the design and production of an antibody-fluorophore conjugate (AFC) as a non-toxic model of an antibody-drug conjugate (ADC). This AFC is based on the conjugation of dansyl sulfonamide ethyl amine (DSEA )-linker maleimide on interchain cysteines of trastuzumab used as a reference antibody. The resulting AFC was first characterized by routine analytical methods (SEC, SDS-PAGE, CE-SDS, HIC and native MS), resulting in similar chromatograms,electropherograms and mass spectra to those reported for hinge Cys-linked ADCs. IdeS digestion of the AFC was then performed, followed by reduction and analysis by liquid chromatography coupled to mass spectrometry analysis. Dye loading and distribution on light chain and Fd fragments were calculated, as well as the average dye to antibody ratio (DAR) for both monomeric and multimeric species. In addition, by analyzing the Fc fragment in the same run, full glycoprofiling and demonstration of the absence of additional conjugation was easily achieved. As for naked antibodies and Fc-fusion proteins, IdeS proteolytic digestion may rapidly become a reference analytical method at all stages of ADC discovery, preclinical and clinical development. The method can be routinely used for comparability assays, formulation, process scale-up and transfer, and to define critical quality attributes in a quality-by-design approach.

Time resolved native ion-mobility mass spectrometry to monitor dynamics of IgG4 Fab arm exchange and "bispecific" monoclonal antibody formation.

Monoclonal antibodies (mAbs) and derivatives such as antibody-drug conjugates (ADC) and bispecific antibodies (bsAb), are the fastest growing class of human therapeutics. Most of the therapeutic antibodies currently on the market and in clinical trials are chimeric, humanized, and human immunoglobulin G1 (IgG1). An increasing number of IgG2s and IgG4s that have distinct structural and functional properties are also investigated to develop products that lack or have diminished antibody effector functions compared to IgG1. Importantly, wild type IgG4 has been shown to form half molecules (one heavy chain and one light chain) that lack interheavy chain disulfide bonds and form intrachain disulfide bonds. Moreover, IgG4 undergoes a process of Fab-arm exchange (FAE) in which the heavy chains of antibodies of different specificities can dissociate and recombine in bispecific antibodies both in vitro and in vivo. Here, native mass spectrometry (MS) and time-resolved traveling wave ion mobility MS (TWIM-MS) were used for the first time for online monitoring of FAE and bsAb formation using Hz6F4-2v3 and natalizumab, two humanized IgG4s which bind to human Junctional Adhesion Molecule-A (JAM-A) and alpha4 integrin, respectively. In addition, native MS analysis of bsAb/JAM-A immune complexes revealed that bsAb can bind up to two antigen molecules, confirming that the Hz6F4 family preferentially binds dimeric JAM-A. Our results illustrate how IM-MS can rapidly assess bsAb structural heterogeneity and be easily implemented into MS workflows for bsAb production follow up and bsAb/antigen complex characterization. Altogether, these results provide new MS-based methodologies for in-depth FAE and bsAb formation monitoring. Native MS and IM-MS will play an increasing role in next generation biopharmaceutical product characterization like bsAbs, antibody mixtures, and antibody-drug conjugates (ADC) as well as for biosimilar and biobetter antibodies.

Correct primary structure assessment and extensive glyco-profiling of cetuximab by a combination of intact, middle-up, middle-down and bottom-up ESI and MALDI mass spectrometry techniques.

The European Medicines Agency received recently the first marketing authorization application for a biosimilar monoclonal antibody (mAb) and adopted the final guidelines on biosimilar mAbs and Fc-fusion proteins. The agency requires high similarity between biosimilar and reference products for approval. Specifically, the amino acid sequences must be identical. The glycosylation pattern of the antibody is also often considered to be a very important quality attribute due to its strong effect on quality, safety, immunogenicity, pharmacokinetics and potency. Here, we describe a case study of cetuximab, which has been marketed since 2004. Biosimilar versions of the product are now in the pipelines of numerous therapeutic antibody biosimilar developers. We applied a combination of intact, middle-down, middle-up and bottom-up electrospray ionization and matrix assisted laser desorption ionization mass spectrometry techniques to characterize the amino acid sequence and major post-translational modifications of the marketed cetuximab product, with special emphasis on glycosylation. Our results revealed a sequence error in the reported sequence of the light chain in databases and in publications, thus highlighting the potency of mass spectrometry to establish correct antibody sequences. We were also able to achieve a comprehensive identification of cetuximab's glycoforms and glycosylation profile assessment on both Fab and Fc domains. Taken together, the reported approaches and data form a solid framework for the comparability of antibodies and their biosimilar candidates that could be further applied to routine structural assessments of these and other antibody-based products.

NanoLC Chips MS/MS for the characterization of N-glycopeptides generated from trypsin digestion of a monoclonal antibody.

In the field of therapeutic recombinant proteins, monoclonal antibodies (mAbs) have achieved a rising success with more than 30 mAbs that have reached the market in the past 20 years. From a structural standpoint, one of the most important posttranslational modifications affecting antibodies is by far glycosylation. Furthermore, glycosylation of mAbs directly impacts on their biological activity and safety and therefore needs to be well characterized. Glycoprotein analysis requires high-resolution separation techniques that can provide detailed structural analysis able to discriminate between glycoforms of various abundances. This chapter describes a protocol for nanoLC-Chip-MS/MS analysis of a proteolytic digest of the heavy chain of a recombinant mAb. The use of graphitized carbon column instead of classical C18 reversed-phase material is shown to be well suited to detect low abundant glycoforms and to provide in one shot information regarding both the oligosaccharide structure and the amino acid sequence of its peptide moiety.