State-of-the-Art Native Mass Spectrometry and Ion Mobility Methods to Monitor Homogeneous Site-Specific Antibody-Drug Conjugates Synthesis.

Evolène Deslignière,Alain Beck,Anthony Ehkirch,Jonathan Sjögren,Valentina D’Atri,Bastiaan L Duivelshof,Sarah Cianférani,Oscar Hernandez-Alba,Davy Guillarme,Hanna Toftevall

doi:10.3390/ph14060498

Abstract

Antibody-drug conjugates (ADCs) are biotherapeutics consisting of a tumor-targeting monoclonal antibody (mAb) linked covalently to a cytotoxic drug. Early generation ADCs were predominantly obtained through non-selective conjugation methods based on lysine and cysteine residues, resulting in heterogeneous populations with varying drug-to-antibody ratios (DAR). Site-specific conjugation is one of the current challenges in ADC development, allowing for controlled conjugation and production of homogeneous ADCs. We report here the characterization of a site-specific DAR2 ADC generated with the GlyCLICK three-step process, which involves glycan-based enzymatic remodeling and click chemistry, using state-of-the-art native mass spectrometry (nMS) methods. The conjugation process was monitored with size exclusion chromatography coupled to nMS (SEC-nMS), which offered a straightforward identification and quantification of all reaction products, providing a direct snapshot of the ADC homogeneity. Benefits of SEC-nMS were further demonstrated for forced degradation studies, for which fragments generated upon thermal stress were clearly identified, with no deconjugation of the drug linker observed for the T-GlyGLICK-DM1 ADC. Lastly, innovative ion mobility-based collision-induced unfolding (CIU) approaches were used to assess the gas-phase behavior of compounds along the conjugation process, highlighting an increased resistance of the mAb against gas-phase unfolding upon drug conjugation. Altogether, these state-of-the-art nMS methods represent innovative approaches to investigate drug loading and distribution of last generation ADCs, their evolution during the bioconjugation process and their impact on gas-phase stabilities. We envision nMS and CIU methods to improve the conformational characterization of next generation-empowered mAb-derived products such as engineered nanobodies, bispecific ADCs or immunocytokines.

Highlights

We propose here size exclusion chromatography (SEC)-native mass spectrometry (nMS) and IM-based collision-induced unfolding (CIU) methods andasIM-based methods as innovative analyticaltotechniques, complementary to more innovative analytical techniques, complementary more classical biophysical techclassical biophysical techniques already implemented in most laboratories, niques already implemented in most R&D laboratories, to improve the conformational to improve the conformational characterization of next-generation empowered Antibody-drug conjugates (ADCs)
This study clearly highlights the benefits of using innovative nMS and IM methodologies for the analytical characterization of ADCproducts
A customized homogeneous site-specific ADC generated through glycan-based enzymatic remodeling and click chemistry was used as a case study

Summary

Introduction

Antibody-drug conjugates (ADC) have evolved into promising and efficient therapeutic agents for targeted chemotherapy, with 9 ADCs currently approved by Pharmaceuticals 2021, 14, 498. Pharmaceuticals 2021, 14, 498 the Food and Drug Administration (FDA), and more than 80 in clinical studies [1]. ADCs are generated through the conjugation of monoclonal antibodies (mAbs) which target the tumor cell, with highly potent cytotoxic drug payloads. Both elements are covalently bound via a cleavable or non-cleavable chemical linker. First-generation ADCs suffered from insufficient potency of the payload or toxicity due to the instability of the ADC, leading to premature drug release [2]. Bestselling second-generation ADCs include brentuximab vedotin (BV, Adcetris® from Seattle Genetics) and trastuzumab emtansine

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