Antibody structural integrity of site-specific antibody-drug conjugates investigated by hydrogen/deuterium exchange mass spectrometry.

We present the results of a hydrogen/deuterium exchange mass spectrometric (HDX-MS) investigation of an antibody-drug conjugate (ADC) comprised of drug-linkers conjugated to cysteine residues that have been engineered into heavy chain (HC) fragment crystallizable (Fc) domain at position 239. A side-by-side comparison of the HC Ser239 wild type (wt) monoclonal antibody (mAb) and the engineered Cys239 mAb indicates that site directed mutagenesis of Ser239 to cysteine has no impact on the HDX kinetics of the mAb. According to the crystal structure of a homologous immunoglobulin G1 (IgG1) antibody (PDB: 1HZH ), the backbone amide of Ser239 is hydrogen-bonded to Val264 backbone amide in the wt-mAb studied here. Replacing Ser239 with a Cys residue does not alter the exchange kinetics of the backbone amide of Val264 suggesting that either Ser or Cys at position 239 has similar amide-hydrogen bonding with Val264. However, a small segment in CH2 domain of the ADC ((264)VDVS) was found to have a slightly increased HDX rate compared to the wt- and C239-mAb constructs. The slightly increased HDX rate of the segment (264)VDVS in ADCs indicates that the further modification of Cys239 with drug-linkers only attenuates the local backbone amide hydrogen-bonding network between Cys239 and Val264. All other regions which are proximal to the site of drug conjugation are unaffected. The results demonstrate that the site-specific drug conjugation at the engineered Cys residue at the position 239 of HC does not impact the structural integrity of antibodies. The results also highlight the utility of applying HDX-MS to ADCs to gain a molecular level insight into the impact of site-specific conjugation technologies on the higher-order structure (HOS) of mAbs. The methodology can be applied generally to site-specific ADC modalities to understand the individual contributions of site-mutagenesis and drug-linker conjugation on the HOS of therapeutic candidate ADCs.

Conformation and dynamics of interchain cysteine-linked antibody-drug conjugates as revealed by hydrogen/deuterium exchange mass spectrometry.

Antibody-drug conjugates (ADCs) are protein therapeutics in which a target specific monoclonal antibody (mAb) is conjugated with drug molecules. The manufacturing of ADCs involves additional conjugation steps, which are carried out on the parent mAbs, and it is important to evaluate how the drug conjugation process impacts the conformation and dynamics of the mAb. Here, we present a comparative study of interchain cysteine linked IgG1 ADCs and the corresponding mAb by hydrogen/deuterium exchange mass spectrometry (HDX-MS). We found that ∼90% of the primary sequence of the ADC conjugated with either monomethyl auristatin E or F (vcMMAE/mcMMAF) displayed the same HDX kinetics as the mAb, indicating the ADCs and mAbs share very similar conformation and dynamics in solution. Minor increases in HDX kinetic rates were observed in two Fc regions in the ADCs relative to the mAb which indicated that both regions become more structurally dynamic and/or more solvent-accessible in the ADCs. The findings led to a subsequent inquiry into whether the local conformational changes were due to the presence of drugs on the interchain cysteine residues or the absence of intact interchain disulfides or both. To address this question, a side-by-side HDX comparison of ADCs, mAbs, reduced mAbs (containing 8 reduced interchain cysteine thiols), and partially reduced mAbs (conjugation process intermediate) was performed. Our results indicated that the slight increase in conformational dynamics detected at the two regions in the ADCs was due to the absence of intact interchain disulfide bonds and not the presence of vcMMAE or mcMMAF on the alkylated interchain cysteine residues. These results highlight the utility of HDX-MS for interrogating the higher-order structure of ADCs and other protein therapeutics.

Localized conformational interrogation of antibody and antibody-drug conjugates by site-specific carboxyl group footprinting.

Establishing and maintaining conformational integrity of monoclonal antibodies (mAbs) and antibody-drug conjugates (ADCs) during development and manufacturing is critical for ensuring their clinical efficacy. As presented here, we applied site-specific carboxyl group footprinting (CGF) for localized conformational interrogation of mAbs. The approach relies on covalent labeling that introduces glycine ethyl ester tags onto solvent-accessible side chains of protein carboxylates. Peptide mapping is used to monitor the labeling kinetics of carboxyl residues and the labeling kinetics reflects the conformation or solvent-accessibility of side chains. Our results for two case studies are shown here. The first study was aimed at defining the conformational changes of mAbs induced by deglycosylation. We found that two residues in CH2 domain (D268 and E297) show significantly enhanced side chain accessibility upon deglycosylation. This site-specific result highlighted the advantage of monitoring the labeling kinetics at the amino acid level as opposed to the peptide level, which would result in averaging out of highly localized conformational differences. The second study was designed to assess conformational effects brought on by conjugation of mAbs with drug-linkers. All 59 monitored carboxyl residues displayed similar solvent-accessibility between the ADC and mAb under native conditions, which suggests the ADC and mAb share similar side chain conformation. The findings are well correlated and complementary with results from other assays. This work illustrated that site-specific CGF is capable of pinpointing local conformational changes in mAbs or ADCs that might arise during development and manufacturing. The methodology can be readily implemented within the industry to provide comprehensive conformational assessment of these molecules.