Understanding the conformational impact of chemical modifications on monoclonal antibodies with diverse sequence variation using hydrogen/deuterium exchange mass spectrometry and structural modeling.

Chemical modifications can potentially induce conformational changes near the modification site and thereby impact the safety and efficacy of protein therapeutics. Hydrogen/deuterium exchange mass spectrometry (HDX-MS) has emerged as a powerful analytical technique with high spatial resolution and sensitivity in detecting such local conformational changes. In this study, we utilized HDX-MS combined with structural modeling to examine the conformational impact on monoclonal antibodies (mAbs) caused by common chemical modifications including methionine (Met) oxidation, aspartic acid (Asp) isomerization, and asparagine (Asn) deamidation. Four mAbs with diverse sequences and glycosylation states were selected. The data suggested that the impact of Met oxidation was highly dependent on its location and glycosylation state. For mAbs with normal glycosylation in the Fc region, oxidation of the two conserved Met252 and Met428 (Kabat numbering) disrupted the interface interactions between the CH2 and CH3 domains, thus leading to a significant decrease in CH2 domain thermal stability as well as a slight increase in aggregation propensity. In contrast, Met oxidation in the variable region and CH3 domain had no detectable impact on mAb conformation. For aglycosylated mAb, Met oxidation could cause a more global conformational change to the whole CH2 domain, coincident with the larger decrease in thermal stability and significant increase in aggregation rate. Unlike Met oxidation, Asn deamidation and Asp isomerization mostly had very limited effects on mAb conformation, with the exception of succiminide intermediate formation which induced a measurable local conformational change to be more solvent protected. Structural modeling suggested that the succinimide intermediate was stabilized by adjacent aromatic amino acids through ring-ring stacking interactions.

On-line H/D exchange LC-MS strategy for structural elucidation of pharmaceutical impurities.

Structural elucidation of pharmaceutical impurities in drug substances and drug products is an important task in pharmaceutical analysis in various phases of drug development. Liquid chromatography-mass spectrometry (LC-MS) technologies play a key role in this task owing to their general attributes of superior selectivity, sensitivity and speed. Full scan and product ion scan analysis, providing molecular weight information and fragmentation data, respectively, offer rich structural information and allow proposal of candidate structures rather quickly. However, these proposed structures often lack certainty especially when dealing with structural isomers. On-line hydrogen/deuterium (H/D) exchange by LC-MS using D2O as the mobile phase component is a powerful tool for identifying active hydrogen atoms, thus constituting a simple strategy for distinguishing between isomeric structures which are sometimes difficult by product ion spectral data or accurate mass data. This review describes the typical experimental setup we use routinely in the laboratories for performing H/D exchange LC-MS experiments in conjunction with representative applications of the strategy in structural elucidation of pharmaceutical impurities.