Charge variant analysis (CVA) of monoclonal antibodies (mAbs) using cation exchange chromatography is routinely used as a fingerprint of the distribution of posttranslational modifications present on the molecule. Traditional salt or pH based eluents are not suited for direct coupling to mass spectrometry due to nonvolatility or high ionic strength. This makes further analysis complicated when an alteration in the charge variant profile or the emergence of an additional peak is encountered. Here, the use of pH gradient elution using volatile, low ionic strength buffers is reported with direct coupling to high-resolution Orbitrap mass spectrometry. The development of a universal method based on pH elution was explored using a number of mAb drug products. Optimized methods facilitated the separation and identification of charge variants including individual glycoforms of the mAbs investigated using the same buffer system but with tailored gradient slopes. The developed method represents an exciting advance for the characterization of biopharmaceuticals as intact entities through the combination of native charge variant separations with high-resolution native mass spectrometry.
Charge variant analysis is a widely used tool to monitor changes in product quality during the manufacturing process of monoclonal antibodies (mAbs). Although it is a powerful technique for revealing mAb heterogeneity, an unexpected outcome, for example the appearance of previously undetected isoforms, requires further, time-consuming analysis. The process of identifying these unknowns can also result in unwanted changes to the molecule that are not attributable to the manufacturing process. To overcome this, we recently reported a method combining highly selective cation exchange chromatography-based charge variant analysis with on-line mass spectrometric (MS) detection. We further explored and adapted the chromatographic buffer system to expand the application range. Moreover, we observed no salt adducts on the native protein, also supported by the optimal choice of MS parameters, resulting in increased data quality and mass accuracy. Here, we demonstrate the utility of this improved method by performing an in-depth analysis of adalimumab before and after forced degradation. By combining molecular mass and retention time information, we were able to identify multiple modifications on adalimumab, including lysine truncation, glycation, deamidation, succinimide formation, isomerisation, N-terminal aspartic acid loss or C-terminal proline amidation and fragmentation along with the N-glycan distribution of each of these identified proteoforms. Host cell protein (HCP) analysis was performed using liquid chromatography-mass spectrometry that verified the presence of the protease Cathepsin L. Based on the presence of trace HCPs with catalytic activity, it can be questioned if fragmentation is solely driven by spontaneous hydrolysis or possibly also by enzymatic degradation.
Charge
sensitive separation methods such as ion exchange chromatography
(CEX) and capillary electrophoresis (CE) have recently been coupled
to mass spectrometry to facilitate high resolution profiling of proteoforms
present within the charge variant profile of complex biopharmaceuticals.
Here we apply pH gradient cation exchange chromatography and microfluidic
capillary electrophoresis using the ZipChip platform for comparative
characterization of the monoclonal antibody Cetuximab. Cetuximab harbors
four glycans per molecule, two on each heavy chain, of which the Fab
glycans have been reported to be complex and multiply sialylated.
The presence of these extra glycosylation sites in the variable region
of the molecule causes significant charge variant and glycan heterogeneity,
which makes comprehensive analysis on the intact protein level challenging.
Both pH gradient CEX-MS and CE-MS were found to be powerful for the
separation of Cetuximab charge variants with eight major peaks being
baseline resolved using both separation platforms. Informative native-like
mass spectra were collected for each charge variant peak using both
platforms that facilitated deconvolution and further analysis. The
total proteoform coverage was exceptionally high with >100 isoforms
identified and relatively quantified with CEX-MS, in case of CE-MS
the proteoform coverage was >200. A deep insight into the heterogeneity
of Cetuximab was unveiled, the high level of sensitivity achievable
enables the implementation of the presented technologies even at early
stages of the biopharmaceutical development platform, such as in developability
assessment, process development and also for monitoring process consistency.
Posttranslational modifications of
proteins play fundamental roles in protein function in health and
disease. More than 600 different types of posttranslational modifications
are known, many of them being of extremely low abundance, causing
subtle changes in physicochemical properties and posing an extreme
challenge to analytical methods required for their characterization.
Here, we report the development of a novel pH gradient-based anion-exchange
chromatography method, which can be directly interfaced to Orbitrap-based
mass spectrometry for the comprehensive characterization of proteoforms
at the intact protein level under native conditions. The analysis
of four different proteins demonstrates outstanding chromatographic
selectivity, while the mass spectra obtained are of excellent quality
enabling the identification of proteoforms, including near isobaric
variants, spanning 4 orders of magnitude in abundance. An in-depth
analysis of ovalbumin from chicken egg white yields the identification
and relative quantification of more than 150 different proteoforms,
including fragmented and dimeric forms. More than 20 different ovalbumin
charge variants together with their glycoform distributions are identified
and quantified, many of which have not been reported previously.
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