LC-MS/MS peptide mapping with automated data processing for routine profiling of N-glycans in immunoglobulins.

Protein N-Glycan analysis is traditionally performed by high pH anion exchange chromatography (HPAEC), reversed phase liquid chromatography (RPLC), or hydrophilic interaction liquid chromatography (HILIC) on fluorescence-labeled glycans enzymatically released from the glycoprotein. These methods require time-consuming sample preparations and do not provide site-specific glycosylation information. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) peptide mapping is frequently used for protein structural characterization and, as a bonus, can potentially provide glycan profile on each individual glycosylation site. In this work, a recently developed glycopeptide fragmentation model was used for automated identification, based on their MS/MS, of N-glycopeptides from proteolytic digestion of monoclonal antibodies (mAbs). Experimental conditions were optimized to achieve accurate profiling of glycoforms. Glycan profiles obtained from LC-MS/MS peptide mapping were compared with those obtained from HPAEC, RPLC, and HILIC analyses of released glycans for several mAb molecules. Accuracy, reproducibility, and linearity of the LC-MS/MS peptide mapping method for glycan profiling were evaluated. The LC-MS/MS peptide mapping method with fully automated data analysis requires less sample preparation, provides site-specific information, and may serve as an alternative method for routine profiling of N-glycans on immunoglobulins as well as other glycoproteins with simple N-glycans.

IgG2 disulfide isoform conversion kinetics.

Human IgG2 antibodies contain three types of disulfide isoforms, classified by the number of Fab arms having disulfide links to the heavy chain hinge region. In the IgG2-B form, both Fab arms have interchain disulfide bonds to the hinge region, and in IgG2-A, neither Fab arm are disulfide linked to the hinge. The IgG2-A/B is a hybrid between these two forms, with only one Fab arm disulfide linked to the hinge. Changes in the relative levels of these forms over time are observed while IgG2 circulates in humans, suggesting IgG2-A→IgG2-A/B→IgG2-B conversion. Using a flow-through dialysis system, we studied the conversion kinetics of these forms in vitro under physiological conditions. For two IgG2κ antibodies, in vivo results closely matched the kinetics observed in vitro, indicating that the changes observed in vivo were solely conversions between isoforms, not differential clearance of specific forms. Moreover, the combined results validate the accuracy of the physiological model for the study of blood redox reactions. Further exploration of the conversion kinetics using material enriched in the IgG2-A forms revealed that the IgG2-A→IgG2-A/B rate was similar between IgG2κ and IgG2λ antibodies. In IgG2κ antibodies, conversion of IgG2-A/B→IgG2-B was slower than the IgG2-A→IgG2-A/B reaction. However, in IgG2λ antibodies, little IgG2-A/B→IgG2-B conversion was detected under physiological conditions. Thus, small differences in the C-terminus of the light chain sequences affect the disulfide conversion kinetics and impact the IgG2 disulfide isoforms produced in vivo.

Assessment of stable isotope incorporation into recombinant proteins.

Stable isotope labeling combined with mass spectrometry has been widely used in a diverse set of applications in the biochemistry and biomedical fields. When stable isotope-labeled proteins are produced via metabolic labeling of cell culture, a comprehensive assessment of the labeling pattern is imperative. In this study, we present a set of mass spectrometry-based bioanalytical tools developed for quantitatively tracing the levels of the stable isotopes incorporated into the recombinant proteins (monoclonal antibodies and Fc fusion proteins expressed in different host systems) that include total mass analysis, peptide mapping analysis, and amino acid analysis. We show that these three mass spectrometry-based analytical methods have distinctive advantages and limitations and that they are mutually complementary in evaluating the quality of stable isotope-labeled proteins. In addition, we show that the analytical techniques developed here are powerful tools to provide valuable insights into studying cell metabolism and performing flux analysis during cell culture.

Evaluation of protein disulfide conversion in vitro using a continuous flow dialysis system.

Recombinant therapeutic proteins are heterogeneous due to chemical and physical modifications. Understanding the impact of these modifications on drug safety and efficacy is critical for optimal process development and for setting reasonable specification limits. In this study, we describe the development of an in vitro continuous flow dialysis system to evaluate potential in vivo behavior of thiol adducted species and incorrectly disulfide bonded species of therapeutic proteins. The system is capable of maintaining the low-level cysteine concentrations found in human blood. Liabilities of cysteamine adducted species, incorrectly disulfide bonded species, and the correctly disulfide bonded form of an Fc-fusion protein were studied using this system. Results showed that 90% of the cysteamine adduct converted into the correctly disulfide bonded form and incorrectly disulfide bonded species in approximately 4 h under physiological conditions. Approximately 50% of incorrectly disulfide bonded species converted into the correctly bonded form in 2 days. These results provide valuable information on potential in vivo stability of the cysteamine adduct, incorrectly disulfide bonded species, and the correctly bonded form of the Fc-fusion protein. These are important considerations when evaluating the criticality of product quality attributes.

Analysis and characterization of aggregation of a therapeutic Fc-fusion protein.

Protein aggregation was observed in a purification intermediate of a therapeutic Fc-fusion protein stored at -30 °C, even though the protein was stable at 4 and -80 °C. The protein was expressed in Escherichia coli as an inclusion body, refolded, and purified using chromatography columns. To study the nature of this aggregation, a series of experiments were conducted to investigate factors that contributed to the protein instability during freezing. We found that the presence of free thiols in the protein is the intrinsic cause. The free thiol cross-linking sites were determined to be at the peptide moiety of the Fc-fusion protein using LC-MS. Partially frozen accompanied by the elevated pH and increased salt and protein concentrations were identified as extrinsic factors that facilitated the aggregation. These results provided important insights into purification process improvement and solution storage of this Fc-fusion protein.

Uncertainty estimates of purity measurements based on current information: toward a "live validation" of purity methods.

PURPOSE: To predict precision and other performance characteristics of chromatographic purity methods, which represent the most widely used form of analysis in the biopharmaceutical industry. METHODS: We have conducted a comprehensive survey of purity methods, and show that all performance characteristics fall within narrow measurement ranges. This observation was used to develop a model called Uncertainty Based on Current Information (UBCI), which expresses these performance characteristics as a function of the signal and noise levels, hardware specifications, and software settings. RESULTS: We applied the UCBI model to assess the uncertainty of purity measurements, and compared the results to those from conventional qualification. We demonstrated that the UBCI model is suitable to dynamically assess method performance characteristics, based on information extracted from individual chromatograms. CONCLUSIONS: The model provides an opportunity for streamlining qualification and validation studies by implementing a "live validation" of test results utilizing UBCI as a concurrent assessment of measurement uncertainty. Therefore, UBCI can potentially mitigate the challenges associated with laborious conventional method validation and facilitates the introduction of more advanced analytical technologies during the method lifecycle.

Quantification of protein posttranslational modifications using stable isotope and mass spectrometry. II. Performance.

In this report, we examine the performance of a mass spectrometry (MS)-based method for quantification of protein posttranslational modifications (PTMs) using stable isotope labeled internal standards. Uniform labeling of proteins and highly similar behavior of the labeled vs nonlabeled analyte pairs during chromatographic separation and electrospray ionization (ESI) provide the means to directly quantify a wide range of PTMs. In the companion report (Jiang et al., Anal. Biochem., 421 (2012) 506-516.), we provided principles and example applications of the method. Here we show satisfactory accuracy and precision for quantifying protein modifications by using the SILIS method when the analyses were performed on different types of mass spectrometers, such as ion-trap, time-of-flight (TOF), and quadrupole instruments. Additionally, the stable isotope labeled internal standard (SILIS) method demonstrated an extended linear range of quantification expressed in accurate quantification up to at least a 4 log concentration range on three different types of mass spectrometers. We also demonstrate that lengthy chromatographic separation is no longer required to obtain quality results, offering an opportunity to significantly shorten the method run time. The results indicate the potential of this methodology for rapid and large-scale assessment of multiple quality attributes of a therapeutic protein in a single analysis.

Quantification of protein posttranslational modifications using stable isotope and mass spectrometry I: principles and applications.

With the increased attention to quality by design (QbD) for biopharmaceutical products, there is a demand for accurate and precise quantification methods to monitor critical quality attributes (CQAs). To address this need we have developed a mass spectrometry (MS) based method to quantify a wide range of posttranslational modifications (PTMs) in recombinant proteins using stable isotope-labeled internal standard (SILIS). The SILIS was produced through metabolic labeling where ¹5N was uniformly introduced at every nitrogen atom in the studied proteins. To enhance the accuracy of the method, the levels of PTMs in SILIS were quantified using orthogonal analytical techniques. Digestion of an unknown sample mixed with SILIS generates a labeled and a nonlabeled version of each peptide. The nonlabeled and labeled counterparts coelute during RP-HPLC separation but exhibit a sufficient mass difference to be distinguished by MS detection. With the application of SILIS, numerous PTMs can be quantified in a single analysis based on the measured MS signal ratios of ¹5N-labeled versus the nonlabeled pairs. Several examples using microbial and mammalian-expressed recombinant proteins demonstrated the principle and utility of this method. The results indicate that SILIS is a valuable methodology in addressing CQAs for the QbD paradigm.

Phosphorylation of human high mobility group N1 protein by protein kinase CK2.

High mobility group (HMG) N1 protein, formerly known as HMG 14, is a member of the chromosomal HMG protein family. Protein kinase CK2 was previously reported to be able to phosphorylate bovine HMGN1 in vitro; Ser89 and Ser99, corresponding to Ser88 and Ser98 in human HMGN1, were shown to be major and minor recognition sites, respectively. In this report, we employed mass spectrometry and examined both the extent and the sites of phosphorylation in HMGN1 protein catalyzed by recombinant human protein kinase CK2. We found that five serine residues, i.e., Ser6, Ser7, Ser85, Ser88, and Ser98, in HMGN1 can be phosphorylated by the kinase in vitro. All five sites were previously shown to be phosphorylated in MCF-7 human breast cancer cells in vivo. Among these five sites, Ser6, Ser7, and Ser85 were new sites of phosphorylation induced by protein kinase CK2 in vitro.