Comparative analysis of monoclonal antibody N-glycosylation using stable isotope labelling and UPLC-fluorescence-MS.

A twoplex method using (12)C6 and (13)C6 stable isotope analogues (Δmass = 6 Da) of 2-aminobenzoic acid (2-AA) is described for quantitative analysis of N-glycans present on monoclonal antibodies and other glycoproteins using ultra performance liquid chromatography with sequential fluorescence and accurate mass tandem quadrupole time of flight (QToF) mass spectrometric detection.

Application of multi-omics techniques for bioprocess design and optimization in chinese hamster ovary cells.

Significant improvements in the productivity and quality of therapeutic proteins produced in Chinese hamster ovary (CHO) cells have been reported since their establishment as host cells for biopharmaceutical production. Initial advances in the field focused on engineering strategies to manipulate genes associated with proliferation, apoptosis, and various metabolic pathways. Process engineering efforts to optimize culture media, batch-feeding strategies and culture conditions, including temperature and osmolarity, were also reported. More recently, focus has shifted toward enhancing process consistency and product quality using systems biology quality by design-based approaches during process development. Integration of different data generated using omics technologies, such as genomics, transcriptomics, proteomics and metabolomics, has facilitated a greater understanding of CHO cell biology. These techniques have enabled the provision of global information on dynamic changes in cellular components associated with different phenotypes. Using systems biology to understand these important host cells at the cellular level will undoubtedly result in further progression in the development and expression of biopharmaceutical products in CHO cells.

N- and O-glycosylation analysis of etanercept using liquid chromatography and quadrupole time-of-flight mass spectrometry equipped with electron-transfer dissociation functionality.

Etanercept is a highly glycosylated therapeutic Fc-fusion protein that contains multiple N- and O-glycosylation sites. An in-depth characterization of the glycosylation of etanercept was carried out using liquid chromatography/mass spectrometry (LC/MS) methods in a systematic approach in which we analyzed the N- and O-linked glycans and located the occupied O-glycosylation sites. Etanercept was first treated with peptide N-glycosidase F to release the N-glycans. The N-glycan pool was labeled with a 2-aminobenzamide (2-AB) fluorescence tag and separated using ultraperformance liquid chromatography-hydrophilic interaction liquid chromatography (UPLC-HILIC). Preliminary structures were assigned using Glycobase. These assignments, which included monosaccharide sequence and linkage information, were confirmed by exoglycosidase array digestions of aliquots of the N-glycan pool. The removal of the N-glycans from etanercept facilitated the selective characterization of O-glycopeptides and enabled the O-glycans to be identified. These were predominantly of the core 1 subtype (HexHexNAc O-structure) attached to Ser/Thr residues. α2→3,6,8,9 sialidase was used to remove the sialic acid residues on the O-glycans allowing the use of an automated LC/MS(E) protocol to identify the O-glycopeptides. Electron-transfer dissociation (ETD) was then used to pinpoint the 12 occupied O-glycosylation sites. The determination of N- and O-glycans and O-glycosylation sites in etanercept provides a basis for future studies addressing the biological importance of specific protein glycosylations in the production of safe and efficacious biotherapeutics.

An automated robotic platform for rapid profiling oligosaccharide analysis of monoclonal antibodies directly from cell culture.

Oligosaccharides attached to Asn297 in each of the CH2 domains of monoclonal antibodies play an important role in antibody effector functions by modulating the affinity of interaction with Fc receptors displayed on cells of the innate immune system. Rapid, detailed, and quantitative N-glycan analysis is required at all stages of bioprocess development to ensure the safety and efficacy of the therapeutic. The high sample numbers generated during quality by design (QbD) and process analytical technology (PAT) create a demand for high-performance, high-throughput analytical technologies for comprehensive oligosaccharide analysis. We have developed an automated 96-well plate-based sample preparation platform for high-throughput N-glycan analysis using a liquid handling robotic system. Complete process automation includes monoclonal antibody (mAb) purification directly from bioreactor media, glycan release, fluorescent labeling, purification, and subsequent ultra-performance liquid chromatography (UPLC) analysis. The entire sample preparation and commencement of analysis is achieved within a 5-h timeframe. The automated sample preparation platform can easily be interfaced with other downstream analytical technologies, including mass spectrometry (MS) and capillary electrophoresis (CE), for rapid characterization of oligosaccharides present on therapeutic antibodies.

The impact of microcarrier culture optimization on the glycosylation profile of a monoclonal antibody.

Microcarriers are widely used for the large-scale culture of attachment-dependent cells with increased cell densities and, ultimately, higher product yield. In these processes, the specific culture conditions can affect the quality of the product, which is closely related to its glycosylation pattern. Furthermore, the lack of studies in the area reinforces the need to better understand the effects of microcarrier culture in product glycosylation. Consequently, in this work, the glycosylation profile of a monoclonal antibody (mAb) produced by adherent CHO-K1 cells grown in Cytodex 3 was evaluated under different conditions, and compared to that obtained of typical adherent cultures. It was found that microcarrier cultures result in a glycosylation profile with different characteristics from T-flask cultures, with a general increase in galactosylation and decrease in fucosylation levels, both with a potentially positive impact on mAb activity. Sialylation also varied but without a general tendency. This study then showed that the specific culture conditions used in microcarrier culture influence the mAb glycan profile, and each functional element (galactose, core fucose, sialic acid) is independently affected by these conditions. In particular, great reductions of fucosylation (from 79 to 55%) were obtained when using half volume at inoculation, and notable decreases in sialylation (from 23 to 2%) and glycoform heterogeneity (from 20 to 11 glycoforms) were observed for shake flask culture, potentially associated with the improved cell densities achieved in these culture vessels.

The impact of cell adaptation to serum-free conditions on the glycosylation profile of a monoclonal antibody produced by Chinese hamster ovary cells.

N-glycosylation is one of the most crucial parameters affecting the biological activity of therapeutic monoclonal antibodies (mAbs), and should therefore be closely monitored and controlled to guarantee a consistent and high-quality product in biopharmaceutical processes. In the present work, the effect of the time-consuming step of gradual cell adaptation to serum-free conditions on the glycosylation profile of a mAb produced by CHO-K1 cells was evaluated. High-performance liquid chromatography analysis revealed important changes in mAb glycosylation patterns in all steps of serum reduction. These changes could be grouped in two distinct phases of the process of adaptation: middle (2.5 to 0.15% serum) and final (0.075 and 0% serum). For intermediate levels of serum, a desirable increase of galactosylation and decrease of fucosylation, but an undesirable increase in sialylation were observed; while the inverse was obtained at the final stages of adaptation. These divergences may be related to the reduction of serum supplementation, to variations in the levels of cell density and viability achieved at these stages, and to the natural shift of the cell growth mode during adaptation from adherent to suspended. The divergent glycan profiles obtained in this study demonstrate a strong influence of the adaptation process on mAb glycosylation, suggesting that control and monitoring of product quality should be implemented at the early stages of process development.

Identification of N-glycans displaying mannose-6-phosphate and their site of attachment on therapeutic enzymes for lysosomal storage disorder treatment.

Characterization of mono- and bis-mannose-6-phosphate (M6P) bearing oligosaccharides present on acid hydrolase enzymes poses a considerable analytical challenge. In the current paper, we investigated the use of UPLC profiling on a 1.7 µm HILIC phase and capillary electrophoresis with laser induced fluorescence detection (CE-LIF) combined with exoglycosidase digestion and weak anion exchange fractionation for the characterization of M6P bearing glycans on recombinant ß-glucuronidase expressed in Chinese Hamster Ovary (CHO) cells. Using this multidimensional approach a number of peaks were observed to resist digestion, suggesting the presence and blocking activity of the M6P tag. To investigate further, mixed oxide affinity purification on a combined TiO(2)/ZrO(2) resin facilitated the selective enrichment of oligosaccharides bearing mono- or diphospho-esters that corresponded to those peaks previously identified to resist exoglycosidase digestion. Alkaline phosphatase digestion identified Man(6)GlcNAc(2) and Man(7)GlcNAc(2) glycans as the primary carriers of the M6P tag. Site-specific glycoproteomic analysis revealed that Man(7)GlcNAc(2)-M6P oligosaccharides were present at asparagine 272 and 420, while asparagine 631 displayed Man(6)GlcNAc(2)-M6P. The analytical strategy applied herein represents a novel yet simple approach for the qualitative and semiquantitative structural characterization of M6P containing oligosaccharides on therapeutic enzymes.

2D-LC analysis of BRP 3 erythropoietin N-glycosylation using anion exchange fractionation and hydrophilic interaction UPLC reveals long poly-N-acetyl lactosamine extensions.

Post-translational modifications, in particular glycosylation, represent critical structural attributes that govern both the pharmacodynamic and pharmacokinetic properties of therapeutic glycoproteins. To guarantee safety and efficacy of recombinant therapeutics, characterization of glycosylation present is a regulatory requirement. In the current paper, we applied a multidimensional strategy comprising a shallow anion exchange gradient in the first dimension, followed by analysis using the recently introduced 1.7 µm HILIC phase in the second dimension for the comprehensive separation of complex N-glycans present on the European Biological Reference Preparation (BRP) 3 erythropoietin standard. Tetra-antennary glycans with multiple sialic acids and poly-N-acetyl lactosamine extensions were the most abundant oligosaccharides present on the molecule. Site-specific glycan analysis was performed to examine microheterogeneity. Tetra-antennary glycans with up to four sialic acids and up to five poly-N-acetyl lactosamine extensions were observed at asparagine 24 and 83, while biantennary glycans were the major structures at asparagine 38. The combined AEC x UPLC HILIC allows for the rapid and comprehensive analysis of complex N-glycosylation present on therapeutic glycoproteins, such as BRP3 erythropoietin.