Electromigration Dispersion in Sodium Dodecyl Sulfate Capillary Gel Electrophoresis of Proteins.

The electromigration dispersion of the light- and heavy-chain subunit peaks of the therapeutic monoclonal antibody omalizumab was investigated in sodium dodecyl sulfate capillary gel electrophoresis (SDS-CGE) using borate cross-linked dextran sieving matrices. Increasing boric acid content (340-640 mM) caused electromigration dispersion shifts for both low (2%)- and high (10%)-dextran-concentration gels in all gel-buffer compositions. In case of the heavy-chain fragment, elevated borate concentrations resulted in decreasing tailing and increasing fronting with the use of higher- and lower-dextran-concentration gels, respectively. The light-chain fragment, on the other hand, exhibited increased fronting with increasing borate concentration for both dextran concentrations examined in this study. Increase of the glycerol ingredient level in the gel-buffer system caused the same effect as the increasing borate concentration in both dextran concentrations. The detected electromigration dispersion was considered as the result of the formation of monomeric and dimeric glycerol-borate complexes as co-ionic constituents, migrating slower than that of the unconjugated tetrahydroxyborate. In addition, complexation of the tetrahydroxyborate anion with the glucose building blocks of the dextran polymer decreased its mobility to practically zero, contributing to further decrease in the resultant effective mobility of the co-ionic species. We suggest that the observed fronting and/or tailing peak shapes of the monoclonal antibody fragments in SDS-CGE at increasing boric acid concentrations can be considered as the result of multiple effects including changes in pH, sieving matrix pore size, viscosity, and the mobility variation of the co-ionic borate adducts with the gel-buffer ingredients. While electromigration dispersion-mediated band broadening, in general, can be minimized via matching the effective mobility of the co-ionic species to the analyte molecules of interest, in case of borate cross-linked dextran gels, optimization of the boric acid concentration required special consideration of its gel cross-linking function. For the light- and heavy-chain fragments of the IgG analyte, best peak shapes were attained with the use of 10% dextran/340 mM boric acid and 10% dextran/640 mM boric acid-containing gel-buffer systems, respectively. Based on this observation, here we introduce the concept of borate-gradient-mediated transient mobility matching in SDS-CGE of proteins. This novel approach resulted in close to optimal peak shapes for the distantly migrating IgG subunits within a single run, as well as unraveled the long-sought possible solution to perform capillary pore-size-gradient gel electrophoresis.

Effect of the Monomer Cross-Linker Ratio on the Separation Selectivity of Monoclonal Antibody Subunits in Sodium Dodecyl Sulfate Capillary Gel Electrophoresis.

With the increasing interest in the biopharmaceutical industry toward novel and innovative protein therapeutics, improved separation techniques are important, especially for the analysis of highly glycosylated candidates. Sodium dodecyl sulfate capillary gel electrophoresis (SDS-CGE) using borate cross-linked dextran is one of the most frequently used methods to analyze biotherapeutic proteins in process control as well as in release and stability testing. In this work, the effect of the monomer (dextran) and cross-linker (borate) ratio was studied in SDS-CGE analysis of a therapeutic monoclonal antibody test item in its reduced and intact forms. A retention model was developed for better understanding of the separation selectivity between the non-glycosylated and glycosylated heavy chain fragments, exploiting the interaction between the dextran-borate adducts and the glycan moiety of the therapeutic antibody. The monomer cross-linker ratio played a significant role in the overall analysis times and affected the separation selectivity between the non-glycosylated and regular (glycosylated) heavy chain fragments; however, it had no effect on the separation of the regular and non-glycosylated intact forms of the monoclonal antibody. Introduction of three-dimensional selectivity plots offered an easy separation optimization option for the separation problem in hand.

Fundamentals of Capillary Electrophoretic Migration and Separation of SDS Proteins in Borate Cross-Linked Dextran Gels.

Recent progress in the development and production of new, innovative protein therapeutics require rapid and adjustable high-resolution bioseparation techniques. Sodium dodecyl sulfate capillary gel electrophoresis (SDS-CGE) using a borate (B) cross-linked dextran (D) separation matrix is widely employed today for rapid consistency analysis of therapeutic proteins in manufacturing and release testing. Transient borate cross-linking of the semirigid dextran polymer chains leads to a high-resolution separation gel for SDS-protein complexes. To understand the migration and separation basis of the D/B gel, the present work explores various gel formulations of dextran monomer (2, 5, 7.5, and 10%) and borate cross-linker (2 and 4%) concentrations. Ferguson plots were analyzed for a mixture of protein standards with molecular weights ranging from 20 to 225 kDa, and the resulting nonlinear concave curves pointed to nonclassical sieving behavior. While the 2% D/4% B gel resulted in the fastest analysis time, the 10% D/2% B gel was found to produce the greatest separation window, even higher than with the 10% D/4% B gel, due to a significant increase in the electroosmotic flow of the former composition in the direction opposite to SDS-protein complex migration. The study then focused on SDS-CGE separation of a therapeutic monoclonal antibody and its subunits. A combination of molecular weight and shape selectivity as well as, to a lesser extent, surface charge density differences (due to glycosylation on the heavy chain) influenced migration. Greater molecular weight selectivity occurred for the higher monomer concentration gels, while improved glycoselectivity was obtained using a more dilute gel, even as low as 2% D/2% B. This latter gel took advantage of the dextran-borate-glycoprotein complexation. The study revealed that by modulating the dextran (monomer) and borate (cross-linker) concentration ratios of the sieving matrix, one can optimize the separation for specific biopharmaceutical modalities with excellent column-to-column, run-to-run, and gel-to-gel migration time reproducibilities (<0.96% relative standard deviation (RSD)). The widely used 10% dextran/4% borate gel represents a good screening option, which can then be followed by a modified composition, optimized for a specific separation as necessary.

Opposing Effects of Chelidonine on Tyrosine and Serine Phosphorylation of STAT3 in Human Uveal Melanoma Cells.

STAT3 is a transcription factor that regulates various cellular processes with oncogenic potential, thereby promoting tumorigenesis when activated uncontrolled. STAT3 activation is mediated by its tyrosine phosphorylation, triggering dimerization and nuclear translocation. STAT3 also contains a serine phosphorylation site, with a postulated regulatory role in STAT3 activation and G2/M transition. Interleukin-6, a major activator of STAT3, is present in elevated concentrations in uveal melanomas, suggesting contribution of dysregulated STAT3 activation to their pathogenesis. Here, we studied the impact of chelidonine on STAT3 signaling in human uveal melanoma cells. Chelidonine, an alkaloid isolated from Chelidonium majus, disrupts microtubules, causes mitotic arrest and provokes cell death in numerous tumor cells. According to our flow cytometry and confocal microscopy data, chelidonine abrogated IL-6-induced activation and nuclear translocation, but amplified constitutive serine phosphorylation of STAT3. Both effects were restricted to a fraction of cells only, in an all-or-none fashion. A partial overlap could be observed between the affected subpopulations; however, no direct connection could be proven. This study is the first proof on a cell-by-cell basis for the opposing effects of a microtubule-targeting agent on the two types of STAT3 phosphorylation.

The Effect of Temperature in Sodium Dodecyl Sulfate Capillary Gel Electrophoresis of Protein Therapeutics.

The temperature-dependent migration of molecular weight protein size standards and several biotherapeutic proteins were studied in sodium dodecyl sulfate capillary gel electrophoresis (SDS-CGE) in the interval from 15 to 60 °C using borate cross-linked dextran sieving matrix. Arrhenius plots were generated to calculate the respective activation energy values for the various solute molecules. SDS-CGE analysis of the biotherapeutic protein test mixture revealed no correlation between the activation energy requirement of the different species and their molecular weights, emphasizing the importance of separation temperature optimization to obtain high resolution between the solute molecules of interest. In contrast, the molecular weight protein size ladder ranging from 10 to 225 kDa, built from the same polypeptide blocks with no post-translational and other modifications, showed predictable activation energy requirement. The electrophoretic mobility of the SDS-protein complexes was found to be the function of the reciprocal sixth root of the molecular weight (Mw-1/6), implying cylindrical conformation.

N-glycosylation structure - function characterization of omalizumab, an anti-asthma biotherapeutic product.

Omalizumab, a glycoprotein based biotherapeutics, is one of the most frequently used targeted antibody biopharmaceutical to reduce asthma exacerbations, improve lung function and reduce oral corticosteroid use. The effector function and clearance time of such glycoprotein drugs is affected by their N-glycosylation, that defines the required administration frequency to improve the quality of life in appropriately selected patients. Therefore, the glycosylation of biologics is an important critical quality attribute (CQA). The profile of asparagine linked carbohydrates is greatly dependent on the manufacturing process. Even a small deviation may have a major effect on the structure and therefore the function of the biotherapeutic product. For this reason, comprehensive N-glycosylation analysis is of high importance during production and release. Capillary electrophoresis (CE) is one of the frequently used tools to characterize protein therapeutics and utilized by the biopharmaceutical industry for protein and glycan level analysis, which are key parts both for drug development and quality control. To reveal important structure - function relationships, characterization of omalizumab is presented using capillary SDS gel electrophoresis with UV detection at the protein level and capillary gel electrophoresis with laser induced fluorescent detection at the N-linked carbohydrate level. This latter technique was also used for oligosaccharide sequencing for glycan structure validation. The results suggested no ADCC function - structure relationship due to the mostly core fucosylated biantennary glycans found. However, the presence of the high mannose structures probably affects the clearance rate of the drug.

Capillary sodium dodecyl sulfate gel electrophoresis of proteins: Introducing the three dimensional Ferguson method.

One of the most extensively utilized rapid characterization, release and stability testing methods of therapeutic proteins in the biopharmaceutical field today is capillary SDS gel electrophoresis using borate cross-linked high molecular weight dextran. In spite of its widespread use, however, the gel composition dependent separation characteristics of this very unique sieving matrix has not been investigated yet. Introduction of three dimensional (3D) Ferguson plots, based on simultaneous variation of the dextran (D) and borate (B) concentrations generating 16 different D/B ratio gels, allowed better understanding of the electromigration process of the SDS-protein complexes. As a result of this comprehensive study, non-linear 3D logarithmic mobility vs dextran and borate concentration surfaces were obtained. Both, the molecular weight protein standards and the new modality fusion protein etanercept resulted in concave 3D Ferguson plots. The interplay between the electroosmotic flow and the viscosity of the matrices played a key role in the resulting migration time and resolution. Selectivity values were defined and evaluated in 3D graph formats for the regular and de-N-glycosylated subunits of etanercept, as well as for the latter with the 10 kDa internal standard to understand both the dextran-borate complexation and sized based selectivities. KR plots of the retardation coefficients as the function of the logarithmic molecular weights were used to more precisely assess the Mw of the samples and to obtain information about the molecular characteristics of the electromigrating SDS-protein complexes.

Multilevel capillary gel electrophoresis characterization of new antibody modalities.

Capillary gel electrophoresis-based methods were applied to comprehensively characterize two development phase new modality monoclonal antibodies including a glycoengineered and a bispecific test compound. The samples were subjected to multilevel characterization at the intact (both by SDS-SGE and cIEF) as well as the reduced protein and the released N-glycan levels. SDS capillary gel electrophoresis analysis showed excellent separation of the light and heavy chains of both samples. The bispecific antibody required a special temperature gradient denaturation process and a longer capillary to resolve its two light chain fragments. Separation of PNGase F digested antibodies revealed migration time shifts, suggesting the presence of N-linked glycosylation on the corresponding subunits. For efficient glycan removal, the highly glycosylated glycoengineered monoclonal antibody was trypsin digested prior to the endoglycosidase treatment. The released glycans were profiled by capillary gel electrophoresis after APTS labeling and their oligosaccharide structures were identified by exoglycosidase based carbohydrate sequencing. Finally, capillary isoelectric focusing shed light on the charge heterogeneity of the test compounds, providing important complementary information. A flowchart was established for workflow optimization.

N-glycosylation analysis of biopharmaceuticals by multicapillary gel electrophoresis: Generation and application of a new glucose unit database.

As glycomics research is gaining momentum in the biopharmaceutical industry, there is an increasing need for reproducible high throughput glycoanalytical methods to monitor and characterize the N-glycosylation of therapeutic glycoproteins. Since the glycosylation pattern of glycobiotherapeutics influences their important biological functions, approaches to comprehensively analyze these complex molecules is of high importance. This paper reports on the use of multicapillary gel electrophoresis in high throughput analysis of fluorophore labeled partitioned N-glycan libraries to generate a new glucose unit database that was consequently applied to identify the carbohydrate structures of two high profile biopharmaceuticals, adalimumab and etanercept.