On the electromigration of charged fluorophore-labeled oligosaccharides in polyethylene oxide solutions.

The separation mechanism of charged fluorophore (aminopyrenetrisulfonate)-labeled maltooligosaccharides with α1-4 linkages was studied in polyethylene oxide (PEO) solutions (MW 300 000 Da) with special interest to possible analyte and/or network deformations as well as potential solute-matrix interactions. The electrophoretic mobilities of the 8-aminopyrene-1,3,6-trisulfonate-labeled maltooligosaccharides were found proportional with their MW(-2/3) . The Arrhenius function was used to determine the activation energy needed by the labeled sugars to migrate through the separation media. With increasing solute size, the activation energy (Ea ) values decreased in polymer concentrations above the entanglement threshold of the PEO, while showed apparently independent function at the entanglement threshold. The observed phenomenon was considered as a result of solute-matrix interaction, which could be alleviated by the addition of an organic modifier to the BGE.

Activation energy associated with the electromigration of oligosaccharides through viscosity modifier and polymeric additive containing background electrolytes.

The activation energy related to the electromigration of oligosaccharides can be determined from their measured electrophoretic mobilities at different temperatures. The effects of a viscosity modifier (ethylene glycol) and a polymeric additive (linear polyacrylamide) on the electrophoretic mobility of linear sugar oligomers with α1-4 linked glucose units (maltooligosaccharides) were studied in CE using the activation energy concept. The electrophoretic separations of 8-aminopyrene-1,3,6-trisulfonate-labeled maltooligosaccharides were monitored by LIF detection in the temperature range of 20-50°C, using either 0-60% ethylene glycol (viscosity modifier) or 0-3% linear polyacrylamide (polymeric additive) containing BGEs. Activation energy curves were constructed based on the slopes of the Arrhenius plots. With the use of linear polyacrylamide additive, solute size-dependent activation energy variations were found for the maltooligosaccharides with polymerization degrees below and above maltoheptaose (DP 7), probably due to molecular conformation changes and possible matrix interaction effects.

Effect of Separation Temperature on Structure Specific Glycan Migration in Capillary Electrophoresis.

Temperature dependent differential migration shifts were studied in capillary electrophoresis between linear (maltooligosaccharides) and branched (sialylated, neutral and core fucosylated biantennary IgG glycans) carbohydrates. Background electrolytes without as well as with low and high molecular weight additives (ethylene glycol, linear polyacrylamide and poly(ethylene oxide)) were investigated for this phenomena in the temperature range of 20-50 °C. Glucose unit (GU) value shifts were observed with increasing temperature for the all IgG glycans both in additive-free and additive-containing background electrolytes, emphasizing the importance of tight temperature control during glycosylation analysis by capillary electrophoresis. The activation energy concept was applied to understand the structure specific electrophoretic migration of the different sugar molecules. Activation energy values were derived from the slopes of the Arrhenius plots of logarithmic mobility vs reciprocal absolute temperature and compared for the linear and branched sugars as well as for the various background electrolyte additives.

Toward the generation of an aminonaphthalene trisulfonate labeled N-glycan database for capillary gel electrophoresis analysis of carbohydrates.

There is an increasing trend to develop therapeutic glycoproteins, mostly antibodies that require high resolution bioanalytical tools to address the challenging aspects of comprehensive carbohydrate characterization. In this paper we introduce an initial version of a glucose unit database for 8-aminonaphthalene-1,3,6-trisulfonic acid-labeled glycans. At this stage we mainly focused on therapeutic IgG derived glycans of core fucosylated biantennary structures with and without sialic acid residues, as well as high mannose structures. Currently 25 oligosaccharides represent this first set of the database that shows the abbreviated names of the individual sugar structures with their graphic representation, precise molecular mass and glucose unit (GU) values with corresponding SDs. The database will provide a quick glycan analysis tool for preliminary data interpretation of rapid (around 200 s) CGE-LED-induced fluorescence (CGE-LEDIF) based glycan profiling runs.

Rapid identification of human SNAP-25 transcript variants by a miniaturized capillary electrophoresis system.

The 25 kDa synaptosomal-associated protein (SNAP-25) is a crucial component of the soluble N-ethylmaleimide-sensitive factor attachment protein receptor complex and plays an important role in neurotransmission in the central nervous system. SNAP-25 has two different splice variants, SNAP-25a and SNAP-25b, differing in nine amino acids that results in a slight functional alteration of the generated soluble N-ethylmaleimide-sensitive factor attachment protein receptor complex. Two independent techniques, a PCR-miniaturized CE method and a real-time PCR based approach were elaborated for the specific and quantitative detection of the two SNAP-25 transcription variants. DNA-constructs coding for the two isoforms were used for optimization. Excellent specificity was observed with the use of our previously described highly sensitive miniaturized CE system in combination with quantitative PCR. The ratio of the two isoforms were reliably detected in a range of at least four orders of magnitude with a linear regression of R(2) = 0.987. Expression of the two isoforms was determined in human samples, where SNAP-25 was detected even in non-neural tissues, although at approximately a 100-fold lower level compared to the central nervous system. The relative amount of the SNAP-25b isoform was higher in the brain, whereas expression of SNAP-25a variant proved to be slightly higher in extra-neural cell types. The genomics approach in conjunction with the miniaturized CE system introduced in this paper is readily applicable for rapid alternative splice variant analysis.

Multicapillary SDS-gel electrophoresis for the analysis of fluorescently labeled mAb preparations: a high throughput quality control process for the production of QuantiPlasma and PlasmaScan mAb libraries.

Molecular heterogeneity of mAb preparations is the result of various co- and post-translational modifications and to contaminants related to the production process. Changes in molecular composition results in alterations of functional performance, therefore quality control and validation of therapeutic or diagnostic protein products is essential. A special case is the consistent production of mAb libraries (QuantiPlasma™ and PlasmaScan™) for proteome profiling, quality control of which represents a challenge because of high number of mAbs (>1000). Here, we devise a generally applicable multicapillary SDS-gel electrophoresis process for the analysis of fluorescently labeled mAb preparations for the high throughput quality control of mAbs of the QuantiPlasma™ and PlasmaScan™ libraries.

Neoglycoproteins as carbohydrate antigens: synthesis, analysis, and polyclonal antibody response.

The analysis and polyclonal antibody response for newly synthesized maltose-BSA conjugate neoglycoproteins is described. In this first proof of concept study, a simple carbohydrate antigen, maltose, was linked to BSA by reductive amination. An aglycone spacer was utilized to conserve the intact annular maltose structure and to promote the accessibility of the carbohydrate immunogen hapten during immunization. The neoglycoproteins were investigated by CGE and the number of conjugated maltose residues was determined by MALDI-TOF MS. The neoglycoproteins were then evaluated by immunization of BALB/c mice and the polyclonal antibody response was tested by ELISA as evidence for the presence of sugar-containing epitope-specific antibodies. Selective antibody binding was demonstrated to the synthesized neoglycoproteins with different (low and high) glycosylation degrees suggesting the possible use of this approach to generate antibodies. Moreover, the polyclonal antibody response was not inhibited by maltose or other simple carbohydrates to confirm presence of the neoglycoprotein-specific antibodies.

Light-emitting diode induced fluorescence (LED-IF) detection design for a pen-shaped cartridge based single capillary electrophoresis system.

CGE is a well-established separation technique for the analysis of biologically important molecules such as nucleic acids. The inherent high resolving power, rapid analysis times, excellent detection sensitivity, and quantification capabilities makes this method favorable compared to conventional manual polyacrylamide and agarose slab gel electrophoresis techniques. In this paper we introduce a novel single-channel capillary gel electrophoresis system with LED-induced fluorescence detection also utilizing a compact pen-shaped capillary cartridge design for automatic analysis of samples from a 96-well plate. To evaluate the suitability of the system, 1000 genomic DNA(gDNA) samples were analyzed in gel filled capillaries and detected by the microball ended excitation and emission optical fiber based LED-induced fluorescence detection system. Excellent migration time reproducibility of RSD <0.75% was obtained over the course of 1000 runs. The system rapidly distinguished between intact and degraded gDNA samples, therefore provided important information if they could be used for downstream quantitative PCR processing where high-quality intact gDNA was key. We envision that this novel system design will rapidly find new applications in both research and clinical diagnostic laboratories as a highly sensitive and easy to use bio-analytical approach.

High-throughput analysis of therapeutic and diagnostic monoclonal antibodies by multicapillary SDS gel electrophoresis in conjunction with covalent fluorescent labeling.

Capillary gel electrophoresis (CGE) in the presence of sodium dodecyl sulfate (SDS) is a well-established and widely used protein analysis technique in the biotechnology industry, and increasingly becoming the method of choice that meets the requirements of the standards of International Conference of Harmonization (ICH). Automated single channel capillary electrophoresis systems are usually equipped with UV absorbance and/or laser-induced fluorescent (LIF) detection options offering general applicability and high detection sensitivity, respectively; however, with limited throughput. This shortcoming is addressed by the use of multicapillary gel electrophoresis (mCGE) systems with LED-induced fluorescent detection (LED-IF), also featuring automation and excellent detection sensitivity, thus widely applicable to rapid and large-scale analysis of biotherapeutics, especially monoclonal antibodies (mAb). The methodology we report in this paper is readily applicable for rapid purity assessment and subunit characterization of IgG molecules including detection of non-glycosylated heavy chains (NGHC) and separation of possible subunit variations such as truncated light chains (Pre-LC) or alternative splice variants. Covalent fluorophore derivatization and the mCGE analysis of the labeled IgG samples with multi-capillary gel electrophoresis are thoroughly described. Reducing and non-reducing conditions were both applied with and without peptide N-glycosidase F mediated deglycosylation.

Ultrafast haplotyping of putative microRNA-binding sites in the WFS1 gene by multiplex polymerase chain reaction and capillary gel electrophoresis.

The transmembrane protein wolframin (WSF1) plays a crucial role in cell integrity in pancreatic beta cells and maintaining ER homeostasis. Genetic variations in the WFS1 gene have been described to be associated with Wolfram syndrome or type 2 diabetes mellitus. In this paper we report on an efficient double-tube allele-specific amplification method in conjunction with ultrafast capillary gel electrophoresis for direct haplotyping analysis of the SNPs in two important miRNA-binding sites (rs1046322 and rs9457) in the WFS1 gene. An automated single-channel capillary gel electrophoresis system was utilized in the method that provided dsDNA fragment analysis in less than 240 s. The light-emitting diode induced fluorescence (LEDIF) detection system enabled excellent sensitivity for automated haplotyping of a large number of clinical samples. The detection limit was 0.002 ng/µL using field amplified injection from water diluted samples. The dynamic quantitation range was 0.08-10.00 ng/µL (R(2)=0.9997) in buffer diluted samples.