Nucleotide and nucleotide sugar analysis in cell extracts by capillary electrophoresis

In biotechnological processes the intracellular level of nucleotides and nucleotide sugars have a direct impact on the post-translational modification (glycosylation) of the therapeutic protein products and on the exopolysaccharide pattern of the cells. Thus, they are precursors and also key components in the production of glycoproteins and glycolipids. All four nucleotides (at different phosphorylation stages) and their natural sugar derivatives coexist in biological samples. Their relative ratios depend on the actual conditions under which the cells are grown. Therefore, their simultaneous determination at different time points and different cell culture conditions in biotechnological samples is of interest in order to develop the optimal cell culture process. In our study capillary electrophoresis (CE) combined with UV detection @ 260 nm was selected for the separation and quantification of the complex nucleotide mixture of the structurally very similar nucleotides and nucleotide sugars in cell extracts. The high separation efficiency of CE as well as its insensitivity to the complex cell matrix makes this method superior to commonly used HPLC methods. In our study eleven nucleotides and six nucleotide sugars were analyzed. A robust and reproducible analysis system was developed. As background electrolyte borate (40 mM, pH 9.5) was used containing 1% PEG (MW 35'000 Da) which enhanced resolution. In order to obtain high reproducibility in terms of migration time, mandatory for the unambiguous identification of the single compounds in the complex cell extract mixtures, dynamic coating was also employed. The method was tested for CHO cell extracts where three sugar nucleotides and seven nucleotides were identified and quantified using GDP-Glc as internal standard

Nucleotide and Nucleotide Sugar Analysis in Cell Extracts by Capillary Electrophoresis: FH-HES Universities of Applied Sciences

In biotechnological processes the intracellular level of nucleotides and nucleotide sugars have a direct impact on the post-translational modification (glycosylation) of the therapeutic protein products and on the exopolysaccharide pattern of the cells. Thus, they are precursors and also key components in the production of glycoproteins and glycolipids. All four nucleotides (at different phosphorylation stages) and their natural sugar derivatives coexist in biological samples. Their relative ratios depend on the actual conditions under which the cells are grown. Therefore, their simultaneous determination at different time points and different cell culture conditions in biotechnological samples is of interest in order to develop the optimal cell culture process. In our study capillary electrophoresis (CE) combined with UV detection @ 260 nm was selected for the separation and quantification of the complex nucleotide mixture of the structurally very similar nucleotides and nucleotide sugars in cell extracts. The high separation efficiency of CE as well as its insensitivity to the complex cell matrix makes this method superior to commonly used HPLC methods. In our study eleven nucleotides and six nucleotide sugars were analyzed. A robust and reproducible analysis system was developed. As background electrolyte borate (40 mM, pH 9.5) was used containing 1% PEG (MW 35'000 Da) which enhanced resolution. In order to obtain high reproducibility in terms of migration time, mandatory for the unambiguous identification of the single compounds in the complex cell extract mixtures, dynamic coating was also employed. The method was tested for CHO cell extracts where three sugar nucleotides and seven nucleotides were identified and quantified using GDP-Glc as internal standard

Rheological and stability aspects of dry and hydrothermally heat treated aleurone-rich wheat milling fraction

Novel aleurone-rich wheat milling fraction developed and produced on industry scale is investigated. The special composition of the novel flour with high protein, dietary fiber and fat content results in a unique combination of the mixing and viscosity properties. Due to the high lipid concentration, the fraction is exposed to fast rancidity. Dry heat (100 °C for 12 min) and hydrothermal treatment processes (96 °C for 6 min with 0–20 L/h steam) were applied on the aleurone-rich flour to modify the technological properties. The chemical, structural changes; the extractability of protein, carbohydrate and phenolic components and the rheological characteristics of the flours were evaluated. The dry treated flour decreased protein and carbohydrate extractability, shortened dough development time, reduced gel strength and enhanced the gelling ability. Hydrothermal treatment caused changes in the phenolic content improved the dough stability and -resistance. Heat treatment processes were able to extend the stability of the flour

Novel RP-HPLC based assay for selective and sensitive endotoxin quantification

The paper presents a novel instrumental analytical endotoxin quantification assay. It uses common analytical laboratory equipment (HPLC-FLD) and allows quantifying endotoxins (ETs) in different matrices from about 109 EU / mL down to about 40 EU / mL (RSE based). Test results are obtained in concentration units (e.g. ng ET / mL), which can then be converted to commonly used endotoxin units (EU / mL) in case of known pyrogenic activity. During endotoxin hydrolysis, the endotoxin specific rare sugar acid KDO is obtained quantitatively. After that, KDO is stoichiometrically reacted with DMB, which results in a highly fluorescent derivative. The mixture is separated using RP-HPLC followed by KDO-DMB quantification with a fluorescence detector. Based on the KDO content, the endotoxin content in the sample is calculated. The developed assay is economic and has a small error. Its applicability was demonstrated in applied research. ETs were quantified in purified bacterial biopolymers, which were produced by Gram-negative bacteria. Results were compared to LAL results obtained for the same samples. A high correlation was found between the results of both methods. Further, the new assay was utilized with high success during the development of novel endotoxin specific depth filters, which allow efficient, economic and sustainable ET removal during DSP. Those examples demonstrate that the new assay has the potential to complement the animal-based biological LAL pyrogenic quantification tests, which are accepted today by the major health authorities worldwide for the release of commercial pharmaceutical products