Microchip capillary gel electrophoresis combined with lectin affinity enrichment employing magnetic beads for glycoprotein analysis.

Due to the constant search for reliable methods to investigate glycoproteins in complex biological samples, an alternative approach combining affinity enrichment with rapid and sensitive analysis on-a-chip is presented. Glycoproteins were specifically captured by lectin-coated magnetic beads, eluted by competitive sugars, and investigated with microchip capillary gel electrophoresis (MCGE), i.e., CGE-on-a-chip. We compared our results to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) data, which turned out to be in very good agreement. While SDS-PAGE offers the possibility of subsequent mass spectrometric analysis of captured and separated analytes, MCGE scores with time savings, higher throughput, and lower sample consumption as well as quality control (QC) and process analytical technology (PAT) applicability. Due to these advantages, a lectin-based glycoprotein capture protocol can easily be optimized. In our case, two different types of magnetic beads were tested and compared regarding lectin binding. The selectivity of our strategy was demonstrated with a set of model glycoproteins, as well as with human serum and serum depleted from high-abundance proteins. The specificity of the capturing method was investigated revealing to a certain degree an unspecific binding between each sample and the beads themselves, which has to be considered for any specific enrichment and data interpretation. In addition, two glycoproteins from Trichoderma atroviride, a fungus with mycoparasitic activity and only barely studied glycoproteome, were enriched by means of a lectin and so identified for the first time. Graphical abstract Glycoproteins from biological samples were detected by microchip capillary gel electrophoresis after lectin affinity enrichment using magnetic beads and elution with respective competitive monosaccharides.

Challenges of glycoprotein analysis by microchip capillary gel electrophoresis.

Glycosylations severely influence a protein's biological and physicochemical properties. Five exemplary proteins with varying glycan moieties were chosen to establish molecular weight (MW) determination (sizing), quantitation, and sensitivity of detection for microchip capillary gel electrophoresis (MCGE). Although sizing showed increasing deviations from literature values (SDS-PAGE or MALDI-MS) with a concomitant higher degree of analyte glycosylation, the reproducibility of MW determination and accuracy of quantitation with high sensitivity and reliability were demonstrated. Additionally, speed of analysis together with the low level of analyte consumption render MCGE attractive as an alternative to conventional SDS-PAGE.

Sensitive detection of C-reactive protein in serum by immunoprecipitation-microchip capillary gel electrophoresis.

Sepsis represents a significant cause of mortality in intensive care units. Early diagnosis of sepsis is essential to increase the survival rate of patients. Among others, C-reactive protein (CRP) is commonly used as a sepsis marker. In this work we introduce immune precipitation combined with microchip capillary gel electrophoresis (IP-MCGE) for the detection and quantification of CRP in serum samples. First high-abundance proteins (HSA, IgG) are removed from serum samples using affinity spin cartridges, and then the remaining proteins are labeled with a fluorescence dye and incubated with an anti-CRP antibody, and the antigen/antibody complex is precipitated with protein G-coated magnetic beads. After precipitation the complex is eluted from the beads and loaded onto the MCGE system. CRP could be reliably detected and quantified, with a detection limit of 25 ng/µl in serum samples and 126 pg/µl in matrix-free samples. The overall sensitivity (LOQ = 75 ng/µl, R(2) = 0.9668) of the method is lower than that of some specially developed methods (e.g., immune radiometric assay) but is comparable to those of clinically accepted ELISA methods. The straightforward sample preparation (not prone to mistakes), reduced sample and reagent volumes (including the antibodies), and high throughput (10 samples/3 h) are advantages and therefore IP-MCGE bears potential for point-of-care diagnosis.

A fluorescent derivatization method of proteins for the detection of low-level impurities by microchip capillary gel electrophoresis.

A novel pre-chip fluorescent derivatization method is presented for protein sizing and quantification by microchip CGE. The derivatization reaction employed a water-soluble and stable fluorescent dye and was performed under conditions that favored the formation of homogeneous reaction products. The method delivered in terms of protein sizing similar results as microchip CGE with on-chip staining but showed an extended linear dynamic range for protein quantification encompassing four orders of magnitude. The sensitivity of the method was similar to standard silver-stained planar gels. The characterization of derivatization reaction products by MS and preparative isoelectric focusing indicated that a constant degree of dye molecule tagging was obtained over a broad range of protein/dye ratios. The method allowed detecting and quantifying an impurity spiked into an antibody preparation down to a level of 0.05%. Advantages of this method compared with CGE approaches with pre-column derivatization include a shorter analysis time and an increased robustness and ease of use.

Microchip CGE linked to immunoprecipitation as an alternative to Western blotting.

A novel approach for protein identification is presented, which combines the specificity of an immunoprecipitation approach with the sensitivity of protein detection in microchip CGE. This method involves derivatization of the sample proteins with a fluorescent dye, target protein isolation with specific antibodies and Protein A coated magnetic beads, and automated sizing and quantification of the eluted samples on microchips. The performance of the new technique was demonstrated with glutathion-S-transferase- and polyHistidine-tagged target proteins in an Escherichia coli background. A specific detection of target proteins was possible down to 0.001% or 1 ng target protein in a background of 100 microg E. coli protein. With this approach, proteins ranging from 10 to 220 kDa could be identified with a panel of different target-specific antibodies. The reproducibility of the method was very similar to standard microchip CGE methods. In a direct comparison to Western blotting, a similar sensitivity and specificity of both techniques was observed. However, the new approach compares favorably to Western blotting in terms of time-to-result, usability and labor intensity, antibody consumption and access to quantitative data.

Non-contact positions impose site selectivity on Cre recombinase.

A first step in Cre-mediated site-specific DNA recombination is binding to the two 13 bp repeats of the 34 bp site loxP. Several nucleotides within loxP do not directly contact the bound enzyme, yet mutation at two of these base pairs, at positions 11 and 12 in each repeat, results in a 100 000-fold reduction in recombination. To understand better how Cre selects DNA sequences for recombination, we combined DNA shuffling mutagenesis and a forward selection strategy to obtain Cre mutants that recombine at 100% efficiency a mutant loxK2 site carrying these dinucleotide changes. The role of the several mutations found in these Cre isolates was analyzed both in vivo and biochemically with purified enzymes. A single mutation at E262 accounts for most but not all of the enhanced activity at loxK2. Secondary mutations act in one or more of three ways: enhancement of loxK2 binding, accelerated synthesis of Cre in vivo or faster DNA recombination at the alternative spacer region present in loxK2. Systematic analysis of all 20 natural amino acids at position E262 shows that the naturally occurring glutamate residue at this position provides the optimal balance of efficiency of recombination at loxP and maximal discrimination against loxK2.

Immunoprecipitation combined with microchip capillary gel electrophoresis: Detection and quantification of ß-galactosidase from crude E. coli cell lysate.

A sensitive and selective analytical method for the determination and quantification of endogenous ß-galactosidase in crude E. coli cell lysates by immunoprecipitation combined with automated microchip capillary gel electrophoresis (IP-MCGE) with laser-induced fluorescence (LIF) detection was developed. Total cell lysates were derivatized minimally with a fluorescence dye, incubated with anti-ß-galactosidase antibodies, and the antigen/antibody complex was precipitated with protein G-coated magnetic beads. After capturing the complex, it was eluted from the beads under denaturing conditions and loaded directly onto a multisample microchip for analysis. The effects of antibody selection and the importance of preclearing steps were studied in detail. For quantification, an external calibration through spiking pure ß-galactosidase into E. coli lysate was performed. Recovery rates of immunoprecipitation after spiking experiments and the amount of unknown endogenous ß-galactosidase in E. coli lysates were determined. As proof of principle, E. coli cultures grown on nutrition media with several glucose/lactose ratios were analyzed. Differences in the expression level of ß-galactosidase could be detected and measured with the developed method. Detected amounts of ß-galactosidase in different culture media correlated with the ß-galactosidase activities in these cultures.

Analysis of Cre-loxP interaction by surface plasmon resonance: influence of spermidine on cooperativity.

To study target site selectivity of one important class of DNA-binding proteins, site-specific DNA recombinases, we developed an automated real-time kinetic assay based on surface plasmon resonance (BIACORE) and formulated a curve-fitting model that takes into account cooperative interactions. Monitoring the interaction between the Cre DNA recombinase and its specific target site loxP by BIACORE, we found that Cre associates with loxP tightly and highly cooperatively. We observed that the cooperative moment of the Cre-loxP interaction is strongly dependent on the concentration of spermidine, a small polyamine influencing DNA conformation. Thus, DNA conformation can have a profound impact on substrate recognition and subsequent recombination.