Preparative separation of immunoglobulins from bovine colostrum by continuous divergent-flow electrophoresis.

Immunoglobulins in bovine colostrum were separated and fractionated from other proteins using the method and instrumentation developed in our laboratory. The proposed separation was based on bidirectional isotachophoresis/moving boundary electrophoresis with electrofocusing of the analytes in a pH gradient from 3.9 to 10.1. The preparative instrumentation included the trapezoidal non-woven fabric that served as separation space with divergent continuous flow. The defatted and casein precipitate-free colostrum supernatant was loaded directly into the instrument without any additional colostrum pre-preparation. Immunoglobulin G was fractionated from other immune proteins such as bovine serum albumin, ß-lactoglobulin, and α-lactalbumin, and was continuously collected in separated fractions over 3 h. The fractions were further processed, and isolated immunoglobulin G in the liquid fractions was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by re-focusing in gel isoelectric focusing. Separated immunoglobulin G was detected in seven fractions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a gradually decreased concentration in the fractions. Re-focusing of the proteins in the fractions by gel isoelectric focusing revealed multiple separated zones of immunoglobulin G with the isoelectric point values covering the range from 5.4 to 7.2. Each fraction contained distinct zones with gradually increased isoelectric point values and decreased concentrations from fraction to fraction.

Combination of capillary isoelectric focusing in a tapered capillary with MALDI-TOF MS for rapid and reliable identification of Dickeya species from plant samples.

This study was undertaken to investigate feasibility of a combination of capillary isoelectric focusing (CIEF) in a tapered fused silica (FS) capillary with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) for a rapid and reliable identification of bacteria taken from plant-tissue-containing samples. Eight strains representing different species of the genus Dickeya were selected on the basis of close proximity of their isoelectric points: D. chrysanthemi, D. chrysanthemi bv. parthenii, D. chrysanthemi bv. chrysanthemi, D. dadantii, D. paradisiaca, D. solani, D. diffenbachiae, and D. dianthicola. Because the Dickeya species (spp.) cannot be easily discriminated from each other when CIEF is performed in a cylindrical FS capillary (commonly used in CIEF) even if a narrow pH gradient is used, a tapered FS capillary was employed instead, which enabled satisfactory discrimination of the examined bacteria due to enhanced separation efficiency of CIEF in the tapered FS capillary. CIEF in the tapered FS capillary was also successfully used for the detection and characterization of Dickeya spp. in a plant-tissue-containing sample. Then an off-line combination of CIEF with MALDI-TOF MS was employed for rapid and reliable identification of Dickeya spp. in the plant-tissue-containing sample. It was found that the presence of plant tissue did not affect the results, making the proposed procedure very promising with respect to the fast and reliable detection and identification of bacteria in plant-tissue-containing samples.

Preparative divergent flow IEF without carrier ampholytes for separation of complex biological samples.

Efficient separation method is a crucial part of the process in which components of highly complex biological sample are identified and characterized. Based on the principles of recently newly established electrophoretic method called divergent flow IEF (DF IEF), we have tested the DF IEF instrument which is able to operate without the use of background carrier ampholytes. We have verified that during separation and focusing of sample consisting of high numbers of proteins (yeast lysate and wheat flour extract), the pH gradient of preparative DF IEF can be created by autofocusing of the sample components themselves without any addition of carrier ampholytes. In DF IEF, the proteins are separated, desalted and concentrated in one step. The fractions of yeast lysate sample, collected at the DF IEF output and subjected to gel IEF, contained the zones of proteins gradually covering the pI values from 3.7 to 8.5. In our experimental arrangement, the highest number of proteins has been found in fractions with pI values around 5.3 as detected by polyacrylamide gel IEF with CBB staining. During DF IEF, the selected protein bands have been concentrated up to 16.8-fold.