Body fluids, like plasma and urine, are comparatively easy to obtain and are useful for the detection of novel diagnostic markers by applying new technologies, like proteomics. However, in plasma, several high-abundance proteins are dominant and repress the signals of the lower-abundance proteins, which then become undetectable either by two-dimensional gels or chromatography. Therefore, depletion of the abundant proteins is a prerequisite for the detection of the low-abundance components. We applied affinity chromatography on blue matrix and Protein G and removed the most abundant human plasma proteins, albumin and the immunoglobulin chains. The plasma proteins, prior to albumin and immunoglobulin depletion, as well the eluates from the two chromatography steps were analyzed by two-dimensional electrophoresis and the proteins were identified by MALDI-TOF-MS. The analysis resulted in the identification of 83 different gene products in the untreated plasma. Removal of the high-abundance proteins resulted in the visualization of new protein signals. In the eluate of the two affinity steps, mostly albumin and immunoglobulin spots were detected but also spots representing several other abundant plasma proteins. The methodology is easy to perform and is useful as a first step in the detection of diagnostic markers in body fluids by applying proteomics technologies.
Two-dimensional gel electrophoresis separates large numbers of proteins in two steps on the basis of differences in their pIs and molecular masses. The separation is usually performed on immobilized pH gradient strips, followed by gradient polyacrylamide gels separating proteins with molecular masses between 5-200 kDa. For the first-dimensional separation the protein samples are usually applied near one end of the strip. Using total soluble protein extracts of the bacterium Haemophilus influenzae, we found that simultaneous sample application at both the basic and the acidic ends of the strip resulted in detection of more and stronger protein spots in comparison with sample application at one end only. Because many proteins of an organism have similar pI and Mr values, an overlapping of protein spots is frequently observed in the second-dimensional separation. The soluble protein fraction of H. influenzae was further separated on gels of constant acrylamide concentration between 7.5% and 15.0%. We found that for proteins of molecular mass within certain ranges, the gels of homogeneous acrylamide concentration provided more efficient spot separation than the gradient gels. The observed improvements in spot resolution may be useful in the characterization of proteins from other organisms or cell lines.
Analysis of the proteome of Haemophilus influenzae by two-dimensional polyacrylamide gel electrophoresis on conventional Tris-glycine gels does not usually result in efficient separation of the proteins in the 5-20 kDa range, which are mainly accumulated in the lower acidic and basic regions. In order to improve the separation of the low molecular mass proteins, we used homogeneous Tricine gels of two urea concentrations in the second-dimensional separation. The Tricine gel systems allowed the efficient and reproducible separation of the proteins of the microorganism with masses between 5 and 20 kDa, however, no proteins with masses below 5 kDa could be visualized. Approximately 80 proteins migrating in the 5-25 kDa region were identified by matrix assisted laser desorption/ionization - mass spectrometry, of which 40 identified for the first time. The digestion of the low mass proteins often produced only few peptides, which were insufficient for confident identification by mass spectrometry. Therefore, the identification was occasionally achieved by a sequential digestion with two proteases, trypsin or endoproteinase Lys-C as first and carboxypeptidase P as second enzyme. The gel system described may be useful for the efficient separation of low molecular mass proteins from other organisms to construct standard maps.
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