Quantification of gel-separated proteins and their phosphorylation sites by LC-MS using unlabeled internal standards: analysis of phosphoprotein dynamics in a B cell lymphoma cell line.

Protein phosphorylation plays a critical role in normal cellular function and is often subverted in disease. Although major advances have recently been made in identification and quantitation of protein phosphorylation sites by MS, current methodological limitations still preclude routine, easily usable, and comprehensive quantitative analysis of protein phosphorylation. Here we report a simple LC-MS method to quantify gel-separated proteins and their sites of phosphorylation; in this approach, integrated chromatographic peak areas of peptide analytes from proteins under study are normalized to those of a non-isotopically labeled internal standard protein spiked into the excised gel samples just prior to in-gel digestion. The internal standard intensities correct for differences in enzymatic activities and sample losses that may occur during the processes of in-gel digestion and peptide extraction from the gel pieces. We used this method of peak area measurement with an internal standard to investigate the effects of pervanadate on protein phosphorylation in the WEHI-231 B cell lymphoma cell line and to assess the role of phosphoinositide 3-kinase (PI3K) in these phosphorylation events. Phosphoproteins, isolated from total cell lysates using IMAC or by immunoprecipitation using Tyr(P) antibodies, were analyzed using this method, leading to identification of >400 proteins, several of which were found at higher levels in phosphoprotein fractions after pervanadate treatment. Pretreatment of cells with the PI3K inhibitor wortmannin reduced the phosphorylation level of certain proteins (e.g. STAT1 and phospholipase Cgamma2) while increasing the phosphorylation of several others. Peak area measurement with an internal standard was also used to follow the dynamics of PI3K-dependent and -independent changes in the post-translational modification of both known and novel phospholipase Cgamma2 phosphorylation sites. Our results illustrate the capacity of this conceptually simple LC-MS method for quantification of gel-separated proteins and their phosphorylation sites and for quantitative profiling of biological systems.

The urinary proteome in Fanconi syndrome implies specificity in the reabsorption of proteins by renal proximal tubule cells.

Polypeptides present in the glomerular filtrate are almost completely reabsorbed in the first segment of the proximal tubule by receptor-mediated endocytosis; in renal Fanconi syndrome (FS), there is failure to reabsorb many of these polypeptides. We have compared the urinary proteomes in patients with Dent's disease (due to a CLC5 mutation), a form of FS, with normal subjects using three different proteomic methods. No differences in the levels of several plasma proteins were detected when standardized to total protein amounts. In contrast, several vitamin and prosthetic group carrier proteins were found in higher amounts in Dent's urine (with respect to total protein). Similarly, complement components, apolipoproteins, and some cytokines represented a larger proportion of the Dent's urinary proteome, suggesting that such proteins are reabsorbed more efficiently than other classes of proteins. Conversely, proteins of renal origin were found in proportionately higher amounts in normal urine. Thus the uptake of filtered vitamins, which are normally bound to their respective carrier proteins to prevent urinary losses, seems a key function of the proximal tubule; in addition, this nephron segment may also play a critical role in reabsorbing potentially cytotoxic polypeptides of plasma origin, preventing them from acting at more distal nephron sites.