Quantitative analysis of bacterial and mammalian proteomes using a combination of cysteine affinity tags and 15N-Metabolic labeling

We describe the combined use of N-15-metabolic labeling and a cysteine-reactive biotin affinity tag to isolate and quantitate cysteine-containing polypeptides (Cys-polypeptides) from Deinococcus radiodurans as well as from mouse B16 melanoma cells. D, radiodurans were cultured in both natural isotopic abundance and N-15-enriched media. Equal numbers of cells from both cultures were combined and the soluble proteins extracted, This mixture of isotopically distinct proteins was derivatized using a commercially available cysteine-reactive reagent that contains a biotin group. Following trypsin digestion, the resulting modified peptides were isolated using immobilized avidin. The mixture was analyzed by capillary reversed-phase liquid chromatography (LC) on-line with ion trap mass spectrometry (RIS) as well as Fourier transform ion cyclotron resonance (FTICR) MS. The resulting spectra contain numerous pairs of Cys-polypeptides whose mass difference corresponds to the number of nitrogen atoms present in each of the peptides. Designation of Cys-polypeptide pairs is also facilitated by the distinctive isotopic distribution of the N-15-labeled peptides versus their N-14-labeled counterparts, Studies with mouse B16 cells maintained in culture allowed the observation of hundreds of isotopically distinct pairs of peptides by LC-FTICR analysis. The ratios of the areas of the pairs of isotopically distinct peptides showed the expected 1:I labeling of the N-14 arid N-15 versions of each peptide. An additional benefit from the present strategy Is that the N-15-labeled peptides do not display significant isotope-dependent chromatographic shifts from their N-14-labeled counterparts, therefore improving the precision for quantitating peptide abundances. The methodology presented offers an alternate, cost-effective strategy for conducting global, quantitative proteomic measurements.