Abstract
Several stable-isotope-based peptide labeling methods have been developed to support large-scale relative quantitation, through mass spectrometry, of proteins present in two different biological samples. In one of these, trypsin-catalyzed 18O-based labeling, quantitation is typically performed at the full scan (MS) level by comparing the peak intensities of sister precursor ions corresponding to the labeled and unlabeled forms of an intact peptide as they co-elute during liquid chromatography (LC) separations. We show here that measuring relative abundance at the product ion (MS/MS) level after fragmentation provides excellent accuracy, sensitivity and signal-to-noise, while combining quantitation with global shotgun protein identification. To facilitate routine data analysis using this approach, we have developed two specialized software programs, ySelect and yRatios, which draw upon database search results for 18O-based data sets and combine fragmentation spectra peak lists to (1) accurately determine protein ratios between two samples while applying a correction for incomplete labeling and (2) tabulate these results in both intuitive summary reports and in formats amenable to systematic pathway level analysis. To validate our process, we subjected simple and complex test protein mixtures to single-step and multistep LC-MS/MS profiling experiments. Ratio distributions approached the expected means, allowing empirical derivation of confidence level cutoffs for determining statistically significant fold-changes in protein abundance. A set of stringent criteria for detecting spurious ratios based on consistency checking between unlabeled and labeled y-ion pairs was found to highlight putative false positive identifications. In summary, this toolkit facilitates comparative proteomic quantitation under conditions that are optimized for making reliable protein inferences.
Highlights
High-throughput identification of proteins has become possible through the development and convergence of a number of technologies over two decades
Tandem mass spectrometry incorporating collision-induced dissociation performed on peptides was determined to produce readily interpretable fragmentation patterns (Hunt, 1986; Arnott, 1993)
I performed all of the experimentation, including both sample preparation from lysates and mass spectrometry
Summary
High-throughput identification of proteins has become possible through the development and convergence of a number of technologies over two decades. When performing a comparison between two complex protein extracts derived from cells or tissue subjected to different experimental conditions, an investigator often does not want only to generate a definitive list of the proteins present in each extract, and an accurate measurement of their relative abundances. In this way, a picture of significant differential expression both in terms of global pathway activity and specific protein up- and down-regulation can potentially be assembled from the profiles and so be informative about the respective cellular states
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