Abstract
Reversible protein phosphorylation plays a pivotal role in the regulation of cellular signaling pathways. Current approaches in phosphoproteomics focus on analysis of the global phosphoproteome in a single cellular state or of receptor stimulation time course experiments, often with a restricted number of time points. Although these studies have provided some insights into newly discovered phosphorylation sites that may be involved in pathways, they alone do not provide enough information to make precise predictions of the placement of individual phosphorylation events within a signaling pathway. Protein disruption and site-directed mutagenesis are essential to clearly define the precise biological roles of the hundreds of newly discovered phosphorylation sites uncovered in modern proteomics experiments. We have combined genetic analysis with quantitative proteomic methods and recently developed visual analysis tools to dissect the tyrosine phosphoproteome of isogenic Zap-70 tyrosine kinase null and reconstituted Jurkat T cells. In our approach, label-free quantitation using normalization to copurified phosphopeptide standards is applied to assemble high density temporal data within a single cell type, either Zap-70 null or reconstituted cells, providing a list of candidate phosphorylation sites that change in abundance after T cell stimulation. Stable isotopic labeling of amino acids in cell culture (SILAC) ratios are then used to compare Zap-70 null and reconstituted cells across a time course of receptor stimulation, providing direct information about the placement of newly observed phosphorylation sites relative to Zap-70. These methods are adaptable to any cell culture signaling system in which isogenic wild type and mutant cells have been or can be derived using any available phosphopeptide enrichment strategy.
Highlights
Reversible protein phosphorylation plays a pivotal role in the regulation of cellular signaling pathways
Tyrosine phosphorylated peptides were enriched according to the standard peptide immunoprecipitation procedure described under “Experimental Procedures”
IMAC, and LC/MS, the phosphopeptides were identified with SEQUEST and filtered as described under “Experimental Procedures” to compile a nonredundant list of tyrosine phosphopeptides
Summary
For label-free comparison of phosphopeptide abundance in the Zap-70 reconstituted Jurkat cells, individual time point SICs were normalized to the LIEDAEpYTAK peak area in the same time point. A label-free data heatmap was generated for comparison of phosphopeptides in Zap-70 reconstituted Jurkat cells through a time course of receptor stimulation. The magnitude of change of the heatmap color was calculated from the log of the ratio of the-fold change of each individual peptide peak area compared with the geometric mean for that peptide across all time points (as described in detail in supplemental material 7). In the second type of heatmap, SILAC ratios corresponding to peptide abundance differences between Zap-70 null and reconstituted cell lines across the time course of receptor stimulation were represented. The coefficient of variation percent was calculated for each SILAC ratio heatmap square among the 5 replicate analyses (supplemental material 6). p values were calculated between the Zap-70 null and Zap-70 reconstituted replicate measurements for each phosphopeptide and time point (supplemental Table 6)
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