Abstract
Targeted mass spectrometry is an essential tool for detecting quantitative changes in low abundant proteins throughout the proteome. Although selected reaction monitoring (SRM) is the preferred method for quantifying peptides in complex samples, the process of designing SRM assays is laborious. Peptides have widely varying signal responses dictated by sequence-specific physiochemical properties; one major challenge is in selecting representative peptides to target as a proxy for protein abundance. Here we present PREGO, a software tool that predicts high-responding peptides for SRM experiments. PREGO predicts peptide responses with an artificial neural network trained using 11 minimally redundant, maximally relevant properties. Crucial to its success, PREGO is trained using fragment ion intensities of equimolar synthetic peptides extracted from data independent acquisition experiments. Because of similarities in instrumentation and the nature of data collection, relative peptide responses from data independent acquisition experiments are a suitable substitute for SRM experiments because they both make quantitative measurements from integrated fragment ion chromatograms. Using an SRM experiment containing 12,973 peptides from 724 synthetic proteins, PREGO exhibits a 40-85% improvement over previously published approaches at selecting high-responding peptides. These results also represent a dramatic improvement over the rules-based peptide selection approaches commonly used in the literature.
Highlights
From the ‡Department of Genome Sciences, University of Washington, Seattle, Washington 98195; §Proteome Software Inc., Portland, OR 97219
We have developed a strategy for generating large-scale, realistic selected reaction monitoring (SRM) and PRMlike training sets using data-independent acquisition (DIA) MS/MS experiments acquired on a QExactive-HF (Thermo Scientific) using higher energy collisional dissociation (HCD) fragmentation
We present a new method, PREGO, to predicting highresponding peptides to aid in generating SRM and parallel reaction monitoring (PRM) assays
Summary
From the ‡Department of Genome Sciences, University of Washington, Seattle, Washington 98195; §Proteome Software Inc., Portland, OR 97219. To successfully develop an SRM assay for a protein of interest, unique peptide sequences must be chosen that produce a high SRM signal (e.g. high-responding peptides). Once identified, these high-responding peptides are often synthesized or purchased, and independently analyzed to determine the most sensitive transition pairs. Representative peptides are essentially chosen at random, using only a small number of criteria, such as having a reasonable length for detection in the mass spectrometer, a lack of methionine, and a preference for peptides containing proline [5] It is not uncommon for SRM assays to fail at the final validation steps because the peptides chosen in the first assay creation step happened to be unexpectedly poor responding peptides. The authors of CONSeQuence and PPA found that their approaches outperformed the ESP Predictor on a variety of data sets
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