Abstract
In the analysis of complex peptide mixtures by MS-based proteomics, many more peptides elute at any given time than can be identified and quantified by the mass spectrometer. This makes it desirable to optimally allocate peptide sequencing and narrow mass range quantification events. In computer science, intelligent agents are frequently used to make autonomous decisions in complex environments. Here we develop and describe a framework for intelligent data acquisition and real-time database searching and showcase selected examples. The intelligent agent is implemented in the MaxQuant computational proteomics environment, termed MaxQuant Real-Time. It analyzes data as it is acquired on the mass spectrometer, constructs isotope patterns and SILAC pair information as well as controls MS and tandem MS events based on real-time and prior MS data or external knowledge. Re-implementing a top10 method in the intelligent agent yields similar performance to the data dependent methods running on the mass spectrometer itself. We demonstrate the capabilities of MaxQuant Real-Time by creating a real-time search engine capable of identifying peptides “on-the-fly” within 30 ms, well within the time constraints of a shotgun fragmentation “topN” method. The agent can focus sequencing events onto peptides of specific interest, such as those originating from a specific gene ontology (GO) term, or peptides that are likely modified versions of already identified peptides. Finally, we demonstrate enhanced quantification of SILAC pairs whose ratios were poorly defined in survey spectra. MaxQuant Real-Time is flexible and can be applied to a large number of scenarios that would benefit from intelligent, directed data acquisition. Our framework should be especially useful for new instrument types, such as the quadrupole-Orbitrap, that are currently becoming available.
Highlights
Mass spectrometry-based proteomics is generally performed in a shotgun format, where the proteome of interest is digested by a sequence specific protease and resulting peptides are analyzed by on-line liquid chromatography tandem mass spectrometry (LC MS/MS)1 [1,2,3,4]
Unlike MaxQuant, this agent—termed “MaxQuant Real-Time”—reconstructs isotope patterns and stable isotope labeling with amino acid in cell culture (SILAC) patterns based on incomplete information from incoming MS scans and makes decisions about data acquisition within the chromatographic time scale
The intelligent agent was developed in C#.NET as part of the MaxQuant computational proteomics environment (EXPERIMENTAL PROCEDURES)
Summary
Construction of the Intelligent Agent—The intelligent agent makes use of the instrument OCX library (Thermo), which allows programmatic access to the mass spectrometer. At the initialization stage of the measurement the tune file is loaded, and the following parameters are passed to the instrument control software: acquisition file, acquisition time, polarity, automatic gain control settings (ion target values, injection waveforms and machine based automatic gain control), and communication with the high-performance liquid chromatography (contact closure). The postsettings consist of the number of micro-scans (always 1 in our experiments) and the data format (centroid or profile) For both the Full and selected ion monitoring (SIM) scan definition the machine is instructed to do single MS and the maximum inject time is defined. The uncorrected precursor mass information is much more accurate than that provided by Xcalibur (only specified to two decimal places by the Xcalibur software), which makes the link back to the correct precursor in post-processing robust This is especially useful when retrieving the isotope patterns of specific peptides of interest (e.g. with targeting). The data sets used for analysis are deposited at Tranche (www.proteomecommons.org)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
