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Literature DB >> 30658528

Active Instrument Engagement Combined with a Real-Time Database Search for Improved Performance of Sample Multiplexing Workflows.

Brian K Erickson¹, Julian Mintseris¹, Devin K Schweppe¹, José Navarrete-Perea¹, Alison R Erickson¹, David P Nusinow¹, Joao A Paulo¹, Steven P Gygi¹.

Abstract

Quantitative proteomics employing isobaric reagents has been established as a powerful tool for biological discovery. Current workflows often utilize a dedicated quantitative spectrum to improve quantitative accuracy and precision. A consequence of this approach is a dramatic reduction in the spectral acquisition rate, which necessitates the use of additional instrument time to achieve comprehensive proteomic depth. This work assesses the performance and benefits of online and real-time spectral identification in quantitative multiplexed workflows. A Real-Time Search (RTS) algorithm was implemented to identify fragment spectra within milliseconds as they are acquired using a probabilistic score and to trigger quantitative spectra only upon confident peptide identification. The RTS-MS3 was benchmarked against standard workflows using a complex two-proteome model of interference and a targeted 10-plex comparison of kinase abundance profiles. Applying the RTS-MS3 method provided the comprehensive characterization of a 10-plex proteome in 50% less acquisition time. These data indicate that the RTS-MS3 approach provides dramatic performance improvements for quantitative multiplexed experiments.

Entities: CellLine Chemical Disease Gene Species

Keywords: IAPI; SPS-MS3; TMT; iTRAQ; isobaric tag; multiplexing; online search; proteomics; real-time

Year: 2019 PMID： 30658528 PMCID： PMC7081948 DOI： 10.1021/acs.jproteome.8b00899

Source DB: PubMed Journal: J Proteome Res ISSN： 1535-3893 Impact factor: 4.466

15 in total

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4. A Strategy to Combine Sample Multiplexing with Targeted Proteomics Assays for High-Throughput Protein Signature Characterization.

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2. ProteoViz: a tool for the analysis and interactive visualization of phosphoproteomics data.

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5. Parallel Notched Gas-Phase Enrichment for Improved Proteome Identification and Quantification with Fast Spectral Acquisition Rates.

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