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Advances in quantitative high‐throughput phosphoproteomics with sample multiplexing

João A. Paulo, Devin K. Schweppe

2021PROTEOMICS31 citationsDOIOpen Access PDF

Abstract

Eukaryotic protein phosphorylation modulates nearly every major biological process. Phosphorylation regulates protein activity, mediates cellular signal transduction, and manipulates cellular structure. Consequently, the dysregulation of kinase and phosphatase pathways has been linked to a multitude of diseases. Mass spectrometry-based proteomic techniques are increasingly used for the global interrogation of perturbations in phosphorylation-based cellular signaling. Strategies for studying phosphoproteomes require high-specificity enrichment, sensitive detection, and accurate localization of phosphorylation sites with advanced LC-MS/MS techniques and downstream informatics. Sample multiplexing with isobaric tags has also been integral to recent advancements in throughput and sensitivity for phosphoproteomic studies. Each of these facets of phosphoproteomics analysis present distinct challenges and thus opportunities for improvement and innovation. Here, we review current methodologies, explore persistent challenges, and discuss the outlook for isobaric tag-based quantitative phosphoproteomic analysis.

Topics & Concepts

PhosphoproteomicsPhosphorylationProteomicsComputational biologyQuantitative proteomicsBiologyProtein phosphorylationSignal transductionStable isotope labeling by amino acids in cell cultureCell biologyProtein kinase ABiochemistryGeneAdvanced Proteomics Techniques and ApplicationsMass Spectrometry Techniques and ApplicationsMetabolomics and Mass Spectrometry Studies