Multi-laboratory assessment of reproducibility, qualitative and quantitative performance of SWATH-mass spectrometry

Collins, Ben C.; Hunter, Christie L.; Liu, Yansheng; Schilling, Birgit; Rosenberger, George; Bader, Samuel L.; Chan, Daniel W.; Gibson, Bradford W.; Gingras, Anne‐Claude; Held, Jason M.; Hirayama-Kurogi, Mio; Hou, Guixue; Krisp, Christoph; Larsen, Brett; Lin, Liang; Liu, Siqi; Molloy, Mark P.; Moritz, Robert L.; Ohtsuki, Sumio; Schlapbach, Ralph; Selevsek, Nathalie; Thomas, Stefani N.; Tzeng, Shin Cheng; Zhang, Hui; Aebersold, Ruedi

doi:10.1038/s41467-017-00249-5

Cited by 463 publications

(466 citation statements)

References 71 publications

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“…The top 20 mostintense precursors of charge state 2-5 were selected for CID fragmentation and MS2 spectra were collected for the range of 50-2,000 m/z, with 100 ms fill time cap and dynamic exclusion of precursor ions from reselection for 15 s, essentially as described (Collins et al, 2013). Data-independent acquisition (SWATH/DIA) mass spectrometry was performed using an updated scheme of 64 variably sized precursor co-isolation windows optimized for human cell lysate MS signal density (SWATHâ 2.0, essentially as described; Collins et al, 2017). SWATH cycles (64 × 50 ms accumulation time) were interspersed by MS1 survey scans for the range of 360-1,460 m/z with a 250 ms fill time cap, resulting in an overall period cycle time of 3,498 ms.…”

Section: Ms Analysismentioning

confidence: 99%

Complex‐centric proteome profiling by SEC ‐ SWATH ‐ MS

Heusel

Bludau

Rosenberger

et al. 2019

Molecular Systems Biology

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117

114

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Proteins are major effectors and regulators of biological processes that can elicit multiple functions depending on their interaction with other proteins. The organization of proteins into macromolecular complexes and their quantitative distribution across these complexes is, therefore, of great biological and clinical significance. In this paper, we describe an integrated experimental and computational technique to quantify hundreds of protein complexes in a single operation. The method consists of size exclusion chromatography (SEC) to fractionate native protein complexes, SWATH/DIA mass spectrometry to precisely quantify the proteins in each SEC fraction, and the computational framework CCprofiler to detect and quantify protein complexes by error‐controlled, complex‐centric analysis using prior information from generic protein interaction maps. Our analysis of the HEK293 cell line proteome delineates 462 complexes composed of 2,127 protein subunits. The technique identifies novel sub‐complexes and assembly intermediates of central regulatory complexes while assessing the quantitative subunit distribution across them. We make the toolset CCprofiler freely accessible and provide a web platform, SECexplorer, for custom exploration of the HEK293 proteome modularity.

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Section: Ms Analysismentioning

confidence: 99%

Complex‐centric proteome profiling by SEC ‐ SWATH ‐ MS

Heusel

Bludau

Rosenberger

et al. 2019

Molecular Systems Biology

Self Cite

117

114

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“…For example, SWATH-MS, an implementation of the DIA strategy, combines the strengths of both aforementioned strategies, and can systematically and reproducibly analyze up of thousands proteins across various conditions and samples (Fig. 1d) [31,34]. To extract quantitative data from the highly complex and convoluted fragment ion spectra generated by DIA/SWATH-MS, prior knowledge about the fragmentation properties of specific peptides is typically employed [35].…”

Section: Proteomics Methods To Provide Mechanistic Insights In Bactermentioning

confidence: 99%

Systems proteomics approaches to study bacterial pathogens: application to Mycobacterium tuberculosis

Banaei‐Esfahani

Nicod

Aebersold

et al. 2017

Current Opinion in Microbiology

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Significant developments and improvements in basic and clinical research notwithstanding, infectious diseases still claim at least 13 million lives annually. Classical research approaches have deciphered many molecular mechanisms underlying infection. Today it is increasingly recognized that multiple molecular mechanisms cooperate to constitute a complex system that is used by a given pathogen to interfere with the biochemical processes of the host. Therefore, systems-level approaches now complement the standard molecular biology techniques to investigate pathogens and their interactions with the human host. Here we review omic studies in Mycobacterium tuberculosis, the causative agent of tuberculosis, with a particular focus on proteomic methods and their application to the bacilli. Likewise, the discussed methods are directly portable to other bacterial pathogens.

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“…These concerns are particularly relevant for plasma proteomics studies where large-cohort projects are typically required to make biological conclusions, and minimizing technical noise is critical in identifying small, biologically significant changes. Towards this goal, researchers should consider incorporating broader technical performance characterization into their method development process, and should understand features such as multi-laboratory repeatability and identify common sources of confounding in their method of choice 103,104 . This information can help the plasma proteomics community move towards the ultimate goal of improved plasma characterization for applications in human health and biology.…”

Section: General Workflow Considerationsmentioning

confidence: 99%

Mass Spectrometry-Based Plasma Proteomics: Considerations from Sample Collection to Achieving Translational Data

Ignjatović

Geyer

Palaniappan

et al. 2019

Preprint

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The proteomic analyses of human blood and blood-derived products (e.g. plasma) offers an attractive avenue to translate research progress from the laboratory into the clinic. However, due to its unique protein composition, performing proteomics assays with plasma is challenging. Plasma proteomics has regained interest due to recent technological advances, but challenges imposed by both complications inherent to studying human biology (e.g. interindividual variability), analysis of biospecimen (e.g. sample variability), as well as technological limitations remain. As part of the Human Proteome Project (HPP), the Human Plasma Proteome Project (HPPP) brings together key aspects of the plasma proteomics pipeline. Here, we provide considerations and recommendations concerning study design, plasma collection, quality metrics, plasma processing workflows, mass spectrometry (MS) data acquisition, data processing and bioinformatic analysis. With exciting opportunities in studying human health and disease though this plasma proteomics pipeline, a more informed analysis of human plasma will accelerate interest whilst enhancing possibilities for the incorporation of proteomics-scaled assays into clinical practice.

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Multi-laboratory assessment of reproducibility, qualitative and quantitative performance of SWATH-mass spectrometry

Cited by 463 publications

References 71 publications

Complex‐centric proteome profiling by SEC ‐ SWATH ‐ MS

Complex‐centric proteome profiling by SEC ‐ SWATH ‐ MS

Systems proteomics approaches to study bacterial pathogens: application to Mycobacterium tuberculosis

Mass Spectrometry-Based Plasma Proteomics: Considerations from Sample Collection to Achieving Translational Data

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