Improved drug target deconvolution with PISA‐DIA using an extended, overlapping temperature gradient

Thermal proteome profiling (TPP) is a powerful tool for drug target deconvolution. Recently, data‐independent acquisition mass spectrometry (DIA‐MS) approaches have demonstrated significant improvements to depth and missingness in proteome data, but traditional TPP (a.k.a. CEllular Thermal Shift Ass...

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Veröffentlicht in:	Proteomics (Weinheim) 2024-08, Vol.24 (16), p.e2300644-n/a
Hauptverfasser:	Emery‐Corbin, Samantha J., Yousef, Jumana M., Adhikari, Subash, Sumardy, Fransisca, Nhu, Duong, Delft, Mark F., Lessene, Guillaume, Dziekan, Jerzy, Webb, Andrew I., Dagley, Laura F.
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Sprache:	eng
Schlagworte:	data independent acquisition (DIA) Deconvolution Design of experiments Experimental design Mass spectrometry Mass spectroscopy Melt temperature Multiplexing protein stability Proteins Proteome Integral Solubility Alteration Proteomes proteomics Reagents Target acquisition target engagement Temperature Temperature gradients Therapeutic targets thermal proteome profiling Workflow
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container_issue	16
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container_title	Proteomics (Weinheim)
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creator	Emery‐Corbin, Samantha J. Yousef, Jumana M. Adhikari, Subash Sumardy, Fransisca Nhu, Duong Delft, Mark F. Lessene, Guillaume Dziekan, Jerzy Webb, Andrew I. Dagley, Laura F.
description	Thermal proteome profiling (TPP) is a powerful tool for drug target deconvolution. Recently, data‐independent acquisition mass spectrometry (DIA‐MS) approaches have demonstrated significant improvements to depth and missingness in proteome data, but traditional TPP (a.k.a. CEllular Thermal Shift Assay “CETSA”) workflows typically employ multiplexing reagents reliant on data‐dependent acquisition (DDA). Herein, we introduce a new experimental design for the Proteome Integral Solubility Alteration via label‐free DIA approach (PISA‐DIA). We highlight the proteome coverage and sensitivity achieved by using multiple overlapping thermal gradients alongside DIA‐MS, which maximizes efficiencies in PISA sample concatenation and safeguards against missing protein targets that exist at high melting temperatures. We demonstrate our extended PISA‐DIA design has superior proteome coverage as compared to using tandem‐mass tags (TMT) necessitating DDA‐MS analysis. Importantly, we demonstrate our PISA‐DIA approach has the quantitative and statistical rigor using A‐1331852, a specific inhibitor of BCL‐xL. Due to the high melt temperature of this protein target, we utilized our extended multiple gradient PISA‐DIA workflow to identify BCL‐xL. We assert our novel overlapping gradient PISA‐DIA‐MS approach is ideal for unbiased drug target deconvolution, spanning a large temperature range whilst minimizing target dropout between gradients, increasing the likelihood of resolving the protein targets of novel compounds.
doi_str_mv	10.1002/pmic.202300644
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subjects	data independent acquisition (DIA) Deconvolution Design of experiments Experimental design Mass spectrometry Mass spectroscopy Melt temperature Multiplexing protein stability Proteins Proteome Integral Solubility Alteration Proteomes proteomics Reagents Target acquisition target engagement Temperature Temperature gradients Therapeutic targets thermal proteome profiling Workflow
title	Improved drug target deconvolution with PISA‐DIA using an extended, overlapping temperature gradient
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