Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-05T08:05:53.722Z Has data issue: false hasContentIssue false

Stability-based approaches in chemoproteomics

Published online by Cambridge University Press:  12 April 2024

Amy L. George
Affiliation:
Laboratory for Biomedical Mass Spectrometry, Biosciences Institute, Newcastle University, Newcastle-upon-Tyne, NE2 4HH, UK
Maria Emilia Dueñas*
Affiliation:
Laboratory for Biomedical Mass Spectrometry, Biosciences Institute, Newcastle University, Newcastle-upon-Tyne, NE2 4HH, UK
José Luis Marín-Rubio*
Affiliation:
Laboratory for Biomedical Mass Spectrometry, Biosciences Institute, Newcastle University, Newcastle-upon-Tyne, NE2 4HH, UK
Matthias Trost*
Affiliation:
Laboratory for Biomedical Mass Spectrometry, Biosciences Institute, Newcastle University, Newcastle-upon-Tyne, NE2 4HH, UK
*
Corresponding author: Maria Emilia Dueñas; Email: [email protected]; Matthias Trost; Email: [email protected]; José Luis Marín-Rubio; Email: [email protected]
Corresponding author: Maria Emilia Dueñas; Email: [email protected]; Matthias Trost; Email: [email protected]; José Luis Marín-Rubio; Email: [email protected]
Corresponding author: Maria Emilia Dueñas; Email: [email protected]; Matthias Trost; Email: [email protected]; José Luis Marín-Rubio; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Target deconvolution can help understand how compounds exert therapeutic effects and can accelerate drug discovery by helping optimise safety and efficacy, revealing mechanisms of action, anticipate off-target effects and identifying opportunities for therapeutic expansion. Chemoproteomics, a combination of chemical biology with mass spectrometry has transformed target deconvolution. This review discusses modification-free chemoproteomic approaches that leverage the change in protein thermodynamics induced by small molecule ligand binding. Unlike modification-based methods relying on enriching specific protein targets, these approaches offer proteome-wide evaluations, driven by advancements in mass spectrometry sensitivity, increasing proteome coverage and quantitation methods. Advances in methods based on denaturation/precipitation by thermal or chemical denaturation, or by protease degradation are evaluated, emphasising the evolving landscape of chemoproteomics and its potential impact on future drug-development strategies.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Phenotypic drug screening has regained traction in drug discovery, wherein compounds undergo assessment within a relevant biological model to induce specific molecular phenotypes (Ref. Reference Vincent1). Evaluating the overall effects of treatments on cellular behaviour provides a holistic view, leading to the discovery of many first-in-class compounds without any prior knowledge of protein targets (Ref. Reference Swinney and Anthony2). This stands in contrast to target-centric approaches that focus on specific proteins (Ref. Reference Swinney and Le3). However, to understand how these hit compounds exert their therapeutic effects, subsequent target deconvolution is necessary. Knowledge of these proteins targets is important for optimising compound safety and efficacy, elucidating mechanism of action (Ref. Reference Troutman4), identifying potential off-target proteins to anticipate side effects (Refs Reference Becher5, Reference Klaeger6, Reference Miettinen and Björklund7), and recognising opportunities for therapeutic expansion (Refs Reference Conway, Li and Parker8, Reference Pognan9). For instance, the identification of additional protein targets has facilitated the repurposing of existing drugs with established safety profiles for alternative diseases (Refs Reference Vincent1, Reference Blanke10).

The coupling of chemical biology with mass spectrometry, known as chemoproteomics, has revolutionised target deconvolution capabilities. Classically, small molecules can undergo covalent modifications by being immobilised, tagged or labelled with probes to ‘capture’ interacting proteins, producing an enriched sample for proteomic analysis (Ref. Reference Conway, Li and Parker8). While these methods such as affinity-based target identification and activity-based protein profiling have been extensively employed and previously reviewed (Ref. Reference Ha11), these target-enrichment approaches may not be universally applicable to all small molecule compounds and could potentially impact the bioactivity or binding specificity of the drug (Ref. Reference Conway, Li and Parker8).

Herein, we will discuss recent modification-free approaches that leverage the direct stabilisation induced by small molecule ligands. The interaction of a drug and protein can alter its biophysical properties, influencing its resistance against thermal and chemical denaturation or enzymatic degradation. These changes can be identified as distinctive differences in soluble protein abundance or proteolytic digestion patterns under stress conditions in the presence and absence of the drug, on a proteome-wide scale. Although each method differs in workflow, applicability across experimental models and quantitative approaches (Table 1), all these methods have experienced substantial improvements in sensitivity and expanded proteome coverage due to the significant advancements in mass spectrometry observed over the last decade. Notably, the emergence of isobaric labelling technology such as tandem mass tags (TMT) has facilitated the multiplexed comparison of different conditions (Refs Reference Becher5, Reference Zinn12). Additionally, the remarkable progress in data-independent acquisition (DIA) has found utility in some specific approaches, providing excellent proteomic coverage (Ref. Reference Piazza13).

Table 1. Key examples of label-free chemoproteomics approaches: strengths and limitations

In this review, we provide an update on methodological advancements, discussing the strengths and limitations of each approach in target deconvolution for drug discovery. A comprehensive understanding of these differences is crucial when selecting the appropriate chemoproteomic technique for drug–protein interaction studies.

Target deconvolution based on thermal denaturation

Thermal proteome profiling

When proteins are exposed to heat, the hydrogen bonds and hydrophobic interactions supporting their folded structure are disrupted, causing a transition into an unfolded state. This exposes their hydrophobic core, resulting in an insoluble precipitation (Ref. Reference Zhou and Pang14). The energy required to disrupt protein structure is altered upon ligand binding, causing a generally higher shift in melting temperature (T m) as energy is also required to dissociate the bound ligand (Refs Reference Huber15, Reference Mateus, Määttä and Savitski16). This phenomenon has been used in drug discovery for assessing target engagement of purified proteins (Ref. Reference Vedadi17). In 2013 it was applied in the cellular thermal shift assay (CETSA) to directly probe target engagement in complex biological samples, including inside live cells, for the first time (Ref. Reference Martinez Molina18). Cell lysates, intact cells or tissues are treated with a compound and vehicle control, allowing sufficient time for protein–drug binding while limiting influence on protein expression. Subsequently, samples are aliquot and heated at increasing temperatures. Denatured protein precipitates are removed by centrifugation, and the remaining soluble fraction is collected for measurement of target protein stability using Western blotting or microtiter-based antibody assays (Refs Reference Martinez Molina18, Reference Almqvist19, Reference Jafari20). In addition, drugs can be assessed over an increasing concentration at a single temperature, known as isothermal dose–response (ITDR), in both cell and lysates to assess levels of target engagement and provide further information on drug efficacy (Refs Reference Martinez Molina18, Reference Jafari20).

The principles of CETSA were coupled with multiplexed quantitative mass spectrometry, called thermal proteome profiling (TPP), extending from assessment of thermal stability in predefined targets to enabling proteome-wide investigation to identify unknown drug targets or off-targets causing toxic side-effects, and monitor downstream effectors (Refs Reference Franken21, Reference Savitski22). In live cells, TPP provides additional information on downstream effectors that are dependent on the cellular environment (Ref. Reference Mateus, Määttä and Savitski16). Binding of the primary protein target may result in downstream effectors also undergoing changes in thermal stability, as protein–protein interactions (PPI) and altered post-translational modification (PTM) can also induce changes in protein stability (Ref. Reference Mateus, Määttä and Savitski16). These effects can be distinguished by performing TPP in lysates without functional cellular machinery (Refs Reference Mateus, Määttä and Savitski16, Reference Franken21, Reference Savitski22). TPP has been applied to study PPI (Refs Reference Mateus23, Reference Tan24), PTM (Refs Reference Huang25, Reference King26, Reference Potel27, Reference Smith28, Reference Viéitez29), mutation (Ref. Reference Peck Justice30) and proteoforms (Ref. Reference Kurzawa31), protein function and cellular processes' (Refs Reference Becher32, Reference Sridharan33) in various sample types (Refs Reference Gholizadeh34, Reference Perrin35) and biological systems (Refs Reference Viéitez29, Reference Cacace36, Reference Mateus37).

In temperature range TPP (TPP-TR) (Fig. 1A), insoluble protein is removed by ultracentrifugation (100 000 × g) to improve signal-to-noise ratio (Ref. Reference Franken21), or more recently with filter-aided benchtop centrifugation methods that increased throughput (Refs Reference Mateus37, Reference Zijlmans38). Each temperature point in the vehicle and drug-treated conditions is labelled with a different isobaric TMT for precise and multiplexed relative quantification. Originally, TMT-10plex was recommended to label 10 temperatures for melting curve generation, requiring two batches per biological replicate for both treatment and control conditions (Refs Reference Franken21, Reference Savitski22). However, with the development of TMTpro 16-plex and 18-plex, it became feasible to use up to nine temperatures for each melting curve generation (Ref. Reference Zinn12). Samples are pooled, fractionated and analysed together in a single liquid chromatography–mass spectrometry (LC–MS) experiment. This improved quantitative precision and sensitivity by reducing technical variation and facilitating direct comparisons within the same experiment (Ref. Reference Zinn12). By plotting the relationship between temperature and soluble protein abundance, a sigmoidal melting curve is generated for each protein under a particular condition, enabling the calculation of the melting point (T m). The T m represents the temperature at which 50% of the protein has denatured, and significant shifts in thermal stability due to ligand binding can be identified using the TPP package (Refs Reference Franken21, Reference Savitski22).

Figure 1. Schematic representation of chemoproteomic approaches based on thermal denaturation. All of these methods are technically applicable to cell lysates, live cells and tissues. (A) TPP-TR: samples are treated with a single dose of compound and subject to an increasing temperature gradient. Protein abundance in soluble fraction of each temperature labelled with TMT, pooled and fractionated. Melting curves constructed in the presence and absence of the drug are used to calculate shift in melting point (T m). (B) TPP-CCR: cells are treated with different compound concentrations and a vehicle control at a fixed temperature, generating affinity data. (C) 2D-TPP: dose-dependent thermal stabilisation profiling. (D) Isothermal shift assay (iTSA) measures difference in the soluble protein fraction at a single temperature, requiring only two TMT channels per biological replicate. By freeing up available TMT channels, more replicates can be condensed into a single experiment as fractionation is still performed. This leads to a four-fold increase in throughput, allowing for more replicate analyses, which improves statistical power.

Notably, the size of thermal shift does not directly depend on the affinity of the ligand but is unique to the protein's thermodynamics (Ref. Reference Mateus, Määttä and Savitski16). Therefore, the concentration of drug causing 50% of the total stabilising effect can be calculated using TPP-compound concentration range (TPP–CCR) (Fig. 1B), where cells are treated with nine different compound concentrations, and a vehicle control (using TMT10 reagents) at a fixed temperature (Refs Reference Franken21, Reference Savitski22). This can generate affinity data similar to ITDR-CETSA, allowing better comparison of binding affinities among multiple protein targets and comparison of potency across different compounds (Refs Reference Franken21, Reference Savitski22). These two approaches were soon combined by two-dimensional TPP (2D-TPP) (Fig. 1C), where cells are incubated with five varying compound concentrations while subjecting each sample to 12 incremental temperature changes across 6 multiplexed TMT10 experiments (Refs Reference Becher5, Reference Tang39). This approach not only provides valuable insights into compound-target affinity but also eliminates false positive hits by monitoring dose-dependent protein stabilisations (Ref. Reference Mateus, Määttä and Savitski16).

TPP traditionally involves fitting of sigmoidal curves to calculate melting temperature in vehicle and treated samples and uses this single parameter to assess for shifts in protein thermal stability (Refs Reference Becher5, Reference Franken21, Reference Savitski22, Reference Fang40, Reference Jarzab41). However, this analysis approach suffers from a high rate of false-negatives as the filtering based on curve quality-parameters for calculating T m are extremely stringent and has limited statistical power (Refs Reference Childs42, Reference Kurzawa43). A substantial portion of the proteome can provide poor fitting curves as they do not establish sigmoidal melting profiles, resulting in their exclusion from statistical analysis. For example, proteins may exist in multiple transitions (Refs Reference Martinez Molina18, Reference Savitski22), ligand-binding does not always cause aggregation (Ref. Reference Martinez Molina18), the temperatures used in a given experiment will not be optimal for some proteins and the method is not applicable to thermally stable proteins (Refs Reference Jarzab41, Reference McCracken44). Alternative models exist, for example, nonparametric analysis of response curves which compares the whole curve and provides a more robust and sensitive analysis (Ref. Reference Childs42), a Bayesian semi-parametric model (Ref. Reference Fang40) or a statistical scoring method for FDR-controlled analysis of 2D-TPP data (Ref. Reference Kurzawa43). Moreover, missing values are increased at higher temperature points due to complete unfolding for some proteins which can in turn affect curve quality (Ref. Reference Kurzawa43), although an isobaric trigger channel can be included to improve MS/MS analysis of peptides from these low-abundant proteins (Ref. Reference Peck Justice45).

While TPP demonstrates a bias for measuring hydrophilic soluble proteins, the addition of non-ionic or zwitterionic detergents, such as 0.4% NP40 (v/v) or 1% CHAPS (wt/v), improves the solubilisation of membrane proteins (Refs Reference Huber15, Reference Mateus, Määttä and Savitski16, Reference Carnero Corrales46, Reference Reinhard47, Reference Ye48). Although this increases proteomic coverage (>8000 protein groups), recent research shows data indicating their destabilizing effects on the proteome. The average melting temperature across the proteome decreases upon the addition of detergent, leading to increased protein precipitation (Refs Reference Ye48, Reference Berlin49).

Several adaptations have been proposed to enhance TPP's throughput, as a considerable limitation is the substantial number of samples required, which can be costly and labour-intensive. Additionally, the method requires expensive reagents and consumes a significant amount of mass spectrometry time. One such adaptation is the isothermal shift assay (iTSA) (Fig. 1D) which quantifies the difference in the soluble protein fraction at a single temperature (median protein T m in the proteome under investigation). This requires only two TMT channels for direct comparison between vehicle and control sample per biological replicate, leading to a four-fold increase in throughput, allowing for more replicate analyses which improves statistical power (Ref. Reference Ball50). An expected limitation of performing thermal shift assays at a single temperature is bias against proteins with higher or lower melting temperatures deviating from the median T m. Nevertheless, iTSA yielded more target identifications than TPP for staurosporine, which can likely be attributed to the increase from 2 to 5 biological replications (Ref. Reference Ball50). Alternatively, to increase throughput and decrease required starting material, a one-pot method named single-tube TPP with uniform progression (STPP-UP) was recently proposed, but did not perform as well as TPP in resolution, sensitivity or accuracy (Ref. Reference Zijlmans38). Rather than subjecting aliquots of a drug or vehicle-treated sample each to different temperatures as in TPP, a single sample per treatment condition is halved, one aliquot exposed to incrementally increasing temperature for equal exposure times. Modification in protein thermostability due to ligand binding will be reflected in denaturation rate, detected as a change in relative protein abundance in the soluble fraction. The other aliquot is incubated at the low temperature for an equal incubation time, providing a baseline control to correct for differences in protein expression (Ref. Reference Zijlmans38). Ruan et al. explored a similar approach to iTSA, but additionally evaluated multiple concentrations at a single temperature to assess target engagement and binding affinities using label-free DIA-MS for quantitation (Ref. Reference Ruan51). Although these approaches require prior knowledge of the distribution of melting temperatures for the model proteome are required to determine at what temperature the largest differences can be measured.

DIA quantitation is being increasingly adopted for measuring protein solubility in thermal shift assays (Refs Reference Ruan51, Reference Sandbaumhüter52). As outlined in our previous work, different label-free DIA approaches within a 1D-TPP workflow perform comparably to TMT-DDA (Ref. Reference George53). It offers experimental flexibility with no restriction by the number of available TMT channels. Additionally, it presents a simplified sample preparation workflow as there is no labelling or fractionation, and reduced experimental costs in studies with large sample numbers (e.g. TMT reagents required for 2D-TPP) (Refs Reference Ruan51, Reference Sandbaumhüter52). Furthermore, iTSA was recently coupled with a fully automated sample preparation platform (autoSISPROT) and DIA quantification to screen 20 kinase inhibitors in a fully automated manner (Ref. Reference Wu54). Overall, these adapted approaches offer advantages such as simplified experimental design, shortened workflows and more statistical power as there increased number of replicates, proving sufficient for target deconvolution with increased throughput, although by summarising the curves at a fixed temperature, not as much information is gained as constructing full melting curves.

Target deconvolution through limited proteolytic degradation

Drug affinity responsive target stability (DARTS)

Changes in protein structure following ligand-binding can alter their susceptibility to proteolysis as binding may change the access of a non-specific protease to some protein regions. This principle was applied in 2009 in drug affinity responsive target stability (DARTS) (Fig. 2A), an assay for target identification (Ref. Reference Lomenick55). The assay can be applied in a targeted approach, where a purified form of the target protein is treated with compounds of interest or vehicle control, before being exposed to a non-specific protease for a limited time (Refs Reference Huang, Wang and Zhang56, Reference Pai57). Unbound proteins in the vehicle-treated control that are more accessible to protease degradation will be less abundant than the drug-bound protein in the compound-treated sample. Proteolytic peptides can be removed from the remaining intact compound-bound protein by SDS–PAGE, and total intact target protein abundance measured by Western blotting, but this relies on availability of a reliable antibody (Ref. Reference Lomenick55). Equally, this approach can be applied to probe protein targets in complex protein mixtures extracted from cells and tissues either before- (to only identifying direct targets) or after- (capture down-steam effects such as PTMs, also affecting protein structure) small molecule treatment (Ref. Reference Lomenick55).

Figure 2. Schematic of chemoproteomic approaches based on limited proteolytic degradation. All methods are currently applicable to cell lysates only. (A) DARTS identifies proteins with enhanced resistance to proteolysis, by enriching for target proteins by SDS–PAGE. Detectable targets will have higher band intensity compared to the vehicle-treated sample. Both regions are excised for in-gel digestion and MS analysis, providing a rapid approach for target identification. (B) Lysates are treated over a concentration range and then aliquot in half. One-half is subject to limited proteolysis under native conditions, then both aliquots are subject to complete digestion under denaturing conditions, analysed with DIA. Peptides with normalised dose-dependent changes in abundance are scored using LiP-Quant score, ranking the list of targets and providing site-specific information.

For discovery target deconvolution studies, after partial proteolysis, protein mixtures can be separated by 1D SDS–PAGE gel and stained (Ref. Reference Lomenick, Olsen and Huang58). The protein bands with enhanced resistance to proteolysis have a higher intensity compared to the vehicle-pronase treated sample, and so both regions are excised for in-gel digestion and mass spectrometry (Refs Reference Lomenick55, Reference Pai57). This would enable identification and relative quantification of target proteins that are negatively enriched (Refs Reference Lomenick, Olsen and Huang58, Reference Robinson59). Although this gel-based technique is biased towards more abundant proteins with visible differences on a gel, and ligand-bound proteins may be masked by comigrating proteins of higher abundance, consequently providing limited coverage (Refs Reference Lomenick55, Reference Lomenick, Olsen and Huang58). To somewhat improve resolution and improve sensitivity to targets, orthogonal separation techniques were recommended such as 2D SDS–PAGE or 2D difference gel electrophoresis (2D DIGE), which are easy to implement but not very efficient (Refs Reference Pai57, Reference Lomenick, Olsen and Huang58). Alternatively, after non-specific protease treatment, degraded peptides can be dialysed to provide an enriched sample of intact ligand-bound protein for bottom-up proteomic analysis, although in-gel digestion approach remains widely used (Refs Reference Lomenick, Olsen and Huang58, Reference Park60, Reference Morretta61, Reference Chin62). A key strength of DARTS is its speed and simplicity, particularly for confirming abundant targets in complex biological samples, and not demanding large protein starting material. If treated in a stepwise manner, generating a proteolytic curve and a dose–dependence curve, the affinity of protein–ligand interactions can be estimated (Ref. Reference Zhang63). However, it does carry limitations in detecting low abundant proteins, and each protein has varied susceptibility to proteolysis and so the technique is not amenable to resistant or sensitive proteins (Ref. Reference Lomenick55).

Limited proteolysis–coupled mass spectrometry (LiP–MS)

Limited proteolysis–coupled mass spectrometry (LiP-MS) (Fig. 2B) is an alternative structural approach used to detect alterations in protein structure in complex biological matrices on a global scale by assessing enzyme accessibility to protein regions that can be altered by protein aggregation, PTM, PPI or protein–metabolite interaction (Refs Reference Cappelletti64, Reference Feng65, Reference Geiger66, Reference Holfeld67, Reference Malinovska68, Reference Piazza69, Reference Schopper70, Reference Stalder71). For target deconvolution, lysates (to identify direct targets only), live cells (to also probe downstream targets), tissues or bodily fluids can be treated with a compound of interest, but proteins must then be extracted under non-denaturing conditions before treatment with a broad-specificity protease for a very limited time, to produce structure-specific peptides (Refs Reference Piazza13, Reference Stalder71, Reference Reber and Gstaiger72). The method requires ~107 cells to yield at least 800 μg of protein and recommends four biological replicates per condition (Ref. Reference Reber and Gstaiger72). Complete tryptic digestion is subsequently performed under denaturing conditions to allow bottom-up analysis using targeted (Ref. Reference Feng65) or untargeted label-free quantitation (Refs Reference Piazza13, Reference Malinovska68, Reference Piazza69, Reference Schopper70). Concurrently, aliquots of the same biological extracts are digested with trypsin-only to measure total protein abundance in the samples, which are used as a normalisation factor to avoid any differences in protein abundance being interpreted as structural changes between vehicle and treated conditions (Refs Reference Cappelletti64, Reference Malinovska68). By comparing the proteolytic patterns in drug-treated and vehicle-treated proteomes using a peptide-centric analysis, ligand-bound peptides with different normalised abundance and proteolytic pattern can be identified (Refs Reference Feng65, Reference Piazza69, Reference Schopper70), using available data analysis packages (Refs Reference Malinovska68, Reference Quast, Schuster and Picotti73), or other software in development (Ref. Reference Manriquez-Sandoval74).

Applied in 2018 to explore protein–metabolite interactions at a single-dose in microbe lysates (LiP-SMap) (Ref. Reference Piazza69), in 2020 the method was integrated with machine learning to tackle more complex proteomes, named LiP-Quant (Ref. Reference Piazza13). This reduced rates of false-positives and negatives in human cell lines by introducing dose-dependent compound treatments. Peptides with identified changes in abundance, not only correlating with a sigmoidal drug dose–response profile but also additional features identified by machine learning, are assigned a LiP-Quant score. This ranks significant targets, differentiating them from false positive identifications while providing good proteomic coverage in human cell lysates (~5200 protein groups) and cells (~6000 protein groups) (Ref. Reference Piazza13). However, LiP-MS was not as sensitive as TPP in detecting target engagement of kinases when tested with staurosporine, and the two approaches identified many different target proteins, suggesting complementarity when used in combination (Refs Reference Piazza13, Reference Hendricks75). Sample handling adjustments were subsequently made to the protocol to increase throughput from 30 samples to 192 samples across 2 days, supporting larger studies (Ref. Reference Malinovska68).

A notable strength of LiP-MS is its ability to provide site-specific information on binding by mapping the limited-proteolytic peptides to the protein sequence, visualised as a structural barcode (Refs Reference Cappelletti64, Reference Malinovska68). With resolution of ~10 amino acids, compound binding sites can be identified (Ref. Reference Malinovska68). This does require high sequence coverage, thus introduces bias to more abundant proteins, which can be somewhat improved by generating a data-dependant acquisition (DDA)-based spectral library to support data-independent acquisition (DIA) analysis, an established approach to increase proteomic coverage and quantitative accuracy (Refs Reference Malinovska68, Reference Piazza69, Reference Reber and Gstaiger72). Controls can also be applied to correct for variations in proteolytic activity in the non-specific enzyme treatment, such as spiking of internal standards or endogenous peptides with known proteolytic patterns (Ref. Reference Schopper70). LiP-MS is not exhaustive as general extraction procedures suffer in recovery of membrane proteins, although adaptations using nondenaturing MS-compatible surfactants have shown improvement (Ref. Reference Piazza13). Additionally, not all compounds induce structural changes that alter the accessibility of the protein to proteolysis, resulting in false negatives (Ref. Reference Schopper70). Moreover, while lysis conditions are kept as physiological as possible it is essential to consider that protein extraction may induce artefactual structural alterations that are absent in live cells, potentially due to de-compartmentalization (Refs Reference Piazza13, Reference Schopper70).

Target deconvolution approaches based on chemical denaturation

Chemical stress can be used to destabilise proteins, allowing assessment of their differential stability caused as a result ligand binding. For example, chaotropic reagents disrupt hydrogen bonds and induce protein unfolding (Ref. Reference Salvi, De Los Rios and Vendruscolo76). Stability of proteins from rates of oxidation (SPROX) (Fig. 3A) uses this to measure the stability of proteins by exposing compound or vehicle treated lysate sample to a concentration series of chemical denaturing conditions, such as guanidine hydrochloride or urea (Ref. Reference West, Tang and Fitzgerald77). They are incubated with equal amounts of hydrogen peroxide to oxidise the accessible methionine side chain residues to assess the thermodynamic properties of proteins and protein–ligand complexes (Refs Reference West, Tang and Fitzgerald77, Reference West78). The binding of a compound to proteins causes changes in their propensity to denature, resulting in the requirement of different amounts of denaturing agent to unfold and expose methionine residues. Non-oxidised and oxidised peptides can be measured using various quantitative workflows such as chemical labelling (Ref. Reference Strickland79). This method is reliant on quantifying methionine-containing peptides and can require substantial amounts of starting material for protein lysates (2–3 mg) (Refs Reference Strickland79, Reference Ogburn80, Reference Walker81). Another method called pulse proteolysis (PP) is based on a similar principle to SPROX by firstly treating proteins with denaturing chemicals, but susceptibility to proteolysis in presence of ligand is measured instead of methionine oxidation. The protein degradation curve will be shifted if a compound has engaged a protein target (Ref. Reference Trindade82).

Figure 3. Schematic of chemoproteomic approaches based on chemical denaturation or precipitation. (A) Stability of proteins from rates of oxidation (SPROX): Cell lysates are treated with increasing concentrations of chaotropic reagent to unfold proteins, exposing methionine residues for oxidation by addition of H2O2. (B) Solvent-induced protein precipitation (SIP): Lysates are treated with increasing concentrations of solvent, causing protein precipitation. Soluble fractions are subject to dimethyl labelling, and vehicle (heavy) and treatment (light) conditions combined per concentration for LC–MS analysis. Fold change between vehicle and treated conditions are compared. (C) Solvent proteome profiling (SPP) combines the principle of SIP with TMT quantification. Each concentration is labelled, combined, fractionated and analysed to construct denaturation curves in the presence and absence of the drug to calculate shift in the concentration of solvent at which 50% of the protein is unfolded.

Chemical denaturation by solvent and acidic stresses can be monitored by measuring protein solubility (Refs Reference Zhang83, Reference Zhang84). Lysates can be treated with increasing concentrations of organic solvent or acid causing protein unfolding and aggregation, and the soluble protein fraction quantified between treatment and vehicle conditions. For example, solvent-induced protein precipitation (SIP) (Fig. 3B) uses increasing percentage of an organic solvent mixture (acetone/ethanol/acetic acid at a 50:50:0.1 ratio) after a single drug dose, or a dose–response at a single percentage of organic solvent to assess affinity drug–target interaction (Ref. Reference Zhang84). Dimethyl labelling with single-shot LC–MS/MS analysis is used for quantitation but does provide relatively low proteomic coverage (1854 proteins) compared to TPP studies that utilise TMT and fractionation (Ref. Reference Zhang84). Solvent proteome profiling (SPP) (Fig. 3C) uses TMT and fractionation to generate full denaturation curves, similar to TPP and identified > 7600 proteins in two biological replicates (Ref. Reference Van Vranken85).

Target deconvolution approaches based on protein-solubility in cells

Common across the various methods discussed, is the measure for differences in protein (or peptide) abundance within the soluble fraction post-exposure to denaturing or degrading factors such as temperature (Ref. Reference Savitski22), chemical (Refs Reference Zhang84, Reference Van Vranken85, Reference Beusch, Sabatier and Zubarev86, Reference Yu87), or proteasomal (Refs Reference Lomenick55, Reference Piazza69). To address some of the drawbacks inherent in these approaches, particularly low-throughput, proteome integral solubility alteration (PISA) assay was developed to measure variations in solubility across the proteome, while reducing analysis time and sample consumption (Ref. Reference Gaetani88).

In 2019, this assay was first applied in a temperature-centric approach, termed PISA-T (Fig. 4A) and was benchmarked with thermal proteome profiling showing notable correlation (Ref. Reference Gaetani88). The workflow maximises the number of samples analysed within a single TMT batch, by pooling the soluble fractions across temperature points before TMT labelling. Measuring protein abundance (Sm) in each consolidated sample, which represents the total area under its melting curve, regardless of curve shape thus overcoming challenges in sigmoidal curve fitting faced with traditional TPP (Refs Reference Childs42, Reference Gaetani88). Subsequent calculation of differences between areas under the melting curves or fold changes (ratios between integral samples) signify ligand-induced alterations in protein solubility because of direct compound binding in cell lysates, or potentially due to perturbations in associated complexes or PTMs when performed in live cells (Refs Reference Gaetani88, Reference Hung89, Reference Heppler90). The assay was also performed in a 2D format, introducing a third sample/channel per biological replicate, which is a consolidation of a concentration-dependant curve, providing added specificity (Ref. Reference Hung89). Addition of mild detergent such as 0.4% NP-40 was included in recent protocols to improve proteomic coverage (Ref. Reference Zhang91).

Figure 4. Schematic of chemoproteomic approaches measuring alterations in solubility, applicable to live cells and lysates. (A) Proteome integral solubility alteration – temperature (PISA-T): utilises a temperature-centric approach, pooling soluble fractions across temperature points prior to TMT labelling and fractionation, to measure protein abundance and difference in area under the melting curve. A 2D format is optional for added specificity. (B) PISA-I, measures protein solubility in live cells post-denaturation using a kosmotropic gradient. Similarly, soluble fractions are pooled prior to TMT labelling followed by fractionation. An advantage is that more TMT channels are available compared with TPP, allowing more samples to be compared quantitatively in a single experiment.

A significant advantage of PISA is the ability to perform many biological replicates within a single TMT-plex, providing higher statistical power for protein solubility shifts (Ref. Reference Heppler90) especially when utilising 16- or 18-plex TMTpro (Ref. Reference Zhang91). Such datasets provide excellent proteomic coverage (>8000 proteins) with little missing values (Ref. Reference Li92), that are a challenge when performing multi-batch TMT required in classical thermal proteome profiling (Ref. Reference Brenes93). An untreated sample can also be analysed as a carrier proteome in a single TMT channel for improving detection and quantification of less abundant peptides in PISA samples (Ref. Reference Gaetani88). The increased throughput of PISA provides flexibility for experimental design and has allowed for many adaptations of the workflow, allowing more complex assessment such as comparison of multiple compounds (Ref. Reference Sabatier94). Other examples are PISA-express, which allows simultaneous assessment of protein expression and thermal stability, used to study pluripotency in stem cells (Ref. Reference Sabatier95), antibiotic mode of action in bacteria (Ref. Reference Maity96), and PISA-REX to additionally analyse redox (Ref. Reference Saei97). Moreover, residence time PISA (ResT-PISA) introduced a temporal perspective of each drug–target complex by measuring protein solubility profiles after drug treatment removal in cell lysates (by filtering) or intact cells (by cell washing) providing a unique value in supporting the prediction of in vivo drug efficacy (Ref. Reference Sabatier98).

PISA assay has also been applied to measure protein solubility following denaturation by stepwise treatment with kosmotropic reagents (PISA-I) (Ref. Reference Beusch, Sabatier and Zubarev86) or solvents (solvent-PISA) (Ref. Reference Van Vranken85), continuing area under the curve analysis. PISA-I applies to live cells (Fig. 4B) and introduces an additional step of quenching kosmotropic ions resulting in an insoluble salt prior to pooling. Known drug targets (in lysates) and downstream effectors in living cells were identified. Notably, some proteins detected by I-PISA had unique and opposing behaviour in solubility when compared to T-PISA in cell lysates, highlighting the value of using complementary denaturation conditions to probe protein-small molecule interactions. Known targets were also successfully identified from 1 μg (equivalent to ~7000 cells) of compound treated lysate among 691 quantified proteins, providing immense value when there are constraints associated with the initial quantity of cellular material (Ref. Reference Beusch, Sabatier and Zubarev86).

Concluding remarks

To summarise, each method presents distinct advantages for studying protein–ligand interaction, offering insights at either the protein or peptide level under various biological contexts. Collectively, they enable discovery of compound targets, off-targets and structural information on specific binding sites on a proteome-wide scale. All of which have significantly advanced target deconvolution, overcoming previous limitations through enhanced mass spectrometry sensitivity and improved quantitative workflows. Ongoing challenges related to throughput are being addressed by automated sample handling, pooling of soluble fractions to support large-scale studies. Trends in method development emphasise the use of carrier proteomes and isobaric trigger channels to improve sensitivity, particularly as we navigate towards low-sample scenarios. Additionally, incorporating proteomic samples in experiments for normalisation has proven beneficial in resolving and identifying more targets, enhancing sensitivity for ligand-induced alterations. As quantitative workflows continue to evolve, whether through enhanced instrument resolution, advancements in TMTpro technology, or the capabilities of DIA, chemoproteomic abilities will continue to accelerate drug discovery.

References

Vincent, F et al. (2022) Phenotypic drug discovery: recent successes, lessons learned and new directions. Nature Reviews Drug Discovery 21, 899914.CrossRefGoogle ScholarPubMed
Swinney, DC and Anthony, J (2011) How were new medicines discovered? Nature Reviews Drug Discovery 10, 507519.CrossRefGoogle ScholarPubMed
Swinney, DC and Le, JA (2020) Recent advances in phenotypic drug discovery. F1000Research 9, 944.CrossRefGoogle ScholarPubMed
Troutman, S et al. (2016) Crizotinib inhibits NF2-associated schwannoma through inhibition of focal adhesion kinase 1. Oncotarget 7, 5451554525.CrossRefGoogle ScholarPubMed
Becher, I et al. (2016) Thermal profiling reveals phenylalanine hydroxylase as an off-target of panobinostat. Nature Chemical Biology 12, 908910.CrossRefGoogle ScholarPubMed
Klaeger, S et al. (2016) Chemical proteomics reveals ferrochelatase as a common off-target of kinase inhibitors. ACS Chemical Biology 11, 12451254.CrossRefGoogle ScholarPubMed
Miettinen, TP and Björklund, M (2014) NQO2 Is a reactive oxygen species generating off-target for acetaminophen. Molecular Pharmaceutics 11, 43954404.CrossRefGoogle ScholarPubMed
Conway, LP, Li, W and Parker, CG (2021) Chemoproteomic-enabled phenotypic screening. Cell Chemical Biology 28, 371393.CrossRefGoogle ScholarPubMed
Pognan, F et al. (2023) The evolving role of investigative toxicology in the pharmaceutical industry. Nature Reviews Drug Discovery 22, 317335.CrossRefGoogle ScholarPubMed
Blanke, CD et al. (2008) Long-term results from a randomized phase II trial of standard- versus higher-dose imatinib mesylate for patients with unresectable or metastatic gastrointestinal stromal tumors expressing KIT. Journal of Clinical Oncology 26, 620625.CrossRefGoogle ScholarPubMed
Ha, J et al. (2021) Recent advances in identifying protein targets in drug discovery. Cell Chemical Biology 28, 394423.CrossRefGoogle ScholarPubMed
Zinn, N et al. (2021) Improved proteomics-based drug mechanism-of-action studies using 16-plex isobaric mass tags. Journal of Proteome Research 20, 17921801.CrossRefGoogle ScholarPubMed
Piazza, I et al. (2020) A machine learning-based chemoproteomic approach to identify drug targets and binding sites in complex proteomes. Nature Communications 11, 4200.CrossRefGoogle ScholarPubMed
Zhou, HX and Pang, X (2018) Electrostatic interactions in protein structure, folding, binding, and condensation. Chemical Reviews 118, 16911741.CrossRefGoogle ScholarPubMed
Huber, KV et al. (2015) Proteome-wide drug and metabolite interaction mapping by thermal-stability profiling. Nature Methods 12, 10551057.CrossRefGoogle ScholarPubMed
Mateus, A, Määttä, TA and Savitski, MM (2016) Thermal proteome profiling: unbiased assessment of protein state through heat-induced stability changes. Proteome Science 15, 13.CrossRefGoogle ScholarPubMed
Vedadi, M et al. (2006) Chemical screening methods to identify ligands that promote protein stability, protein crystallization, and structure determination. Proceedings of the National Academy of Sciences 103, 1583515840.CrossRefGoogle ScholarPubMed
Martinez Molina, D et al. (2013) Monitoring drug target engagement in cells and tissues using the cellular thermal shift assay. Science (New York, N.Y.) 341, 8487.CrossRefGoogle ScholarPubMed
Almqvist, H et al. (2016) CETSA Screening identifies known and novel thymidylate synthase inhibitors and slow intracellular activation of 5-fluorouracil. Nature Communications 7, 11040.CrossRefGoogle ScholarPubMed
Jafari, R et al. (2014) The cellular thermal shift assay for evaluating drug target interactions in cells. Nature Protocols 9, 21002122.CrossRefGoogle ScholarPubMed
Franken, H et al. (2015) Thermal proteome profiling for unbiased identification of direct and indirect drug targets using multiplexed quantitative mass spectrometry. Nature Protocols 10, 15671593.CrossRefGoogle ScholarPubMed
Savitski, MM et al. (2014) Tracking cancer drugs in living cells by thermal profiling of the proteome. Science (New York, N.Y.) 346, 1255784.CrossRefGoogle ScholarPubMed
Mateus, A et al. (2020) Thermal proteome profiling for interrogating protein interactions. Molecular Systems Biology 16, e9232.CrossRefGoogle ScholarPubMed
Tan, CSH et al. (2018) Thermal proximity coaggregation for system-wide profiling of protein complex dynamics in cells. Science (New York, N.Y.) 359, 11701177.CrossRefGoogle ScholarPubMed
Huang, JX et al. (2019) High throughput discovery of functional protein modifications by hotspot thermal profiling. Nature Methods 16, 894901.CrossRefGoogle ScholarPubMed
King, DT et al. (2022) Thermal proteome profiling reveals the O-GlcNAc-dependent meltome. Journal of the American Chemical Society 144, 38333842.CrossRefGoogle ScholarPubMed
Potel, CM et al. (2021) Impact of phosphorylation on thermal stability of proteins. Nature Methods 18, 757759.CrossRefGoogle ScholarPubMed
Smith, IR et al. (2021) Identification of phosphosites that alter protein thermal stability. Nature Methods 18, 760762.CrossRefGoogle ScholarPubMed
Viéitez, C et al. (2022) High-throughput functional characterization of protein phosphorylation sites in yeast. Nature Biotechnology 40, 382390.CrossRefGoogle ScholarPubMed
Peck Justice, SA et al. (2020) Mutant thermal proteome profiling for characterization of missense protein variants and their associated phenotypes within the proteome. Journal of Biological Chemistry 295, 1621916238.CrossRefGoogle ScholarPubMed
Kurzawa, N et al. (2023) Deep thermal profiling for detection of functional proteoform groups. Nature Chemical Biology 19, 962971.CrossRefGoogle ScholarPubMed
Becher, I et al. (2018) Pervasive protein thermal stability variation during the cell cycle. Cell 173, 14951507, e18.CrossRefGoogle ScholarPubMed
Sridharan, S et al. (2019) Proteome-wide solubility and thermal stability profiling reveals distinct regulatory roles for ATP. Nature Communications 10, 1155.CrossRefGoogle ScholarPubMed
Gholizadeh, E et al. (2021) Identification of celecoxib-targeted proteins using label-free thermal proteome profiling on rat hippocampus. Molecular Pharmacology 99, 308318.CrossRefGoogle ScholarPubMed
Perrin, J et al. (2020) Identifying drug targets in tissues and whole blood with thermal-shift profiling. Nature Biotechnology 38, 303308.CrossRefGoogle ScholarPubMed
Cacace, E et al. (2023) Systematic analysis of drug combinations against gram-positive bacteria. Nature Microbiology, 8(11): p. 21962212.CrossRefGoogle ScholarPubMed
Mateus, A et al. (2018) Thermal proteome profiling in bacteria: probing protein state in vivo. Molecular Systems Biology 14, e8242.CrossRefGoogle ScholarPubMed
Zijlmans, DW et al. (2023) STPP-UP: an alternative method for drug target identification using protein thermal stability. Journal of Biological Chemistry 299, 105279.CrossRefGoogle ScholarPubMed
Tang, G et al. (2023) Orthogonal strategies for profiling potential cellular targets of anandamide and cannabidiol. Chemistry 29, e202300682.CrossRefGoogle ScholarPubMed
Fang, S et al. (2021) A Bayesian semi-parametric model for thermal proteome profiling. Communications Biology 4, 810.CrossRefGoogle ScholarPubMed
Jarzab, A et al. (2020) Meltome atlas-thermal proteome stability across the tree of life. Nature Methods 17, 495503.CrossRefGoogle ScholarPubMed
Childs, D et al. (2019) Nonparametric analysis of thermal proteome profiles reveals novel drug-binding proteins. Molecular and Cellular Proteomics 18, 25062515.CrossRefGoogle ScholarPubMed
Kurzawa, N et al. (2020) A computational method for detection of ligand-binding proteins from dose range thermal proteome profiles. Nature Communications 11, 5783.CrossRefGoogle ScholarPubMed
McCracken, NA et al. (2021) Inflect: optimizing computational workflows for thermal proteome profiling data analysis. Journal of Proteome Research 20, 18741888.CrossRefGoogle ScholarPubMed
Peck Justice, SA et al. (2021) Boosting detection of low-abundance proteins in thermal proteome profiling experiments by addition of an isobaric trigger channel to TMT multiplexes. Analytical Chemistry 93, 70007010.CrossRefGoogle Scholar
Carnero Corrales, MA et al. (2021) Thermal proteome profiling identifies the membrane-bound purinergic receptor P2X4 as a target of the autophagy inhibitor indophagolin. Cell Chemical Biology 28, 17501757.e5.CrossRefGoogle ScholarPubMed
Reinhard, FB et al. (2015) Thermal proteome profiling monitors ligand interactions with cellular membrane proteins. Nature Methods 12, 11291131.CrossRefGoogle ScholarPubMed
Ye, Y et al. (2023) The introduction of detergents in thermal proteome profiling requires lowering the applied temperatures for efficient target protein identification. Molecules 28, 4859.CrossRefGoogle ScholarPubMed
Berlin, E et al. (2023) Nonionic surfactants can modify the thermal stability of globular and membrane proteins interfering with the thermal proteome profiling principles to identify protein targets. Analytical Chemistry 95, 40334042.CrossRefGoogle ScholarPubMed
Ball, KA et al. (2020) An isothermal shift assay for proteome scale drug-target identification. Communications Biology 3, 75.CrossRefGoogle ScholarPubMed
Ruan, C et al. (2022) Matrix thermal shift assay for fast construction of multidimensional ligand-target space. Analytical Chemistry 94, 64826490.CrossRefGoogle ScholarPubMed
Sandbaumhüter, FA et al. (2023) Label-free quantitative thermal proteome profiling reveals target transcription factors with activities modulated by MC3R signaling. Analytical Chemistry 95, 1540015408.CrossRefGoogle ScholarPubMed
George, AL et al. (2023) Comparison of quantitative mass spectrometric methods for drug target identification by thermal proteome profiling. Journal of Proteome Research 22, 26292640.CrossRefGoogle ScholarPubMed
Wu, Q et al. (2024) High-throughput drug target discovery by fully automated proteomics sample preparation platform. Chemical Science 15, 28332847.CrossRefGoogle ScholarPubMed
Lomenick, B et al. (2009) Target identification using drug affinity responsive target stability (DARTS). Proceedings of the National Academy of Sciences of the United States of America 106, 2198421989.CrossRefGoogle ScholarPubMed
Huang, L, Wang, D and Zhang, C (2021) Drug affinity responsive target stability (DARTS) assay to detect interaction between a purified protein and a small molecule. Methods in Molecular Biology 2213, 175182.CrossRefGoogle ScholarPubMed
Pai, MY et al. (2015) Drug affinity responsive target stability (DARTS) for small-molecule target identification. Methods in Molecular Biology (Clifton. N.J.) 1263, 287298.CrossRefGoogle ScholarPubMed
Lomenick, B, Olsen, RW and Huang, J (2011) Identification of direct protein targets of small molecules. ACS Chemical Biology 6, 3446.CrossRefGoogle ScholarPubMed
Robinson, TJ et al. (2013) High-throughput screen identifies disulfiram as a potential therapeutic for triple-negative breast cancer cells: interaction with IQ motif-containing factors. Cell Cycle 12, 30133024.CrossRefGoogle ScholarPubMed
Park, SI et al. (2024) NDUFA12 As a functional target of the anticancer compound ertredin in human hepatoma cells as revealed by label-free chemical proteomics. Journal of Proteome Research 23, 130141.CrossRefGoogle ScholarPubMed
Morretta, E et al. (2021) Novel insights on the molecular mechanism of action of the anti-angiogenic pyrazolyl-urea GeGe-3 by functional proteomics. Bioorganic Chemistry 115, 105168.CrossRefGoogle ScholarPubMed
Chin, RM et al. (2014) The metabolite α-ketoglutarate extends lifespan by inhibiting ATP synthase and TOR. Nature 510, 397401.CrossRefGoogle ScholarPubMed
Zhang, C et al. (2019) A semi-quantitative drug affinity responsive target stability (DARTS) assay for studying rapamycin/mTOR interaction. Journal of Visualized Experiments : JoVE 150. doi: 10.3791/59656Google Scholar
Cappelletti, V et al. (2021) Dynamic 3D proteomes reveal protein functional alterations at high resolution in situ. Cell 184, 545559, e22.CrossRefGoogle ScholarPubMed
Feng, Y et al. (2014) Global analysis of protein structural changes in complex proteomes. Nature Biotechnology 32, 10361044.CrossRefGoogle ScholarPubMed
Geiger, R et al. (2016) L-arginine modulates T cell metabolism and enhances survival and anti-tumor activity. Cell 167, 829842, e13.CrossRefGoogle ScholarPubMed
Holfeld, A et al. (2023) Limited proteolysis–mass spectrometry to identify metabolite-protein interactions. Methods in Molecular Biology 2554, 6989.CrossRefGoogle ScholarPubMed
Malinovska, L et al. (2023) Proteome-wide structural changes measured with limited proteolysis–mass spectrometry: an advanced protocol for high-throughput applications. Nature Protocols 18, 659682.CrossRefGoogle ScholarPubMed
Piazza, I et al. (2018) A map of protein-metabolite interactions reveals principles of chemical communication. Cell 172, 358372, e23.CrossRefGoogle ScholarPubMed
Schopper, S et al. (2017) Measuring protein structural changes on a proteome-wide scale using limited proteolysis-coupled mass spectrometry. Nature Protocols 12, 23912410.CrossRefGoogle ScholarPubMed
Stalder, P et al. (2023) An approach to characterize mechanisms of action of anti-amyloidogenic compounds in vitro and in situ. bioRxiv: The Preprint Server For Biology. doi: 10.1101/2023.12.18.572111Google Scholar
Reber, V and Gstaiger, M (2023) Target deconvolution by limited proteolysis coupled to mass spectrometry. Methods in Molecular Biology 2706, 177190.CrossRefGoogle ScholarPubMed
Quast, JP, Schuster, D and Picotti, P (2021) protti: an R package for comprehensive data analysis of peptide- and protein-centric bottom-up proteomics data. Bioinformatics Advances 2, vbab041.CrossRefGoogle Scholar
Manriquez-Sandoval, E et al. (2023) FLiPPR: a processor for limited proteolysis (LiP) mass spectrometry datasets built on FragPipe. bioRxiv: the Preprint Server for Biology. doi: 10.1101/2023.12.04.569947Google ScholarPubMed
Hendricks, JA et al. (2022) Mechanistic insights into a CDK9 inhibitor via orthogonal proteomics methods. ACS Chemical Biology 17, 5467.CrossRefGoogle ScholarPubMed
Salvi, G, De Los Rios, P and Vendruscolo, M (2005) Effective interactions between chaotropic agents and proteins. Proteins 61, 492499.CrossRefGoogle ScholarPubMed
West, GM, Tang, L and Fitzgerald, MC (2008) Thermodynamic analysis of protein stability and ligand binding using a chemical modification- and mass spectrometry-based strategy. Analytical Chemistry 80, 41754185.CrossRefGoogle ScholarPubMed
West, GM et al. (2010) Quantitative proteomics approach for identifying protein-drug interactions in complex mixtures using protein stability measurements. Proceedings of the National Academy of Sciences of the United States of America 107, 90789082.CrossRefGoogle ScholarPubMed
Strickland, EC et al. (2013) Thermodynamic analysis of protein-ligand binding interactions in complex biological mixtures using the stability of proteins from rates of oxidation. Nature Protocols 8, 148161.CrossRefGoogle ScholarPubMed
Ogburn, RN et al. (2017) Discovery of tamoxifen and N-desmethyl tamoxifen protein targets in MCF-7 cells using large-scale protein folding and stability measurements. Journal of Proteome Research 16, 40734085.CrossRefGoogle ScholarPubMed
Walker, EJ et al. (2019) Global analysis of methionine oxidation provides a census of folding stabilities for the human proteome. Proceedings of the National Academy of Sciences of the United States of America 116, 60816090.CrossRefGoogle ScholarPubMed
Trindade, RV et al. (2016) Pulse proteolysis and precipitation for target identification. Journal of Proteome Research 15, 22362245.CrossRefGoogle ScholarPubMed
Zhang, X et al. (2022) Highly effective identification of drug targets at the proteome level by pH-dependent protein precipitation. Chemical Science 13, 1240312418.CrossRefGoogle ScholarPubMed
Zhang, X et al. (2020) Solvent-induced protein precipitation for drug target discovery on the proteomic scale. Analytical Chemistry 92, 13631371.CrossRefGoogle ScholarPubMed
Van Vranken, JG et al. (2021) Assessing target engagement using proteome-wide solvent shift assays. eLife 10, e70784.CrossRefGoogle ScholarPubMed
Beusch, CM, Sabatier, P and Zubarev, RA (2022) Ion-based proteome-integrated solubility alteration assays for systemwide profiling of protein–molecule interactions. Analytical Chemistry 94, 70667074.CrossRefGoogle ScholarPubMed
Yu, C et al. (2023) Solvent-induced proteome profiling for proteomic quantitation and target discovery of small molecular drugs. Proteomics 23, e2200281.CrossRefGoogle ScholarPubMed
Gaetani, M et al. (2019) Proteome integral solubility alteration: a high-throughput proteomics assay for target deconvolution. Journal of Proteome Research 18, 40274037.CrossRefGoogle ScholarPubMed
Hung, SW et al. (2024) Distinct molecular targets of ProEGCG from EGCG and superior inhibition of angiogenesis signaling pathways for treatment of endometriosis. Journal of Pharmaceutical Analysis 14, 100114.CrossRefGoogle ScholarPubMed
Heppler, LN et al. (2022) The antimicrobial drug pyrimethamine inhibits STAT3 transcriptional activity by targeting the enzyme dihydrofolate reductase. The Journal of Biological Chemistry 298, 101531.CrossRefGoogle ScholarPubMed
Zhang, X et al. (2022) Proteome integral solubility alteration (PISA) assay in mammalian cells for deep, high-confidence, and high-throughput target deconvolution. Bio-Protocol 12, e4556.CrossRefGoogle ScholarPubMed
Li, J et al. (2020) TMTPro reagents: a set of isobaric labeling mass tags enables simultaneous proteome-wide measurements across 16 samples. Nature Methods 17, 399404.CrossRefGoogle ScholarPubMed
Brenes, A et al. (2019) Multibatch TMT reveals false positives, batch effects and missing values. Molecular & Cellular Proteomics: MCP 18, 19671980.CrossRefGoogle ScholarPubMed
Sabatier, P et al. (2021) Comprehensive chemical proteomics analyses reveal that the new TRi-1 and TRi-2 compounds are more specific thioredoxin reductase 1 inhibitors than auranofin. Redox Biology 48, 102184.CrossRefGoogle ScholarPubMed
Sabatier, P et al. (2021) An integrative proteomics method identifies a regulator of translation during stem cell maintenance and differentiation. Nature Communications 12, 6558.CrossRefGoogle ScholarPubMed
Maity, R et al. (2023) Merging multi-OMICs with proteome integral solubility alteration unveils antibiotic mode of action. bioRxiv: the Preprint Server for Biology. doi: 10.1101/2023.09.07.556692Google Scholar
Saei, A.A. et al. (2023) Multifaceted proteome analysis at solubility, redox, and expression dimensions for target identification. bioRxiv: the Preprint Server for Biology. doi: 10.1101/2023.08.31.555796Google Scholar
Sabatier, P et al. (2022) System-wide profiling by proteome integral solubility alteration assay of drug residence times for target characterization. Analytical Chemistry 94, 1577215780.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Key examples of label-free chemoproteomics approaches: strengths and limitations

Figure 1

Figure 1. Schematic representation of chemoproteomic approaches based on thermal denaturation. All of these methods are technically applicable to cell lysates, live cells and tissues. (A) TPP-TR: samples are treated with a single dose of compound and subject to an increasing temperature gradient. Protein abundance in soluble fraction of each temperature labelled with TMT, pooled and fractionated. Melting curves constructed in the presence and absence of the drug are used to calculate shift in melting point (Tm). (B) TPP-CCR: cells are treated with different compound concentrations and a vehicle control at a fixed temperature, generating affinity data. (C) 2D-TPP: dose-dependent thermal stabilisation profiling. (D) Isothermal shift assay (iTSA) measures difference in the soluble protein fraction at a single temperature, requiring only two TMT channels per biological replicate. By freeing up available TMT channels, more replicates can be condensed into a single experiment as fractionation is still performed. This leads to a four-fold increase in throughput, allowing for more replicate analyses, which improves statistical power.

Figure 2

Figure 2. Schematic of chemoproteomic approaches based on limited proteolytic degradation. All methods are currently applicable to cell lysates only. (A) DARTS identifies proteins with enhanced resistance to proteolysis, by enriching for target proteins by SDS–PAGE. Detectable targets will have higher band intensity compared to the vehicle-treated sample. Both regions are excised for in-gel digestion and MS analysis, providing a rapid approach for target identification. (B) Lysates are treated over a concentration range and then aliquot in half. One-half is subject to limited proteolysis under native conditions, then both aliquots are subject to complete digestion under denaturing conditions, analysed with DIA. Peptides with normalised dose-dependent changes in abundance are scored using LiP-Quant score, ranking the list of targets and providing site-specific information.

Figure 3

Figure 3. Schematic of chemoproteomic approaches based on chemical denaturation or precipitation. (A) Stability of proteins from rates of oxidation (SPROX): Cell lysates are treated with increasing concentrations of chaotropic reagent to unfold proteins, exposing methionine residues for oxidation by addition of H2O2. (B) Solvent-induced protein precipitation (SIP): Lysates are treated with increasing concentrations of solvent, causing protein precipitation. Soluble fractions are subject to dimethyl labelling, and vehicle (heavy) and treatment (light) conditions combined per concentration for LC–MS analysis. Fold change between vehicle and treated conditions are compared. (C) Solvent proteome profiling (SPP) combines the principle of SIP with TMT quantification. Each concentration is labelled, combined, fractionated and analysed to construct denaturation curves in the presence and absence of the drug to calculate shift in the concentration of solvent at which 50% of the protein is unfolded.

Figure 4

Figure 4. Schematic of chemoproteomic approaches measuring alterations in solubility, applicable to live cells and lysates. (A) Proteome integral solubility alteration – temperature (PISA-T): utilises a temperature-centric approach, pooling soluble fractions across temperature points prior to TMT labelling and fractionation, to measure protein abundance and difference in area under the melting curve. A 2D format is optional for added specificity. (B) PISA-I, measures protein solubility in live cells post-denaturation using a kosmotropic gradient. Similarly, soluble fractions are pooled prior to TMT labelling followed by fractionation. An advantage is that more TMT channels are available compared with TPP, allowing more samples to be compared quantitatively in a single experiment.