Reimagining high-throughput profiling of reactive cysteines for cell-based screening of large electrophile libraries

Kuljanin, Miljan; Mitchell, Dylan C.; Schweppe, Devin K.; Gikandi, Ajami; Nusinow, David P.; Bulloch, Nathan J.; Vinogradova, Ekaterina V.; Wilson, David L.; Kool, Eric T.; Mancias, Joseph D.; Cravatt, Benjamin F.; Gygi, Steven P.

doi:10.1038/s41587-020-00778-3

Cited by 185 publications

(334 citation statements)

References 71 publications

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“…The Figure 5. A) Cysteines and B) cysteine proteins identified experimentally in Backus et al, [12] Gygi et al, [58] in the current study, those theoretically detectable based on in silico trypsin digestion, and all found in Uniprot/Swiss-Prot sequences. C) Venn diagram of unique cysteines identified in current study and Gygi et al All data can be found in Table S5.…”

Section: Sp3-faims Chemoproteomic Analysis Of a Panel Of Cell Lines Protease Digests And Subcellular Fractionssupporting

confidence: 58%

“…For comparison, our prior study identified only 15.0 and 14.6 % of proteins, respectively (Figure 5B). As Gygi et al recently reported a new high throughput and high coverage cysteine chemoproteomic method, streamlined cysteine activity-based protein profiling (SLC-ABPP), [58] we additionally opted to benchmark our dataset against their comprehensive inventory of chemoproteomic-detected cysteines. We find that the SP3-FAIMS method identified~31 % more cysteines and~18 % more proteins, using only a fraction of the instrument time (Figure 5).…”

Section: Sp3-faims Chemoproteomic Analysis Of a Panel Of Cell Lines Protease Digests And Subcellular Fractionsmentioning

confidence: 99%

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SP3‐FAIMS Chemoproteomics for High‐Coverage Profiling of the Human Cysteinome**

et al. 2021

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Chemoproteomics has enabled the rapid and proteome-wide discovery of functional, redox-sensitive, and ligandable cysteine residues. Despite widespread adoption and considerable advances in both sample-preparation workflows and MS instrumentation, chemoproteomics experiments still typically only identify a small fraction of all cysteines encoded by the human genome. Here, we develop an optimized sample-preparation workflow that combines enhanced peptide labeling with singlepot, solid-phase-enhanced sample-preparation (SP3) to improve the recovery of biotinylated peptides, even from small sample sizes. By combining this improved workflow with on-line highfield asymmetric waveform ion mobility spectrometry (FAIMS) separation of labeled peptides, we achieve unprecedented coverage of > 14000 unique cysteines in a single-shot 70 min experiment. Showcasing the wide utility of the SP3-FAIMS chemoproteomic method, we find that it is also compatible with competitive small-molecule screening by isotopic tandem orthogonal proteolysis-activity-based protein profiling (isoTOP-ABPP). In aggregate, our analysis of 18 samples from seven cell lines identified 34225 unique cysteines using only~28 h of instrument time. The comprehensive spectral library and improved coverage provided by the SP3-FAIMS chemoproteomics method will provide the technical foundation for future studies aimed at deciphering the functions and druggability of the human cysteineome.

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Section: Sp3-faims Chemoproteomic Analysis Of a Panel Of Cell Lines Protease Digests And Subcellular Fractionssupporting

confidence: 58%

Section: Sp3-faims Chemoproteomic Analysis Of a Panel Of Cell Lines Protease Digests And Subcellular Fractionsmentioning

confidence: 99%

SP3‐FAIMS Chemoproteomics for High‐Coverage Profiling of the Human Cysteinome**

et al. 2021

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“…In recent years the scope, scale, and speed with which chemically reactive amino acids can be profiled has accelerated dramatically; chemoselective probes are now available for cysteine 4 , serine 39 , lysine 5 , methionine 6 , tyrosine 7 , aspartate/glutamate 9,40 , tryptophan 41 , and histidine 42 . Supporting this, advances in mass-spectrometry have significantly expanded the number and rate at which individual reactive sites can be profiled 43,44 , and subsequently exploited by electrophilic drug hunters. CORe provides a technology bridge between unbiased proteomic profiling of reactive sites and protein sequence-function relationships, and will be a valuable tool for proteome engineers alongside other methods including MAGE, CRMAGE and CREATE.…”

Section: Discussionmentioning

confidence: 99%

Prioritization of antimicrobial targets by CRISPR-based oligo recombineering

Benns

Storch

Falco

et al. 2021

Preprint

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Nucleophilic amino acids are important in covalent drug development yet underutilized as antimicrobial targets. Over recent years, several chemoproteomic technologies have been developed to mine chemically-accessible residues via their intrinsic reactivity toward electrophilic probes. However, these approaches cannot discern which reactive sites contribute to protein function and should therefore be prioritized for drug discovery. To address this, we have developed a CRISPR-based Oligo Recombineering (CORe) platform to systematically prioritize reactive amino acids according to their contribution to protein function. Our approach directly couples protein sequence and function with biological fitness. Here, we profile the reactivity of >1,000 cysteines on ~700 proteins in the eukaryotic pathogen Toxoplasma gondii and prioritize functional sites using CORe. We competitively compared the fitness effect of 370 codon switches at 74 cysteines and identify functional sites in a diverse range of proteins. In our proof of concept, CORe performed >800 times faster than a standard genetic workflow. Reactive cysteines decorating the ribosome were found to be critical for parasite growth, with subsequent target-based screening validating the apicomplexan translation machinery as a target for covalent ligand development. CORe is system-agnostic, and supports expedient identification, functional prioritization, and rational targeting of reactive sites in a wide range of organisms and diseases.

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“…Several variants of the latter have been published (e.g. [91,92],) which differ in aspects including the exact probe design with either preinstalled or latent affinity handle as well as quantitative MS strategy with the final sample consisting of enriched probelabeled peptides. Signal reduction for a specific probemodified peptide upon cell pre-treatment with a compound of interest is used to infer compound labeling of a target residue.…”

Section: Affinity-enrichmentbased Chemoproteomic Approachesmentioning

confidence: 99%

“…In this case, the covalent library members do not need additional features to be compatible with the workflow (compared to the PAL equivalent mentioned previously), so that throughput becomes a key limiting factor for screening applications. This has led to the recent report of a scaled-down TMTbased streamlined cysteine (SLC)-ABPP workflow [91] which allows profiling of 8,000 cysteine residues in 18 minutes per compound with reduced input material requirements. While these workflows are used so far predominantly for cysteinetargeting compounds, they can per se be applied to any reactive amino acids for which pan-reactive probes are available.…”

Section: Affinity-enrichmentbased Chemoproteomic Approachesmentioning

confidence: 99%

Proteomics in the pharmaceutical and biotechnology industry: a look to the next decade

Lill¹,

Mathews²,

Rose³

et al. 2021

Expert Review of Proteomics

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Introduction: Pioneering technologies such as proteomics have helped fuel the biotechnology and pharmaceutical industry with the discovery of novel targets and an intricate understanding of the activity of therapeutics and their various activities in vitro and in vivo. The field of proteomics is undergoing an inflection point, where new sensitive technologies are allowing intricate biological pathways to be better understood, and novel biochemical tools are pivoting us into a new era of chemical proteomics and biomarker discovery. In this review, we describe these areas of innovation, and discuss where the fields are headed in terms of fueling biotechnological and pharmacological research and discuss current gaps in the proteomic technology landscape. Areas Covered: Single cell sequencing and single molecule sequencing. Chemoproteomics. Biological matrices and clinical samples including biomarkers. Computational tools including instrument control software, data analysis. Expert Opinion: Proteomics will likely remain a key technology in the coming decade, but will have to evolve with respect to type and granularity of data, cost and throughput of data generation as well as integration with other technologies to fulfill its promise in drug discovery.

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Reimagining high-throughput profiling of reactive cysteines for cell-based screening of large electrophile libraries

Cited by 185 publications

References 71 publications

SP3‐FAIMS Chemoproteomics for High‐Coverage Profiling of the Human Cysteinome**

SP3‐FAIMS Chemoproteomics for High‐Coverage Profiling of the Human Cysteinome**

Prioritization of antimicrobial targets by CRISPR-based oligo recombineering

Proteomics in the pharmaceutical and biotechnology industry: a look to the next decade

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