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

Yan, Tianyang; Desai, Heta S; Boatner, Lisa; Yen, Stephanie L.; Cao, Jian; Palafox, Maria; Jami‐Alahmadi, Yasaman; Backus, Keriann M.

doi:10.1002/cbic.202000870

Cited by 57 publications

(131 citation statements)

References 65 publications

(129 reference statements)

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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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Section: Discussionmentioning

confidence: 99%

Prioritization of antimicrobial targets by CRISPR-based oligo recombineering

Benns

Storch

Falco

et al. 2021

Preprint

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“…Samples were prepared as reported. 15 Jurkat proteome (200 μL of 1 mg/mL) was first labeled with IAA 1 or other reagents (4 μL of 100 mM stock solution in DMSO, final concentration = 2 mM) for 1h at ambient temperature. CuAAC was performed with biotin-azide 2 or other reagents (4 μL of 200 mM stock in DMSO, final concentration = 4 mM), TCEP (4 μL of fresh 50 mM stock in water, final concentration = 1 mM), TBTA (12 μL of 1.7 mM stock in DMSO/t-butanol 1:4, final concentration = 100 μM), and CuSO4 (4 μL of 50 mM stock in water, final concentration = 1 mM) for 1h at ambient temperature.…”

Section: Methodsmentioning

confidence: 99%

“…13,14 However, a central challenge of these studies is that they still only sample a small fraction (2.4%) of all cysteines in the human proteome (estimated to comprise >260,000 residues). 15 Closing this gap requires the development of optimized chemoproteomic sample preparation and data analysis workflows. Supporting this premise, our recent work revealed that using a SP3 cleanup method combined with on-line sample fractionation could achieve 5.5-fold increased coverage compared to prior methods, with decreased instrument time.…”

Section: Introductionmentioning

confidence: 99%

“…Supporting this premise, our recent work revealed that using a SP3 cleanup method combined with on-line sample fractionation could achieve 5.5-fold increased coverage compared to prior methods, with decreased instrument time. 15 One aspect of global cysteine chemoproteomics workflows that remains largely unexplored is the impact of reagent gas-phase fragmentation during MS/MS analysis and whether such fragmentation might impact data analysis or coverage of labeled peptides. The inertness of the triazole formed during 'click chemistry' to gas-phase reactions has been widely documented.…”

Section: Introductionmentioning

confidence: 99%

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Enhancing Cysteine Chemoproteomic Coverage Through Systematic Assessment of Click Chemistry Product Fragmentation

Yan¹,

Palmer²,

Geiszler

et al. 2021

Preprint

Self Cite

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Mass spectrometry-based chemoproteomics has enabled functional analysis and small molecule screening at thousands of cysteine residues in parallel. Widely adopted chemoproteomic sample preparation workflows rely on the use of pan-cysteine reactive probes such as iodoacetamide alkyne combined with biotinylation via copper-catalyzed azide–alkyne cycloaddition (CuAAC) or ‘click chemistry’ for cysteine capture. Despite considerable advances in both sample preparation and analytical platforms, current techniques only sample a small fraction of all cysteines encoded in the human proteome. Extending the recently introduced labile mode of the MSFragger search engine, here we report an in-depth analysis of cysteine biotinylation via click chemistry (CBCC) reagent gas-phase fragmentation during MS/MS analysis. We find that CBCC conjugates produce both known and novel diagnostic fragments and peptide remainder ions. Among these species, we identified a candidate signature ion for CBCC peptides, the oxonium-biotin fragment ion that is generated upon fragmentation of the N(triazole)–C(alkyl) bond together with cyclization. Guided by our empirical comparison of the fragmentation patterns of five CBCC reagent combinations, we achieved enhanced coverage of cysteine labeled peptides. For larger, fragmentation-prone biotinylation reagents, implementation of labile search afforded unique PSMs and provides a roadmap for the utility of such searches in enhancing chemoproteomic peptide coverage.

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“…Eine Erhöhung der Zahl quantifizierter Cysteinreste im Proteom haben Keriann Backus und ihre Gruppe erreicht. 3) Neben der kupferkatalysierten Klick-Chemie wurden bisher nur wenige bioorthogonale Reaktionen eingesetzt. Cao und Coautor:innen haben die Suzuki-Miyaura-Reaktion für positionsaufgelöste proteomweite Experimente genutzt.…”

Section: Positionsaufgelöste Chemo Proteomische Methodenunclassified

Trendbericht Biochemie: Kovalente Proteinliganden

Hacker¹

2021

Nachr Chem

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

Cited by 57 publications

References 65 publications

Prioritization of antimicrobial targets by CRISPR-based oligo recombineering

Prioritization of antimicrobial targets by CRISPR-based oligo recombineering

Enhancing Cysteine Chemoproteomic Coverage Through Systematic Assessment of Click Chemistry Product Fragmentation

Trendbericht Biochemie: Kovalente Proteinliganden

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