E. coli monothiol glutaredoxin GrxD replenishes Fe-S clusters to the essential ErpA A-type carrier under low iron stress.

Iron-sulfur (Fe-S) clusters are required for essential biological pathways, including respiration and isoprenoid biosynthesis. Complex Fe-S cluster biogenesis systems have evolved to maintain an adequate supply of this critical protein cofactor. In Escherichia coli, two Fe-S biosynthetic systems, the "housekeeping" Isc and "stress responsive" Suf pathways, interface with a network of cluster trafficking proteins, such as ErpA, IscA, SufA, and NfuA. GrxD, a Fe-S cluster-binding monothiol glutaredoxin, also participates in Fe-S protein biogenesis in both prokaryotes and eukaryotes. Previous studies in E. coli showed that the ΔgrxD mutation causes sensitivity to iron depletion, spotlighting a critical role for GrxD under conditions that disrupt Fe-S homeostasis. Here, we utilized a global chemoproteomic mass spectrometry (MS) approach to analyse the contribution of GrxD to the Fe-S proteome. Our results demonstrate that 1) GrxD is required for biogenesis of a specific subset of Fe-S proteins under iron-depleted conditions, 2) GrxD is required for cluster delivery to ErpA under iron limitation, 3) GrxD is functionally distinct from other Fe-S trafficking proteins and, 4) GrxD Fe-S cluster binding is responsive to iron limitation. All these results lead to the proposal that GrxD is required to maintain Fe-S cluster delivery to the essential trafficking protein ErpA during iron limitation conditions.

Monitoring Fe-S cluster occupancy across the E. coli proteome using chemoproteomics.

Iron-sulfur (Fe-S) clusters are ubiquitous metallocofactors involved in redox chemistry, radical generation and gene regulation. Common methods to monitor Fe-S clusters include spectroscopic analysis of purified proteins and autoradiographic visualization of radiolabeled iron distribution in proteomes. Here, we report a chemoproteomic strategy that monitors changes in the reactivity of Fe-S cysteine ligands to inform on Fe-S cluster occupancy. We highlight the utility of this platform in Escherichia coli by (1) demonstrating global disruptions in Fe-S incorporation in cells cultured under iron-depleted conditions, (2) determining Fe-S client proteins reliant on five scaffold, carrier and chaperone proteins within the Isc Fe-S biogenesis pathway and (3) identifying two previously unannotated Fe-S proteins, TrhP and DppD. In summary, the chemoproteomic strategy described herein is a powerful tool that reports on Fe-S cluster incorporation directly within a native proteome, enabling the interrogation of Fe-S biogenesis pathways and the identification of previously uncharacterized Fe-S proteins.

An infection-induced oxidation site regulates legumain processing and tumor growth.

Oxidative stress is a defining feature of most cancers, including those that stem from carcinogenic infections. Reactive oxygen species can drive tumor formation, yet the molecular oxidation events that contribute to tumorigenesis are largely unknown. Here we show that inactivation of a single, redox-sensitive cysteine in the host protease legumain, which is oxidized during infection with the gastric cancer-causing bacterium Helicobacter pylori, accelerates tumor growth. By using chemical proteomics to map cysteine reactivity in human gastric cells, we determined that H. pylori infection induces oxidation of legumain at Cys219. Legumain oxidation dysregulates intracellular legumain processing and decreases the activity of the enzyme in H. pylori-infected cells. We further show that the site-specific loss of Cys219 reactivity increases tumor growth and mortality in a xenograft model. Our findings establish a link between an infection-induced oxidation site and tumorigenesis while underscoring the importance of cysteine reactivity in tumor growth.

Heterogeneous adaptation of cysteine reactivity to a covalent oncometabolite.

An important context in which metabolism influences tumorigenesis is the genetic cancer syndrome hereditary leiomyomatosis and renal cell carcinoma (HLRCC), a disease in which mutation of the tricarboxylic acid cycle enzyme fumarate hydratase (FH) causes hyperaccumulation of fumarate. This electrophilic oncometabolite can alter gene activity at the level of transcription, via reversible inhibition of epigenetic dioxygenases, as well as posttranslationally, via covalent modification of cysteine residues. To better understand the potential for metabolites to influence posttranslational modifications important to tumorigenesis and cancer cell growth, here we report a chemoproteomic analysis of a kidney-derived HLRCC cell line. Using a general reactivity probe, we generated a data set of proteomic cysteine residues sensitive to the reduction in fumarate levels caused by genetic reintroduction of active FH into HLRCC cell lines. This revealed a broad up-regulation of cysteine reactivity upon FH rescue, which evidence suggests is caused by an approximately equal proportion of transcriptional and posttranslational modification-mediated regulation. Gene ontology analysis highlighted several new targets and pathways potentially modulated by FH mutation. Comparison of the new data set with prior studies highlights considerable heterogeneity in the adaptive response of cysteine-containing proteins in different models of HLRCC. This is consistent with emerging studies indicating the existence of cell- and tissue-specific cysteine-omes, further emphasizing the need for characterization of diverse models. Our analysis provides a resource for understanding the proteomic adaptation to fumarate accumulation and a foundation for future efforts to exploit this knowledge for cancer therapy.

A chemoproteomic portrait of the oncometabolite fumarate.

Hereditary cancer disorders often provide an important window into novel mechanisms supporting tumor growth. Understanding these mechanisms thus represents a vital goal. Toward this goal, here we report a chemoproteomic map of fumarate, a covalent oncometabolite whose accumulation marks the genetic cancer syndrome hereditary leiomyomatosis and renal cell carcinoma (HLRCC). We applied a fumarate-competitive chemoproteomic probe in concert with LC-MS/MS to discover new cysteines sensitive to fumarate hydratase (FH) mutation in HLRCC cell models. Analysis of this dataset revealed an unexpected influence of local environment and pH on fumarate reactivity, and enabled the characterization of a novel FH-regulated cysteine residue that lies at a key protein-protein interface in the SWI-SNF tumor-suppressor complex. Our studies provide a powerful resource for understanding the covalent imprint of fumarate on the proteome and lay the foundation for future efforts to exploit this distinct aspect of oncometabolism for cancer diagnosis and therapy.

A cysteinyl-tRNA synthetase variant confers resistance against selenite toxicity and decreases selenocysteine misincorporation.

Selenocysteine (Sec) is the 21st genetically encoded amino acid in organisms across all domains of life. Although structurally similar to cysteine (Cys), the Sec selenol group has unique properties that are attractive for protein engineering and biotechnology applications. Production of designer proteins with Sec (selenoproteins) at desired positions is now possible with engineered translation systems in Escherichia coli However, obtaining pure selenoproteins at high yields is limited by the accumulation of free Sec in cells, causing undesired incorporation of Sec at Cys codons due to the inability of cysteinyl-tRNA synthetase (CysRS) to discriminate against Sec. Sec misincorporation is toxic to cells and causes protein aggregation in yeast. To overcome this limitation, here we investigated a CysRS from the selenium accumulator plant Astragalus bisulcatus that is reported to reject Sec in vitro Sequence analysis revealed a rare His → Asn variation adjacent to the CysRS catalytic pocket. Introducing this variation into E. coli and Saccharomyces cerevisiae CysRS increased resistance to the toxic effects of selenite and selenomethionine (SeMet), respectively. Although the CysRS variant could still use Sec as a substrate in vitro, we observed a reduction in the frequency of Sec misincorporation at Cys codons in vivo We surmise that the His → Asn variation can be introduced into any CysRS to provide a fitness advantage for strains burdened by Sec misincorporation and selenium toxicity. Our results also support the notion that the CysRS variant provides higher specificity for Cys as a mechanism for plants to grow in selenium-rich soils.

Hydrogen sulfide perturbs mitochondrial bioenergetics and triggers metabolic reprogramming in colon cells.

Unlike most other tissues, the colon epithelium is exposed to high levels of H2S derived from gut microbial metabolism. H2S is a signaling molecule that modulates various physiological effects. It is also a respiratory toxin that inhibits complex IV in the electron transfer chain (ETC). Colon epithelial cells are adapted to high environmental H2S exposure as they harbor an efficient mitochondrial H2S oxidation pathway, which is dedicated to its disposal. Herein, we report that the sulfide oxidation pathway enzymes are apically localized in human colonic crypts at the host-microbiome interface, but that the normal apical-to-crypt gradient is lost in colorectal cancer epithelium. We found that sulfide quinone oxidoreductase (SQR), which catalyzes the committing step in the mitochondrial sulfide oxidation pathway and couples to complex III, is a critical respiratory shield against H2S poisoning. H2S at concentrations ≤20 µm stimulated the oxygen consumption rate in colon epithelial cells, but, when SQR expression was ablated, H2S concentrations as low as 5 µm poisoned cells. Mitochondrial H2S oxidation altered cellular bioenergetics, inducing a reductive shift in the NAD+/NADH redox couple. The consequent electron acceptor insufficiency caused uridine and aspartate deficiency and enhanced glutamine-dependent reductive carboxylation. The metabolomic signature of this H2S-induced stress response mapped, in part, to redox-sensitive nodes in central carbon metabolism. Colorectal cancer tissues and cell lines appeared to counter the growth-restricting effects of H2S by overexpressing sulfide oxidation pathway enzymes. Our findings reveal an alternative mechanism for H2S signaling, arising from alterations in mitochondrial bioenergetics that drive metabolic reprogramming.

Optimization of Caged Electrophiles for Improved Monitoring of Cysteine Reactivity in Living Cells.

Cysteine residues play critical roles in protein function and are susceptible to numerous post-translational modifications (PTMs) that serve to modulate the activity and localization of diverse proteins. Many of these PTMs are highly transient and labile, thus necessitating methods to study these modifications directly within the context of living cells. We previously reported a caged electrophilic probe, CBK1, that can be activated by UV for temporally controlled covalent modification of cysteine residues in living cells. To improve upon the number of cysteine residues identified in cellular cysteine-profiling studies, the reactivity and uncaging efficiency of a panel of caged electrophiles were explored. We identified an optimized caged electrophilic probe, CIK4, that affords significantly improved coverage of cellular cysteine residues. The broader proteome coverage afforded by CIK4 renders it a useful tool for the biological investigation of cysteine-reactivity changes and PTMs directly within living cells and highlights design elements that are critical to optimizing photoactivatable chemical probes for cellular labeling.

Investigating the proteome reactivity and selectivity of aryl halides.

Protein-reactive electrophiles are critical to chemical proteomic applications including activity-based protein profiling, site-selective protein modification, and covalent inhibitor development. Here, we explore the protein reactivity of a panel of aryl halides that function through a nucleophilic aromatic substitution (S(N)Ar) mechanism. We show that the reactivity of these electrophiles can be finely tuned by varying the substituents on the aryl ring. We identify p-chloro- and fluoronitrobenzenes and dichlorotriazines as covalent protein modifiers at low micromolar concentrations. Interestingly, investigating the site of labeling of these electrophiles within complex proteomes identified p-chloronitrobenzene as highly cysteine selective, whereas the dichlorotriazine favored reactivity with lysines. These studies illustrate the diverse reactivity and amino-acid selectivity of aryl halides and enable the future application of this class of electrophiles in chemical proteomics.

Proteomic strategies to interrogate the FeS proteome.

Iron­sulfur (FeS) clusters, inorganic cofactors composed of iron and sulfide, participate in numerous essential redox, non-redox, structural, and regulatory biological processes within the cell. Though structurally and functionally diverse, the list of all proteins in an organism capable of binding one or more FeS clusters is referred to as its FeS proteome. Importantly, the FeS proteome is highly dynamic, with continuous cluster synthesis and delivery by complex FeS cluster biogenesis pathways. This cluster delivery is balanced out by processes that can result in loss of FeS cluster binding, such as redox state changes, iron availability, and oxygen sensitivity. Despite continued expansion of the FeS protein catalogue, it remains a challenge to reliably identify novel FeS proteins. As such, high-throughput techniques that can report on native FeS cluster binding are required to both identify new FeS proteins, as well as characterize the in vivo dynamics of FeS cluster binding. Due to the recent rapid growth in mass spectrometry, proteomics, and chemical biology, there has been a host of techniques developed that are applicable to the study of native FeS proteins. This review will detail both the current understanding of the FeS proteome and FeS cluster biology as well as describing state-of-the-art proteomic strategies for the study of FeS clusters within the context of a native proteome.

Conserved hydrogen bonding networks of MitoNEET tune Fe-S cluster binding and structural stability.

While its biological function remains unclear, the three-cysteine, one-histidine ligated human [2Fe-2S] cluster containing protein mitoNEET is of interest because of its interaction with the anti-diabetes drug pioglitazone. The mitoNEET [2Fe-2S] cluster demonstrates proton-coupled electron transfer (PCET) and marked cluster instability, which have both been linked to the single His ligand. Highly conserved hydrogen bonding networks, which include the His-87 ligand, exist around the [2Fe-2S] cluster. Through a series of site-directed mutations, PCET of the cluster has been examined, demonstrating that multiple sites of protonation exist in addition to the His ligand, which can influence redox potential. The mutations also demonstrate that while replacement of the His ligand with cysteine results in a stable cluster, the removal of Lys-55 also greatly stabilizes the cluster. We have also noted for the first time that the oxidation state of the cluster controls stability: the reduced cluster is stable, while the oxidized one is much more labile. Finally, it is shown that upon cluster loss the mitoNEET protein structure becomes less stable, while upon in vitro reconstitution, both the cluster and the secondary structure are recovered. Recently, two other proteins have been identified with a three-Cys(sulfur), one-His motif, IscR and Grx3/4-Fra2, both of which are sensors of iron and redox homeostatsis. These results lead to a model in which mitoNEET could sense the cellular oxidation state and proton concentration and respond through cluster loss and unfolding.

Chemoproteomics Reveals Disruption of Metal Homeostasis and Metalloproteins by the Antibiotic Holomycin.

The natural product holomycin contains a unique cyclic ene-disulfide and exhibits broad-spectrum antimicrobial activities. Reduced holomycin chelates metal ions with a high affinity and disrupts metal homeostasis in the cell. To identify cellular metalloproteins inhibited by holomycin, reactive-cysteine profiling was performed using isotopic tandem orthogonal proteolysis-activity-based protein profiling (isoTOP-ABPP). This chemoproteomic analysis demonstrated that holomycin treatment increases the reactivity of metal-coordinating cysteine residues in several zinc-dependent and iron-sulfur cluster-dependent enzymes, including carbonic anhydrase II and fumarase A. We validated that holomycin inhibits fumarase A activity in bacterial cells and diminishes the presence of iron-sulfur clusters in fumarase A. Whole-proteome abundance analysis revealed that holomycin treatment induces zinc and iron starvation and cellular stress. This study suggests that holomycin inhibits bacterial growth by impairing the functions of multiple metalloenzymes and sets the stage for investigating the impact of metal-binding molecules on metalloproteomes by using chemoproteomics.

Chemoproteomic interrogation of selenocysteine by low-pH isoTOP-ABPP.

Selenoproteins comprise a small group of selenocysteine (Sec) containing proteins, often involved in redox homeostasis. While Sec is functionally similar to cysteine (Cys), with both acting as protein-centered nucleophiles, chemoproteomic strategies employing electrophilic probes have often failed to rigorously identify Sec residues, due to their relatively low abundance with respect to Cys across a proteome. To improve the enrichment and detection of selenoproteins, herein we describe a chemoproteomic strategy that relies on the unique properties of Sec as compared to Cys, such as reduced pKa and the unique isotopic distribution of selenium. Low pH electrophilic probe labeling of mouse proteomes reduces Cys reactivity, resulting in increased identification of most soluble selenoproteins. This quantitative chemoproteomic platform provides a method to reliably measure changes in selenoprotein abundance across growth conditions as well as quantify inhibition by selenoprotein specific inhibitors, such as Auranofin.

Conditional Covalent Lethality Driven by Oncometabolite Accumulation.

Hereditary leiomyomatosis and renal cell carcinoma (HLRCC) is a cancer predisposition syndrome driven by mutation of the tumor suppressor fumarate hydratase (FH). Inactivation of FH causes accumulation of the electrophilic oncometabolite fumarate. In the absence of methods for reactivation, tumor suppressors can be targeted via identification of synthetic lethal interactions using genetic screens. Inspired by recent advances in chemoproteomic target identification, here, we test the hypothesis that the electrophilicity of the HLRCC metabolome may produce unique susceptibilities to covalent small molecules, a phenomenon we term conditional covalent lethality. Screening a panel of chemically diverse electrophiles, we identified a covalent ligand, MP-1, that exhibits FH-dependent cytotoxicity. Synthesis and structure-activity profiling identified key molecular determinants underlying the molecule's effects. Chemoproteomic profiling of cysteine reactivity together with clickable probes validated the ability of MP-1 to engage an array of functional cysteines, including one lying in the Zn-finger domain of the tRNA methyltransferase enzyme TRMT1. TRMT1 overexpression rescues tRNA methylation from inhibition by MP-1 and partially attenuates the covalent ligand's cytotoxicity. Our studies highlight the potential for covalent metabolites and small molecules to synergistically produce novel synthetic lethal interactions and raise the possibility of applying phenotypic screening with chemoproteomic target identification to identify new functional oncometabolite targets.

Redox characterization of the FeS protein MitoNEET and impact of thiazolidinedione drug binding.

MitoNEET is a small mitochondrial protein that has been identified recently as a target for the thiazolidinedione (TZD) class of diabetes drugs. MitoNEET also binds a unique three-Cys- and one-His-ligated [corrected] [2Fe-2S] cluster. Here we use protein film voltammetry (PFV) as a means to probe the redox properties of mitoNEET and demonstrate the direct impact of TZD drug binding upon the redox chemistry of the FeS cluster. When TZDs bind, the midpoint potential at pH 7 is lowered by more than 100 mV, shifting from approximately 0 to -100 mV. In contrast, a His87Cys mutant negates the ability of TZDs to affect the midpoint potential, suggesting a model of drug binding in which His87 is critical to communication with the FeS center of mitoNEET.

Interrogation of Functional Mitochondrial Cysteine Residues by Quantitative Mass Spectrometry.

Mitochondria are cellular sites of diverse redox biology, including ROS production, iron-sulfur biogenesis, and secondary metabolism, which all rely on proteogenic reactive cysteine residues. Mass spectrometry-based proteomic methods to monitor the reactivity and functionality of cysteine residues across complex proteomes have greatly expanded over the past decade. Here we describe a mitochondrial isolation procedure coupled with cysteine-reactive IA labeling that affords identification and characterization of functional mitochondrial cysteine residues that were heretofore inaccessible to whole-cell proteomic analysis.

Cysteine reactivity across the subcellular universe.

Cysteine residues are concentrated at key functional sites within proteins, performing diverse roles in metal binding, catalysis, and redox chemistry. Chemoproteomic platforms to interrogate the reactive cysteinome have developed significantly over the past 10 years, resulting in a greater understanding of cysteine functionality, modification, and druggability. Recently, chemoproteomic methods to examine reactive cysteine residues from specific subcellular organelles have provided significantly improved proteome coverage and highlights the unique functionalities of cysteine residues mediated by cellular localization. Here, the diverse physicochemical properties of the mammalian subcellular organelles are explored in the context of their effects on cysteine reactivity. The unique functions of cysteine residues found in the mitochondria and endoplasmic reticulum are highlighted, together with an overview into chemoproteomic platforms employed to investigate cysteine reactivity in subcellular organelles.

A Quantitative Chemoproteomic Platform to Monitor Selenocysteine Reactivity within a Complex Proteome.

Mammalian selenocysteine (Sec)-containing proteins, selenoproteins, are important to (patho)physiological processes, including redox homeostasis. Sec residues have been recalcitrant to mass spectrometry-based chemoproteomic methods that enrich for reactive cysteine (Cys) residues with electrophilic chemical probes, despite confirmed reactivity of Sec with these electrophiles. Highly abundant Cys peptides likely suppress low-abundant Sec peptides. By exploiting the decreased pKa of Sec relative to Cys, we have developed a chemoproteomic platform that relies on low pH (pH 5.75) electrophile labeling, reducing Cys reactivity and enhancing identification of Sec-containing peptides across mouse tissues and cell lines. The utility of this Sec-profiling platform is underscored by evaluation of the selectivity of auranofin, an inhibitor of the selenoprotein, thioredoxin reductase, against both reactive Cys- and Sec-containing proteins. Platform limitations pertain to the non-physiological low-pH conditions that could perturb protein structure and function. Future work necessitates the discovery of Sec-selective electrophiles that function at physiological pH.

Selenium-Encoded Isotopic Signature Targeted Profiling.

Selenium (Se), as an essential trace element, plays crucial roles in many organisms including humans. The biological functions of selenium are mainly mediated by selenoproteins, a unique class of selenium-containing proteins in which selenium is inserted in the form of selenocysteine. Due to their low abundance and uneven tissue distribution, detection of selenoproteins within proteomes is very challenging, and therefore functional studies of these proteins are limited. In this study, we developed a computational method, named as selenium-encoded isotopic signature targeted profiling (SESTAR), which utilizes the distinct natural isotopic distribution of selenium to assist detection of trace selenium-containing signals from shotgun-proteomic data. SESTAR can detect femtomole quantities of synthetic selenopeptides in a benchmark test and dramatically improved detection of native selenoproteins from tissue proteomes in a targeted profiling mode. By applying SESTAR to screen publicly available datasets from Human Proteome Map, we provide a comprehensive picture of selenoprotein distributions in human primary hematopoietic cells and tissues. We further demonstrated that SESTAR can aid chemical-proteomic strategies to identify additional selenoprotein targets of RSL3, a canonical inducer of cell ferroptosis. We believe SESTAR not only serves as a powerful tool for global profiling of native selenoproteomes, but can also work seamlessly with chemical-proteomic profiling strategies to enhance identification of target proteins, post-translational modifications, or protein-protein interactions.