Bioorthogonal chemical labeling of endogenous neurotransmitter receptors in living mouse brains.

Neurotransmitter receptors are essential components of synapses for communication between neurons in the brain. Because the spatiotemporal expression profiles and dynamics of neurotransmitter receptors involved in many functions are delicately governed in the brain, in vivo research tools with high spatiotemporal resolution for receptors in intact brains are highly desirable. Covalent labeling by chemical reaction (chemical labeling) of proteins without genetic manipulation is now a powerful method for analyzing receptors in vitro. However, selective target receptor labeling in the brain has not yet been achieved. This study shows that ligand-directed alkoxyacylimidazole (LDAI) chemistry can be used to selectively tether synthetic probes to target endogenous receptors in living mouse brains. The reactive LDAI reagents with negative charges were found to diffuse well over the whole brain and could selectively label target endogenous receptors, including AMPAR, NMDAR, mGlu1, and GABAAR. This simple and robust labeling protocol was then used for various applications: three-dimensional spatial mapping of endogenous receptors in the brains of healthy and disease-model mice; multi-color receptor imaging; and pulse-chase analysis of the receptor dynamics in postnatal mouse brains. Here, results demonstrated that bioorthogonal receptor modification in living animal brains may provide innovative molecular tools that contribute to the in-depth understanding of complicated brain functions.

Photoproximity labeling of endogenous receptors in the live mouse brain in minutes.

Understanding how protein-protein interaction networks in the brain give rise to cognitive functions necessitates their characterization in live animals. However, tools available for this purpose require potentially disruptive genetic modifications and lack the temporal resolution necessary to track rapid changes in vivo. Here we leverage affinity-based targeting and photocatalyzed singlet oxygen generation to identify neurotransmitter receptor-proximal proteins in the live mouse brain using only small-molecule reagents and minutes of photoirradiation. Our photooxidation-driven proximity labeling for proteome identification (named PhoxID) method not only recapitulated the known interactomes of three endogenous neurotransmitter receptors (α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR), inhibitory γ-aminobutyric acid type A receptor and ionotropic glutamate receptor delta-2) but also uncovered age-dependent shifts, identifying NECTIN3 and IGSF3 as developmentally regulated AMPAR-proximal proteins in the cerebellum. Overall, this work establishes a flexible and generalizable platform to study receptor microenvironments in genetically intact specimens with an unprecedented temporal resolution.

Lysine-Reactive N-Acyl-N-aryl Sulfonamide Warheads: Improved Reaction Properties and Application in the Covalent Inhibition of an Ibrutinib-Resistant BTK Mutant.

The covalent inhibition of a target protein has gained widespread attention in the field of drug discovery. Most of the current covalent drugs utilize the high reactivity of cysteines toward modest electrophiles. However, there is a growing need for warheads that can target lysine residues to expand the range of covalently druggable proteins and to deal with emerging proteins with mutations resistant to cysteine-targeted covalent drugs. We have recently developed an N-acyl-N-alkyl sulfonamide (NASA) as a lysine-targeted electrophile. Despite its successful application, this NASA warhead suffered from instability in physiological environments, such as serum-containing medium, because of its high intrinsic reactivity. In this study, we sought to modify the structure of the NASA warhead and found that N-acyl-N-aryl sulfonamides (ArNASAs) are promising electrophiles for use in a lysine-targeted covalent inhibition strategy. We prepared a focused library of ArNASA derivatives with diverse structures and reactivity and identified several warhead candidates with suppressed hydrolysis-mediated inactivation and reduced nonspecific reactions with off-target proteins, without sacrificing the reactivity toward the target. These reaction properties enabled the improved covalent inhibition of intracellular heat shock protein 90 (HSP90) in the presence of serum and the development of the first irreversible inhibitor for ibrutinib-resistant Bruton's tyrosine kinase (BTK) bearing the C481S mutation. This study clearly demonstrated the use of a set of ArNASA warheads to create highly potent covalent drugs and highlighted the importance of enriching the current arsenal of lysine-reactive warheads.

Organelle membrane-specific chemical labeling and dynamic imaging in living cells.

Lipids play crucial roles as structural elements, signaling molecules and material transporters in cells. However, the functions and dynamics of lipids within cells remain unclear because of a lack of methods to selectively label lipids in specific organelles and trace their movement by live-cell imaging. We describe here a technology for the selective labeling and fluorescence imaging (microscopic or nanoscopic) of phosphatidylcholine in target organelles. This approach involves the metabolic incorporation of azido-choline, followed by a spatially limited bioorthogonal reaction that enables the visualization and quantitative analysis of interorganelle lipid transport in live cells. More importantly, with live-cell imaging, we obtained direct evidence that the autophagosomal membrane originates from the endoplasmic reticulum. This method is simple and robust and is thus powerful for real-time tracing of interorganelle lipid trafficking.

Enhanced Suppression of a Protein-Protein Interaction in Cells Using Small-Molecule Covalent Inhibitors Based on an N-Acyl-N-alkyl Sulfonamide Warhead.

Protein-protein interactions (PPIs) intimately govern various biological processes and disease states and therefore have been identified as attractive therapeutic targets for small-molecule drug discovery. However, the development of highly potent inhibitors for PPIs has proven to be extremely challenging with limited clinical success stories. Herein, we report irreversible inhibitors of the human double minute 2 (HDM2)/p53 PPI, which employ a reactive N-acyl-N-alkyl sulfonamide (NASA) group as a warhead. Mass-based analysis successfully revealed the kinetics of covalent inhibition and the modification sites on HDM2 to be the N-terminal α-amine and Tyr67, both rarely seen in traditional covalent inhibitors. Finally, we demonstrated prolonged p53-pathway activation and more effective induction of the p53-mediated cell death in comparison to a noncovalent inhibitor. This study highlights the potential of the NASA warhead as a versatile electrophile for the covalent inhibition of PPIs and opens new avenues for the rational design of potent covalent PPI inhibitors.

Y chromosome analysis for common surnames in the Japanese male population.

For many years of Japan's long history, Japanese surnames have been handed down patrilineally. This study investigated relations between major surnames and Y chromosomal polymorphism among the Japanese male population. To analyze genetic phylogeny in namesakes, the Y-single nucleotide polymorphism (SNP) plus Y-short tandem repeat (STR) approach was employed. A haplogroup based on SNPs and haplotypes at 17 STR loci were typed in 567 unrelated volunteers recruited in Kanagawa, Japan. Samples covered 27 common surnames such as Satoh and Suzuki, each name having 10-55 bearers. Significant difference was found for SNP haplogroup compositions and a multidimensional scaling plot using STR haplotypes in several surname groups. By contrast, these common surnames displayed wide diversity with phylogenetic networks, suggesting that no genetic drift event has occurred in their history. In all, 22 descent clusters were found, as judgcriteria ed by ad hoc of groups within five mutational steps in the 15 STR loci with the same haplogroup. The times of the most recent common ancestor ranged from 279 to over 2577 years. According to the approximate millennium span of Japanese surname history, descent criteria are expected to be reasonable for grouping within four step-neighbors. High heterogeneity of common surnames resembles that observed for England and Spain, but not for Ireland. Our results highlight that common Japanese surnames consist of descent clusters and many singletons, reflecting a mixture of long-term bearers and short-term bearers among the population. The genetic study of this population revealed characteristic features of Japanese surnames.

Selective and reversible modification of kinase cysteines with chlorofluoroacetamides.

Irreversible inhibition of disease-associated proteins with small molecules is a powerful approach for achieving increased and sustained pharmacological potency. Here, we introduce α-chlorofluoroacetamide (CFA) as a novel warhead of targeted covalent inhibitor (TCI). Despite weak intrinsic reactivity, CFA-appended quinazoline showed high reactivity toward Cys797 of epidermal growth factor receptor (EGFR). In cells, CFA-quinazoline showed higher target specificity for EGFR than the corresponding Michael acceptors in a wide concentration range (0.1-10 µM). The cysteine adduct of the CFA derivative was susceptible to hydrolysis and reversibly yielded intact thiol but was stable in solvent-sequestered ATP-binding pocket of EGFR. This environment-dependent hydrolysis can potentially reduce off-target protein modification by CFA-based drugs. Oral administration of CFA quinazoline NS-062 significantly suppressed tumor growth in a mouse xenograft model. Further, CFA-appended pyrazolopyrimidine irreversibly inhibited Bruton's tyrosine kinase with higher target specificity. These results demonstrate the utility of CFA as a new class warheads for TCI.

Site-specific covalent labeling of His-tag fused proteins with N-acyl-N-alkyl sulfonamide reagent.

The ability to incorporate a desired functionality into proteins of interest in a site-specific manner can provide powerful tools for investigating biological systems and creating therapeutic conjugates. However, there are not any universal methods that can be applied to all proteins, and it is thus important to explore the chemical strategy for protein modification. In this paper, we developed a new reactive peptide tag/probe pair system for site-specific covalent protein labeling. This method relies on the recognition-driven reaction of a peptide tag and a molecular probe, which comprises the lysine-containing short histidine tag (KH6 or H6K) and a binuclear nickel (II)- nitrilotriacetic acid (Ni2+-NTA) complex probe containing a lysine-reactive N-acyl-N-alkyl sulfonamide (NASA) group. The selective interaction of the His-tag and Ni2+-NTA propeles a rapid nucleophilic reaction between a lysine residue of the tag and the electrophilic NASA group of the probe by the proximity effect, resulting in the tag-site-specific functionalization of proteins. We characterized the reactive profile and site-specificity of this method using model peptides and proteins in vitro, and demonstrated the general utility for production of a nanobody-chemical probe conjugate without compromising its binding ability.

Development of a Cell-Based Ligand-Screening System for Identifying Hsp90 Inhibitors.

Because of its critical roles in regulating cellular signal transduction, the molecular chaperone heat-shock protein 90 (Hsp90) has become a novel therapeutic target for various diseases, including cancer, inflammation, and neurological diseases. However, the lack of methods that allow us to directly evaluate the binding of small molecule ligands to intracellular Hsp90 makes the inhibitor development more difficult. Here, we report a simple cell-based assay system for the Hsp90 inhibitor in live-cell environments. In this strategy, the binding activity of ligands of interest is evaluated by competitive inhibition of ligand-directed N-acyl-N-alkyl sulfonamide (LDNASA) chemistry-mediated Hsp90 labeling. Using several known Hsp90 inhibitors, we demonstrated that our method could easily detect the ligand-binding event of Hsp90 in live cells. Our system is applicable to high-throughput ligand screening, and we discovered a new small molecule candidate that binds to the N-terminal ATP binding domain of Hsp90. These results demonstrate the use of the competitive LDNASA-based approach to directly evaluate ligand activity in live cells and identify potent drug candidates from chemical libraries.

Imaging and Profiling of Proteins under Oxidative Conditions in Cells and Tissues by Hydrogen-Peroxide-Responsive Labeling.

Reactive oxygen species (ROS) such as hydrogen peroxide (H2O2) can inflict damage to biomolecules under oxidative stress and also act as signaling molecules at physiological levels. Here we developed a unique chemical tool to elucidate the biological roles of ROS using both fluorescence imaging and conditional proteomics. H2O2-responsive protein labeling reagents (Hyp-L) were designed to selectively tag proteins under the oxidative conditions in living cells and tissues. The Hyp-L signal remained even after sample fixation, which was compatible with conventional immunostaining. Moreover, Hyp-L allowed proteomic profiling of the labeled proteins using a conditional proteomics workflow. The integrative analysis enabled the identification of ROS generation and/or accumulation sites with a subcellular resolution. For the first time, we characterized that autophagosomes were enriched with H2O2 in activated macrophages. Hyp-L was further applied to mouse brain tissues and clearly revealed oxidative stress within mitochondria by the conditional proteomics.

Chemistry for Covalent Modification of Endogenous/Native Proteins: From Test Tubes to Complex Biological Systems.

Chemical modification of proteins provides powerful tools to realize a broad range of exciting biological applications, including the development of new classes of biopharmaceuticals and functional studies of individual proteins in complex biological systems. Numerous strategies for linking desired chemical probes with target proteins have been developed in the last two decades, with most exploiting genetic protein engineering and/or bio-orthogonal chemistry that utilizes unnatural amino acids incorporated into proteins. Modification of native proteins in test tubes and biological contexts by site-specific and target-selective approaches remains challenging because appropriate organic chemistry to carry out such modifications is currently limited. Nonetheless, a variety of promising strategies have appeared recently that address this grand challenge in chemical biology. These new chemistries yield native protein-based well-defined bioconjugations, specific labeling of endogenous proteins in various biological crude milieus, and the establishment of chemical proteomics as a new research area in protein science. In this Perspective, we focus on recent remarkable progress in chemistry for native protein modification. We survey chemical characteristics of the methods and describe briefly these advanced applications to address unsolved biological issues. Current limitations and future directions of this research field are also discussed.

Chemical Profiling of the Endoplasmic Reticulum Proteome Using Designer Labeling Reagents.

The endoplasmic reticulum (ER) is an organelle that performs a variety of essential cellular functions via interactions with other organelles. Despite its important role, chemical tools for profiling the composition and dynamics of ER proteins remain very limited because of the labile nature of these proteins. Here, we developed ER-localizable reactive molecules (called ERMs) as tools for ER-focused chemical proteomics. ERMs can spontaneously localize in the ER of living cells and selectively label ER-associated proteins with a combined affinity and imaging tag, enabling tag-mediated ER protein enrichment and identification with liquid chromatography tandem mass spectrometry (LC-MS/MS). Using this method, we performed proteomic analysis of the ER of HeLa cells and newly assigned three proteins, namely, PAICS, TXNL1, and PPIA, as ER-associated proteins. The ERM probes could be used simultaneously with the nucleus- and mitochondria-localizable reactive molecules previously developed by our group, which enabled orthogonal organellar chemoproteomics in a single biological sample. Moreover, quantitative analysis of the dynamic changes in ER-associated proteins in response to tunicamycin-induced ER stress was performed by combining ER-specific labeling with SILAC (stable isotope labeling by amino acids in cell culture)-based quantitative MS technology. Our results demonstrated that ERM-based chemical proteomics provides a powerful tool for labeling and profiling ER-related proteins in living cells.

Affinity-Guided Oxime Chemistry for Selective Protein Acylation in Live Tissue Systems.

Catalyst-mediated protein modification is a powerful approach for the imaging and engineering of natural proteins. We have previously developed affinity-guided 4-dimethylaminopyridine (AGD) chemistry as an efficient protein modification method using a catalytic acyl transfer reaction. However, because of the high electrophilicity of the thioester acyl donor molecule, AGD chemistry suffers from nonspecific reactions to proteins other than the target protein in crude biological environments, such as cell lysates, live cells, and tissue samples. To overcome this shortcoming, we here report a new acyl donor/organocatalyst system that allows more specific and efficient protein modification. In this method, a highly nucleophilic pyridinium oxime (PyOx) catalyst is conjugated to a ligand specific to the target protein. The ligand-tethered PyOx selectively binds to the target protein and facilitates the acyl transfer reaction of a mild electrophilic N-acyl-N-alkylsulfonamide acyl donor on the protein surface. We demonstrated that the new catalytic system, called AGOX (affinity-guided oxime) chemistry, can modify target proteins, both in test tubes and cell lysates, more selectively and efficiently than AGD chemistry. Low-background fluorescence labeling of the endogenous cell-membrane proteins, carbonic anhydrase XII and the folate receptor, in live cells allowed for the precise quantification of diffusion coefficients in the protein's native environment. Furthermore, the excellent biocompatibility and bioorthogonality of AGOX chemistry were demonstrated by the selective labeling of an endogenous neurotransmitter receptor in mouse brain slices, which are highly complicated tissue samples.

Combined effects of multiple linked loci on pairwise sibling tests.

The advanced multiplex STR system, PowerPlex Fusion, includes four linked locus pairs. The conventional Identifiler system has one pair of linked loci. Therefore, sibling tests conducted using the advanced system might be more affected by linkage than those conducted using the conventional system. This study simulated single and combined effects of the four linked locus pairs on pairwise sibling tests. Simulated genotypes of 100,000 pairs of full siblings and nonrelatives were constructed according to allele frequencies of the Japanese population. The single linkage effect was evaluated for simulated genotype data by calculating both the likelihood ratio accounting for the linkage between two loci and the likelihood ratio ignoring the linkage. The combined effect was obtained by multiplication of the respective single effects. Furthermore, we investigated the possibility that ignoring the linkage affects subject classification by introducing a scale of the likelihood ratio into sibling tests. The single effect in the Identifiler analysis was 0.645-1.746 times if the linkage was ignored. Overestimations and underestimations were predictable from the identical-by-state status at two linked loci. The combined effect in the PowerPlex Fusion analysis was 0.217-7.390 times. Ignoring the linkage rarely caused a false conclusive or inconclusive result, even from PowerPlex Fusion analysis. Application of the advanced system improved sibling tests considerably. The additional examined loci were more beneficial than the adverse effect of the linkage derived from the four linked locus pairs.

A Set of Organelle-Localizable Reactive Molecules for Mitochondrial Chemical Proteomics in Living Cells and Brain Tissues.

Protein functions are tightly regulated by their subcellular localization in live cells, and quantitative evaluation of dynamically altered proteomes in each organelle should provide valuable information. Here, we describe a novel method for organelle-focused chemical proteomics using spatially limited reactions. In this work, mitochondria-localizable reactive molecules (MRMs) were designed that penetrate biomembranes and spontaneously concentrate in mitochondria, where protein labeling is facilitated by the condensation effect. The combination of this selective labeling and liquid chromatography-mass spectrometry (LC-MS) based proteomics technology facilitated identification of mitochondrial proteomes and the profile of the intrinsic reactivity of amino acids tethered to proteins expressed in live cultured cells, primary neurons and brain slices. Furthermore, quantitative profiling of mitochondrial proteins whose expression levels change significantly during an oxidant-induced apoptotic process was performed by combination of this MRMs-based method with a standard quantitative MS technique (SILAC: stable isotope labeling by amino acids in cell culture). The use of a set of MRMs represents a powerful tool for chemical proteomics to elucidate mitochondria-associated biological events and diseases.

Analysis of Cell-Surface Receptor Dynamics through Covalent Labeling by Catalyst-Tethered Antibody.

A general technique for introducing biophysical probes into selected receptors in their native environment is valuable for the study of their structure, dynamics, function, and molecular interactions. A number of such techniques rely on genetic engineering, which is not applicable for the study of endogenous proteins, and such approaches often suffer from artifacts due to the overexpression and bulky size of the probes/protein tags used. Here we designed novel catalyst-antibody conjugates capable of introducing small chemical probes into receptor proteins such as epidermal growth factor receptor (EGFR) and human epidermal growth factor receptor 2 (HER2) in a selective manner on the surface of living cells. Because of the selectivity and efficiency of this labeling technique, we were able to monitor the cellular dynamics and lifetime of HER2 endogenously expressed on cancer cells. More significantly, the current labeling technique comprises a stable covalent bond, which combined with a peptide mass fingerprinting analysis allowed epitope mapping of antibodies on living cells and identification of potential binding sites of anti-EGFR affibody. Although as yet unreported in the literature, the binding sites predicted by our labeling method were consistently supported by the subsequent mutation and binding assay experiments. In addition, this covalent labeling method provided experimental evidence that HER2 exhibits a more dynamic structure than expected on the basis of crystallographic analysis alone. Our novel catalyst-antibody conjugates are expected to provide a general tool for investigating the protein trafficking, fluctuation, and molecular interactions of an important class of cell-surface receptors on live cell surfaces.

Protein-Labeling Reagents Selectively Activated by Copper(I).

Copper is an essential trace element that participates in many biological processes through its unique redox cycling between cuprous (Cu+) and cupric (Cu2+) oxidation states. To elucidate the biological functions of copper, chemical biology tools that enable selective visualization and detection of copper ions and proteins in copper-rich environments are required. Herein, we describe the design of Cu+-responsive reagents based on a conditional protein labeling strategy. Upon binding Cu+, the probes generated quinone methide via oxidative bond cleavage, which allowed covalent labeling of surrounding proteins with high Cu+ selectivity. Using gel- and imaging-based analyses, the best-performing probe successfully detected changes in the concentration of labile Cu+ in living cells. Moreover, conditional proteomics analysis suggested intramitochondrial Cu+ accumulation in cells undergoing cuproptosis. Our results highlight the power of Cu+-responsive protein labeling in providing insights into the molecular mechanisms of Cu+ metabolism and homeostasis.

Fluorophore labeling of native FKBP12 by ligand-directed tosyl chemistry allows detection of its molecular interactions in vitro and in living cells.

Introducing synthetic fluorophores into specific endogenous proteins and analyzing their function in living cells are a great challenge in chemical biology. Toward this end, we demonstrate the target-selective and site-specific fluorescent labeling of native FKBP12 (FK506-binding protein 12) in vitro and in living cells using ligand-directed tosyl (LDT) chemistry. The LDT-mediated labeling yielded a semisynthetic FKBP12 containing the Oregon green (OG) dye near the catalytic pocket. The OG-labeled FKBP12 (OG-FKBP12) acted as a fluorescent reporter that allows monitoring of its interaction with rapamycin and FRB (FKBP-rapamycin-binding domain) in vitro. We also successfully demonstrated the visualization of the rapamycin-mediated complexation of the OG-FKBP12 and FRB inside of living cells by the combined use with fluorescent protein-tag technology and Förster resonance energy-transfer imaging.

Semisynthetic lectin-4-dimethylaminopyridine conjugates for labeling and profiling glycoproteins on live cell surfaces.

Glycoproteins on cell surfaces play important roles in biological processes, including cell-cell interaction/signaling, immune response, and cell differentiation. Given the diversity of the structure of glycans, labeling and imaging of selected glycoproteins are challenging, although several promising strategies have been developed recently. Here, we design and construct semisynthetic reactive lectins (sugar-binding proteins) that are able to selectively label glycoproteins. Congerin II, an animal galectin, and wheat germ agglutinin are conjugated with 4-dimethylaminopyridine (DMAP), a well-known acyl transfer catalyst by our affinity-guided DMAP method and Cu(I)-assisted click chemistry. Selective labeling of glycoproteins is facilitated by the DMAP-tethered lectin catalysts both in vitro and on living cells. Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) analysis enabled us to isolate labeled glycoproteins that are uniquely exposed on distinct cell lines. Furthermore, the combination of immunoprecipitation with mass spectrometry (MS)-fingerprinting techniques allowed us to characterize 48 glycoproteins endogenously expressed on HeLa cells, and some low-abundant glycoproteins, such as epidermal growth factor receptor (EGFR) and neuropilin-1, were successfully identified. Our results demonstrate that semisynthetic DMAP-tethered lectins provide a new tool for labeling and profiling glycoproteins on living cells.

Quantitative Analysis of the Endoplasmic Reticulum-Associated Proteins Using ER-Localizable Reactive Molecules.

The endoplasmic reticulum (ER) is an essential organelle responsible for many cellular functions, including protein synthesis and folding, lipid synthesis, membrane trafficking, and storage of Ca2+. Therefore, global profiling of ER-associated proteins should be invaluable for understanding these biological processes. However, the difficulty of isolating the intact ER hampered proteome-wide analysis of ER proteins. This chapter describes a chemoproteomic approach for ER proteome analysis using ER-localizable reactive molecules (ERMs), which need neither ER fractionation nor genetic transformation. ERMs spontaneously accumulate in the ER of live cells, and the resultant high concentration of ERMs facilitates spatially limited chemical modification of ER-localized proteins with a detection/purification tag via simple intermolecular reactions. This enables the tag-mediated enrichment and quantitative analysis of the ER-associated proteins using liquid chromatography-tandem mass spectrometry (LC-MS/MS) coupled with SILAC technology.