Activity-based Protein Profiling Research Articles

Profiling Cysteine Proteases Activities in Neuroinflammatory Cells.

A new activity-based probe (ABP) of cysteine proteases (FGA139) has been designed and synthesized. The design of the ABP has been done based upon the chemical structure of an irreversible inhibitor of cysteine proteases by attaching a bodipy fluorophore at the N-terminus of the peptide backbone. The synthetic route of the probe has a metathesis and a "click" reaction as key steps. Although some studies have been reported about the role played by cysteine proteases in neurodegenerative diseases, there are not definitive conclusions. The obtained ABP has been employed as a chemical tool to profile activities of cysteine proteases cathepsins B, L, and calpain in neurodegenerative cell models through confocal imaging. Colocalization of the probe to specific antibodies of the proteases and competitive experiments with non-fluorescent inhibitors confirm the specificity of the ABP. From a theranostic perspective, our findings strongly suggest that FGA139 exhibits a protective role in various cell lines against oxidative stress or pro-inflammatory toxicity and it effectively attenuates macrophage activation triggered by LPS.

Previously Published Phosphatase Probes have Limited Utility Due to their Unspecific Reactivity.

This study explores the use of activity-based protein profiling to study protein tyrosine phosphatases. With the discovery of allosteric SHP2 inhibitors, this enzyme family has resurfaced as interesting drug targets. Therefore, we envisioned that previously described direct electrophiles and quinone methide-based traps targeting phosphatases could be applied in competitive activity-based protein profiling assays. This study evaluates three direct electrophiles, specifically, a vinyl sulfonate, a vinyl sulfone, and an α-bromobenzylphosphonate as well as three quinone methide-based traps as activity-based probes. For all these moieties it was previously shown that they could selectively engage in assays with purified or overexpressed phosphatases in bacterial lysates. However, this study demonstrates that probes based on these moieties all suffer from unspecific labelling. Direct electrophiles were either unspecific or not activity-based, while quinone methide-based traps showed dependence on phosphatase activity but also resulted in unspecific labelling due to diffusion after activation. This phenomenon, termed 'bystander' labelling, occurred even with catalytically inactive SHP2 mutants. We concluded that alternative strategies or chemistries are needed to apply activity-based protein profiling in phosphatase research. Moreover, this study shows that quinone methide-based designs have limited potential in probe and inhibitor development strategies due to their intrinsic reactivity.

Identification of Aberrant Expression of Gemcitabine-Targeting Proteins in Drug-Resistant Cells Using an Activity-Based Gemcitabine Probe.

Gemcitabine-based monotherapy or combination therapy has become the standard treatment for locally advanced and metastatic pancreatic cancer. However, the emergence of resistance within weeks of treatment severely compromises therapeutic efficacy. The intricate biological process of gemcitabine resistance in pancreatic cancer presents a complex challenge, as the underlying mechanisms remain unclear. Identifying the target protein of gemcitabine is crucial for studying its drug-resistance mechanism. An activity-based probe is a powerful tool for studying drug target proteins, but the current lack of activity-based gemcitabine probes with robust biological activity hinders research on gemcitabine. In this study, we developed three active probes based on gemcitabine, among which Gem-3 demonstrated excellent stability and labeling efficacy. We utilized Gem-3 in conjunction with chemical proteomics to identify intracellular target proteins. We identified 79 proteins that interact with gemcitabine, most of which were previously unknown and represented various functional classes. Additionally, we validated the increased expression of IFIT3 and MARCKS in drug-resistant cells, along with the activation of the NF-κB signaling pathway. These findings substantially contribute to our comprehension of gemcitabine's target proteins and further our understanding of the mechanisms driving gemcitabine resistance in pancreatic cancer cells.

CG17192 is a Phospholipase That Regulates Signaling Lipids in the Drosophila Gut upon Infection.

The chemoproteomics technique, activity-based protein profiling (ABPP), has proven to be an invaluable tool in assigning functions to enzymes. The serine hydrolase (SH) enzyme superfamily, in particular, has served as an excellent example in displaying the versatility of various ABPP platforms and has resulted in a comprehensive cataloging of the biochemical activities associated within this superfamily. Besides SHs, in mammals, several other enzyme classes have been thoroughly investigated using ABPP platforms. However, the utility of ABPP platforms in fly models remains underexplored. Realizing this knowledge gap, leveraging complementary ABPP platforms, we reported the full array of SH activities during various developmental stages and adult tissues in the fruit fly (Drosophila melanogaster). Following up on this study, using ABPP, we mapped SH activities in adult fruit flies in an infection model and found that a gut-resident lipase CG17192 showed increased activity during infection. To assign a biological function to this uncharacterized lipase, we performed an untargeted lipidomics analysis and found that phosphatidylinositols were significantly elevated when CG17192 was depleted in the adult fruit fly gut. Next, we overexpressed this lipase in insect cells, and using biochemical assays, we show that CG17192 is a secreted enzyme that has phospholipase C (PLC) type activity, with phosphatidylinositol being a preferred substrate. Finally, we show during infection that heightened CG17192 regulates phosphatidylinositol levels and, by doing so, likely modulates signaling pathways in the adult fruit fly gut that might be involved in the resolution of this pathophysiological condition.

Enzyme Activity-Based Optical Probe: Imaging Aminopeptidases N in Vulnerable Plaque and Serum.

Cardiovascular disease, a chronic and progressive arterial wall disease, is increasingly recognized for its clinical significance. Aminopeptidases N (APN), crucial in the pathophysiological processes of vulnerable plaque, have been linked to endothelial dysfunction, oxidative stress, and plaque formation, thus highlighting their potential as biomarkers for disease progression. However, current detection methods for APN in body fluids and in vivo have limitations, including insufficient sensitivity and specificity, time delays, and the inability to directly reflect enzyme activity in plaques. To address these challenges, we developed an optical probe, HD-APN, for in vivo imaging of aminopeptidases, providing a potential implementation in cardiovascular disease. Our work demonstrated the applicability of HD-APN for specific monitoring of aminopeptidase levels in plaques and serum, shedding light on its potential for further research in cardiovascular disease.

Expanding the Library of Covalent Cysteine Cathepsin Probes Featuring Sulfoxonium Ylide Electrophiles.

Covalent activity-based probes are invaluable tools to monitor protease activity in vitro and in vivo. We recently discovered that dimethyl sulfoxonium ylides (SYs) bind selectively to cysteine cathepsin proteases in a mechanism-dependent manner. Herein, we present the synthetic routes and characterization of an expanded library of SY probes with a greater diversity in recognition sequences. The probes exhibit a range of potency and selectivity for the cathepsin family members. We also investigated the impact of fluorophore positioning on probes bearing P1 lysine. When sulfonated cyanine 5 was attached via the lysine side chain, the resulting probe was selective for cathepsin S. When attached to the α-amine, with the side chain amine either free or Boc-protected, the probes reacted with both cathepsin S and X. Bulk in the P1 position is thus well tolerated by cathepsin S but not cathepsin X. We examined the impact of Cy5 sulfonation on probe properties, demonstrating that unsulfonated probes exhibit greater cellular uptake, which affects their relative selectivity. Finally, we demonstrated that SY probes exhibit minimal labeling of cathepsin S in freshly prepared lysates, but this increases during the prolonged incubation of lysates. This work extends our understanding of SY probes and informs future probe development.

Chemical Proteomics Approaches for Screening Small Molecule Inhibitors Covalently Binding to SARS-Cov-2.

Although various strategies have been used to prevent and treat SARS-CoV-2, the spread and evolution of SARS-CoV-2 is still progressing rapidly. The emerging variants Omicron and its sublineage have a greater ability to spread and escape nearly all current monoclonal antibodies treatments, highlighting an urgent need to develop therapeutics targeting current and emerging Omicron variants or recombinants with breadth and potency. Here, some small molecule drugs are rapidly identified that could covalently binding to receptor binding domain (RBD) protein of Omicron through the combined application of artificial intelligence (AI) and activity-based protein profiling (ABPP) technology. The surface plasmon resonance (SPR) and pseudo-virus neutralization experiments further reveal that an FDA-approved drug gallic acid has robust neutralization potency against Omicron pseudo-virus with the IC50 values of 23.56 × 10-6 m. Taken together, a platform combining AI intelligence, biochemical, SPR, molecular docking, and pseudo-virus-based screening for rapid identification and evaluation of potential anti-SARS-CoV-2 small molecule drugs is established and the effectiveness of the platform is validated.

N-terminomics profiling of naïve and inflamed murine colon reveals proteolytic signatures of legumain.

Legumain is a cysteine protease broadly associated with inflammation. It has been reported to cleave and activate protease-activated receptor 2 to provoke pain associated with oral cancer. Outside of gastric and colon cancer, little has been reported on the roles of legumain within the gastrointestinal tract. Using a legumain-selective activity-based probe, LE28, we report that legumain is activated within colonocytes and macrophages of the murine colon, and that it is upregulated in models of acute experimental colitis. We demonstrated that loss of legumain activity in colonocytes, either through pharmacological inhibition or gene deletion, had no impact on epithelial permeability in vitro. Moreover, legumain inhibition or deletion had no obvious impacts on symptoms or histological features associated with dextran sulfate sodium-induced colitis, suggesting its proteolytic activity is dispensable for colitis initiation. To gain insight into potential functions of legumain within the colon, we performed field asymmetric waveform ion mobility spectrometry-facilitated quantitative proteomics and N-terminomics analyses on naïve and inflamed colon tissue from wild-type and legumain-deficient mice. We identified 16 altered cleavage sites with an asparaginyl endopeptidase signature that may be direct substrates of legumain and a further 16 cleavage sites that may be indirectly mediated by legumain. We also analyzed changes in protein abundance and proteolytic events broadly associated with colitis in the gut, which permitted comparison to recent analyses on mucosal biopsies from patients with inflammatory bowel disease. Collectively, these results shed light on potential functions of legumain and highlight its potential roles in the transition from inflammation to colorectal cancer.

Chemically Stable Diazo Peptides as Selective Probes of Cysteine Proteases in Living Cells.

Diazo peptides have been described earlier, however, due to their high reactivity have not been broadly used until today. Here, we report the preparation, properties, and applications of chemically stable internal diazo peptides. Peptidyl phosphoranylidene-esters and amides were found to react with triflyl azide primarily to novel 3,4-disubstituted triazolyl-peptides. Nonaflyl azide instead furnished diazo peptides, which are chemically stable from pH 1-14 as amides and from pH 1-8 as esters. Thus, diazo peptides prepared by solid phase peptide synthesis were stable to final deprotection with 95% trifluoroacetic acid. Diazo peptides with the recognition sequence of caspase-3 were identified as specific, covalent, and irreversible inhibitors of this enzyme at low nanomolar concentrations. A fluorescent diazo peptide entered living cells enabling microscopic imaging and quantification of apoptotic cells via flow cytometry. Thus, internal diazo peptides constitute a novel class of activity-based probes and enzyme inhibitors useful in chemical biology and medicinal chemistry.

Hypoxanthine ameliorates diet-induced insulin resistance by improving hepatic lipid metabolism and gluconeogenesis via AMPK/mTOR/PPARα pathway

AimInsulin resistance (IR) is a pivotal metabolic disorder associated with type 2 diabetes and metabolic syndrome. This study investigated the potential of hypoxanthine (Hx), a purine metabolite and uric acid precursor, in ameliorating IR and regulating hepatic glucose and lipid metabolism. MethodsWe utilized both in vitro IR-HepG2 cells and in vivo diet-induced IR mice to investigate the impact of Hx. The HepG2 cells were treated with Hx to evaluate its effects on glucose production and lipid deposition. Activity-based protein profiling (ABPP) was applied to identify Hx-target proteins and the underlying pathways. In vivo studies involved administration of Hx to IR mice, followed by assessments of IR-associated indices, with explores on the potential regulating mechanisms on hepatic glucose and lipid metabolism. Key findingsHx intervention significantly reduced glucose production and lipid deposition in a dose-dependent manner without affecting cell viability in IR-HepG2 cells. ABPP identified key Hx-target proteins engaged in fatty acid and pyruvate metabolism. In vivo, Hx treatment reduced IR severities, as evidenced by decreased HOMA-IR, fasting blood glucose, and serum lipid profiles. Histological assessments confirmed reduced liver lipid deposition. Mechanistic insights revealed that Hx suppresses hepatic gluconeogenesis and fatty acid synthesis, and promotes fatty acid oxidation via the AMPK/mTOR/PPARα pathway. SignificanceThis study delineates a novel role of Hx in regulating hepatic metabolism, offering a potential therapeutic strategy for IR and associated metabolic disorders. The findings provide a foundation for further investigation into the role of purine metabolites in metabolic regulation and their clinical implications.

Cathepsin B promotes Aβ proteotoxicity by modulating aging regulating mechanisms

While the activities of certain proteases promote proteostasis and prevent neurodegeneration-associated phenotypes, the protease cathepsin B (CTSB) enhances proteotoxicity in Alzheimer’s disease (AD) model mice, and its levels are elevated in brains of AD patients. How CTSB exacerbates the toxicity of the AD-causing Amyloid β (Aβ) peptide is controversial. Using an activity-based probe, aging-altering interventions and the nematode C. elegans, we discovered that the CTSB CPR-6 promotes Aβ proteotoxicity but mitigates the toxicity of polyQ stretches. While the knockdown of cpr-6 does not affect lifespan, it alleviates Aβ toxicity by reducing the expression of swsn-3 and elevating the level of the protein SMK-1, both involved in the regulation of aging. These observations unveil a mechanism by which CTSB aggravates Aβ–mediated toxicity, indicate that it plays opposing roles in the face of distinct proteotoxic insults and highlight the importance of tailoring specific remedies for distinct neurodegenerative disorders.

Activity-based protein profiling guided new target identification of quinazoline derivatives for expediting bactericide discovery: Activity-based protein profiling derived new target discovery of antibacterial quinazolines

IntroductionThe looming antibiotic-resistance problem has imposed an enormous crisis on global public health and agricultural development. Even worse, the evolution and widespread distribution of antibiotic-resistance elements in bacterial pathogens have made the resurgence of diseases that were once easily treatable deadly again. The development of antibiotics with novel mechanisms of action is urgently required. ObjectivesInspired by charming activity-based protein profiling (ABPP) technology and increasing attention to quinazolines in the development of antibacterial agents, this study engineered a series of new quinazoline derivatives, assessed their antibacterial profiles, and first identified the possible target. MethodsThe target identification and their possible binding sites were verified by ABPP technology, molecular docking, and molecular dynamic simulations. The fatty acid synthesis process was analyzed by gas chromatography, propidium iodide staining, and scanning electron microscopy. The physicochemical properties and fungicide-likeness were evaluated using the Fungicide Physicochemical-properties Analysis Database. ResultsCompound 7a, an acrylamide-functionalized quinazoline derivative, exhibited excellent antibacterial potency against Xanthomonas oryzae pv. oryzae with an EC50 value of 13.20 µM. More importantly, ABPP technology showed that β-ketoacyl-ACP-synthase Ⅱ (FabF) was the first identified quinazolines’ potential target. Compound 7a could selectively bind to the Cys151 residue of FabF through covalent interaction, suppress fatty acid biosynthesis, and damage the cell membrane integrity, thereby killing the bacteria. The pot experiment results showed that compound 7a demonstrated protective and curative values of 49.55 % and 47.46 %, surpassing controls bismerthiazol and thiodiazole copper. Finally, compound 7a exhibited low toxicity towards non-target organisms. These unprecedented performances contributed to excavating new quinazoline-based bactericidal agents. ConclusionOur research highlights the superiority of ABPP technology, for the first time, identifies the target of engineered quinazolines in pathogenic bacteria, and their potential target fished by ABPP tools holds great promise for the development of quinazoline-based and/or FabF-targeted bactericides.

Development and Application of Reversible and Irreversible Covalent Probes for Human and Mouse Cathepsin-K Activity Detection, Revealing Nuclear Activity.

Cathepsin-K (CTSK) is an osteoclast-secreted cysteine protease that efficiently cleaves extracellular matrices and promotes bone homeostasis and remodeling, making it an excellent therapeutic target. Detection of CTSK activity in complex biological samples using tailored tools such as activity-based probes (ABPs) will aid tremendously in drug development. Here, potent and selective CTSK probes are designed and created, comparing irreversible and reversible covalent ABPs with improved recognition components and electrophiles. The newly developed CTSK ABPs precisely detect active CTSK in mouse and human cells and tissues, from diseased and healthy states such as inflamed tooth implants, osteoclasts, and lung samples, indicating changes in CTSK's activity in the pathological samples. These probes are used to study how acidic pH stimulates mature CTSK activation, specifically, its transition from pro-form to mature form. Furthermore, this study reveals for the first time, why intact cells and cell lysate exhibit diverse CTSK activity while having equal levels of mature CTSK enzyme. Interestingly, these tools enabled the discovery of active CTSK in human osteoclast nuclei and in the nucleoli. Altogether, these novel probes are excellent research tools and can be applied in vivo to examine CTSK activity and inhibition in diverse diseases without immunogenicity hazards.

Columbianadin ameliorates rheumatoid arthritis by attenuating synoviocyte hyperplasia through targeted vimentin to inhibit the VAV2/Rac-1 signaling pathway

IntroductionRheumatoid arthritis (RA) is an autoimmune disease pathologically characterized by synovial inflammation. The abnormal activation of synoviocytes seems to accompany the progression of RA. The role and exact molecular mechanism in RA of columbianadin (CBN) which is a natural coumarin is still unclear. ObjectivesThe present research aimed to investigate the effect of vimentin on the abnormal growth characteristics of RA synoviocytes and the targeted regulatory role of CBN. MethodsCell migration and invasion were detected using the wound healing and transwell method. Mechanistically, the direct molecular targets of CBN were screened and identified by activity-based protein profiling. The expression of relevant proteins and mRNA in cells and mouse synovium was detected by western blotting and qRT-PCR. Changes in the degree of paw swelling and body weight of mice were recorded. H&E staining, toluidine blue staining, and micro-CT were used to visualize the degree of pathological damage in the ankle joints of mice. Small interfering RNA and plasmid overexpression of vimentin were used to observe their effects on MH7A cell proliferation, migration, apoptosis, and downstream molecular signaling. ResultsThe TNF-α-induced proliferation and migration of MH7A cells could be significantly repressed by CBN (25,50 μM), and the expression of apoptosis and autophagy-associated proteins could be modulated. Furthermore, CBN could directly bind to vimentin and inhibit its expression and function in synoviocytes, thereby ameliorating foot and paw swelling and joint damage in CIA mice. Silencing and overexpression of vimentin might be involved in developing RA synovial hyperplasia and invasive cartilage by activating VAV2 phosphorylation-mediated expression of Rac-1, which affects abnormal growth characteristics, such as synoviocyte invasion and migration. ConclusionCBN-targeted vimentin restrains the overactivation of RA synoviocytes thereby delaying the pathological process in CIA mice, which provides valuable targets and insights for understanding the pathological mechanisms of RA synovial hyperplasia.

Small-molecule targeting BCAT1-mediated BCAA metabolism inhibits the activation of SHOC2-RAS-ERK to induce apoptosis of Triple-negative breast cancer cells

IntroductionTriple-negative breast cancer (TNBC) is the most malignant subtype of breast cancer with the worst prognosis. Exploring novel carcinogenic factors and therapeutic drugs for TNBC remains a focus to improve prognosis. Branched-chain amino acid transaminase 1 (BCAT1), a crucial enzyme in branched-chain amino acid (BCAA) metabolism, has been linked to various tumor developments, but its carcinogenic function and mechanism in TNBC remain unclear. Eupalinolide B (EB) is a naturally-derived small-molecule with anti-tumor activity, but its role in TNBC remains unknown. ObjectivesBy exploring the targets and pharmacological mechanisms of EB in inhibiting TNBC, this study aimed to discover novel therapeutic targets and potential inhibitors for TNBC, and elucidate novel pathogenic mechanisms of TNBC. MethodsThe inhibitory effect of EB on TNBC was investigated using mouse models and cellular phenotypic experiments. Activity-based protein profiling (ABPP) technology, pull down-WB, CETSA-WB and MST were utilized to discover and validate the targets of EB. The oncogenic role of BCAT1 was determined through clinical data analysis and biochemical experiments. To elucidate the mechanism by which EB inhibited TNBC, many methods, including but not limited to HPLC and proteomic sequencing were used. ResultsWe found that EB significantly inhibited TNBC progression. We identified BCAT1 as the direct target of EB and confirmed that BCAT1 was critical for TNBC development. EB inhibited BCAT1-involved BCAA metabolism to reduce the synthesis of BCAAs (including Leu, Ile, and Val), thereby inhibiting SHOC2 (a Leu-rich repeat protein) expression and the downstream SHOC2-participating RAS-ERK signaling pathway, ultimately leading to apoptosis of TNBC cells. ConclusionCollectively, this study not only elucidates the oncogenic role of BCAT1 and its downstream SHOC2-RAS-ERK signaling axis in TNBC progression but also opens up avenues for potential therapies targeting BCAT1 or BCAA metabolism (using EB alone or in combination with its inhibitor candesartan) for TNBC treatment.

Development of an Activity-Based Ratiometric Electrochemical Switch for Direct, Real-Time Sensing of Pantetheinase in Live Cells, Blood, and Urine Samples.

Pantetheinase is a key biomarker for the diagnosis of acute kidney injury and the monitoring of malaria progression. Currently, existing methods for sensing pantetheinase, also known as Vanin-1, show considerable potential but come with certain limitations, including their inability to directly sense analytes in turbid biofluid samples without tedious sample pretreatment. Here, we describe the first activity-based electrochemical probe, termed VaninLP, for convenient and specific direct targeting of pantetheinase activity in turbid liquid biopsy samples. The probe was designed such that cleavage of the pantetheinase amide linkage, triggered by a self-immolative reaction, simultaneously ejects an amino ferrocene reporter. Among the distinctive properties of the VaninLP probe for sensing pantetheinase are its high selectivity, sensitivity, and enzyme affinity, a wide linear concentration range (8-300 ng/mL), and low limit of detection (2.47 ng/mL). The designed probe precisely targeted pantetheinase and was free of interference by other electroactive biological species. We further successfully applied the VaninLP probe to monitor and quantify the activity of pantetheinase on the surfaces of HepG2 tumor cells, blood, and urine samples. Collectively, our findings indicate that VaninLP holds significant promise as a point-of-care tool for diagnosing early-stage kidney injury, as well as monitoring the progression of malaria.

The Proteolytic Activity of Neutrophil-Derived Serine Proteases Bound to the Cell Surface Arming Lung Epithelial Cells for Viral Defense.

The collaboration between cellular proteases and host cells is pivotal in mounting an effective innate immune defense. Of particular interest is the synergistic interaction between cathepsin G (CatG) and neutrophil elastase (NE), which are proteases secreted by activated neutrophils, and the human alveolar basal epithelial cell line (A549) and the human lung epithelial-like cell line (H1299), because of the potential implications for viral infection. Our study aimed to investigate the binding capacity of CatG and NE on the surface of A549 and H1299 cells through preincubation with purified CatG and NE; thereby, the proteolytic activity could be detected using activity-based probes. Both CatG and NE were capable of binding to the cell surface and exhibited proteolytic activity, leading to increased cell surface levels of MHC I molecules, which is crucial for displaying the endogenous antigenic repertoire. In addition, CatG cleaved the S2' site of the SARS-CoV-2 spike protein at two specific sites (815RS816 and 817FI818) as well as NE (813SK814 and 818IE819), which potentially leads to the destruction of the fusion peptide. Additionally, furin required the presence of Ca2+ ions for the distinct cleavage site necessary to generate the fusion peptide. Overall, the findings suggest that CatG and NE can fortify target cells against viral entry, underscoring the potential significance of cell surface proteases in protecting against viral invasion.

Target Fishing Reveals a Novel Mechanism of N-Acylamino Saccharin Derivatives Targeting Glyceraldehyde-3-Phosphate Dehydrogenase toward Cyanobacterial Blooms Control.

Based on current challenges of poor targeting and limited choices in chemical control methods of cyanobacterial blooms (CBs), identifying new targets is an urgent and formidable task in the quest for target-based algaecides. This study discovered N-acylamino saccharin derivatives exhibiting potent algicidal activity. Thus, using N-acylamino saccharin as the probes, glyceraldehyde-3-phosphate dehydrogenase from cyanobacterial (CyGAPDH) was identified as a new target of algaecides through the activity-based protein profiling (ABPP) strategy for the first time. Building upon the structure of Probe2, a series of derivatives were designed and synthesized, with compound b6 demonstrating the most potent inhibitory activity against CyGAPDH and Synechocystis sp. PCC6803 (IC50 = 1.67 μM and EC50 = 1.15 μM). Furthermore, the potential covalent binding model of b6 to the cysteine residue C154 was explored through covalent possibility prediction, LC-MS experiments, substrate competitive inhibition experiments, and molecular docking. Especially, the results revealed C154 as a crucial covalent binding site, with residues T184 and R11 forming robust hydrophobic interactions and H181 establishing significant hydrogen-bonding interactions with b6, highlighting their potential as essential pharmacophores. In summary, this study not only identifies a novel target of algaecides for the control of CB but also lays the solid foundation for the development of targeted covalent algaecides.

An allosteric cyclin E-CDK2 site mapped by paralog hopping with covalent probes.

More than half of the ~20,000 protein-encoding human genes have paralogs. Chemical proteomics has uncovered many electrophile-sensitive cysteines that are exclusive to subsets of paralogous proteins. Here we explore whether such covalent compound-cysteine interactions can be used to discover ligandable pockets in paralogs lacking the cysteine. Leveraging the covalent ligandability of C109 in the cyclin CCNE2, we substituted the corresponding residue in paralog CCNE1 to cysteine (N112C) and found through activity-based protein profiling that this mutant reacts stereoselectively and site-specifically with tryptoline acrylamides. We then converted the tryptoline acrylamide-CCNE1-N112C interaction into in vitro NanoBRET (bioluminescence resonance energy transfer) and in cellulo activity-based protein profiling assays capable of identifying compounds that reversibly inhibit both the N112C mutant and wild-type CCNE1:CDK2 (cyclin-dependent kinase 2) complexes. X-ray crystallography revealed a cryptic allosteric pocket at the CCNE1:CDK2 interface adjacent to N112 that binds the reversible inhibitors. Our findings, thus, show how electrophile-cysteine interactions mapped by chemical proteomics can extend the understanding of protein ligandability beyond covalent chemistry.

Differential Effect of Simulated Microgravity on the Cellular Uptake of Small Molecules.

The space environment can affect the function of all physiological systems, including the properties of cell membranes. Our goal in this study was to explore the effect of simulated microgravity (SMG) on the cellular uptake of small molecules based on reported microgravity-induced changes in membrane properties. SMG was applied to cultured cells using a random-positioning machine for up to three hours. We assessed the cellular accumulation of compounds representing substrates of uptake and efflux transporters, and of compounds not shown to be transported by membrane carriers. Exposure to SMG led to an increase of up to 60% (p < 0.01) in the cellular uptake of efflux transporter substrates, whereas a glucose transporter substrate showed a decrease of 20% (p < 0.05). The uptake of the cathepsin activity-based probe GB123 (MW, 1198 g/mol) was also enhanced (1.3-fold, p < 0.05). Cellular emission of molecules larger than ~3000 g/mol was reduced by up to 50% in SMG (p < 0.05). Our findings suggest that short-term exposure to SMG could differentially affect drug distribution across membranes. Longer exposure to microgravity, e.g., during spaceflight, may have distinct effects on the cellular uptake of small molecules.