Thiol-reactive Agents Research Articles

Dynamic Covalent Michael Acceptors to Penetrate Cells: Thiol-Mediated Uptake with Tetrel-Centered Exchange Cascades, Assisted by Halogen-Bonding Switches.

Chalcogen-centered cascade exchange chemistry is increasingly understood to account for thiol-mediated uptake, that is, the ability of reversibly thiol-reactive agents to penetrate cells. Here, reversible Michael acceptors are shown to enable and inhibit thiol-mediated uptake, including the cytosolic delivery of proteins. Dynamic cyano-cinnamate dimers rival the best chalcogen-centered inhibitors. Patterns generated in inhibition heatmaps reveal contributions from halogen-bonding switches that occur independent from the thyroid transporter MCT8. The uniqueness of these patterns supports that the entry of tetrel-centered exchangers into cells differs from chalcogen-centered systems. These results expand the chemical space of thiol-mediated uptake and support the existence of a universal exchange network to bring matter into cells, abiding to be decoded for drug delivery and drug discovery in the broadest sense.

THE USE OF BIO-MOLECULAR SUBSTANCE OF MARINE BIOTA AS AN ALTERNATIVE EARLY INDICATOR OF OIL POLLUTED ENVIRONMENT: A NEW APPROACH FOR MONITORING CONSIDERATION

THE USE OF BIO-MOLECULAR SUBSTANCE OF MARINE BIOTA AS AN ALTERNATIVE EARLY INDICATOR OF OIL POLLUTED ENVIRONMENT: A NEW APPROACH FOR MONITORING CONSIDERATION

N-Acetylcysteine Inhibits Aortic Stenosis Progression in a Murine Model by Blocking Shear-Induced Activation of Platelet Latent Transforming Growth Factor Beta 1.

Objective: Aortic stenosis (AS) is characterized by narrowing of the aortic valve opening, resulting in peak blood flow velocity that induces high wall shear stress (WSS) across the valve. Severe AS leads to heart failure and death. There is no treatment available for AS other than valve replacement. Platelet-derived transforming growth factor beta 1 (TGF-β1) partially contributes to AS progression in mice, and WSS is a potent activator of latent TGF-β1. N-acetylcysteine (NAC) inhibits WSS-induced TGF-β1 activation in vitro. We hypothesize that NAC will inhibit AS progression by inhibiting WSS-induced TGF-β1 activation. Approach: We treated a cohort of Ldlr(-/-)Apob(100/100) low density lipoprotein receptor (LDLR) mice fed a high-fat diet with NAC (2% in drinking water) at different stages of disease progression and measured its effect on AS progression and TGF-β1 activation. Results: Short-term NAC treatment inhibited AS progression in mice with moderate and severe AS relative to controls, but not in LDLR mice lacking platelet-derived TGF-β1 (TGF-β1platlet-KO-LDLR). NAC treatment reduced TGF-β signaling, p-Smad2 and collagen levels, and mesenchymal transition from isolectin B4 and CD45-positive cells in LDLR mice. Mechanistically, NAC treatment resulted in plasma NAC concentrations ranging from 75.5 to 449.2 ng/mL, which were sufficient to block free thiol labeling of plasma proteins and reduce active TGF-β1 levels without substantially affecting reactive oxygen species-modified products in valvular cells. Conclusions: Short-term treatment with NAC inhibits AS progression by inhibiting WSS-induced TGF-β1 activation in the LDLR mouse model of AS, motivating a clinical trial of NAC and/or other thiol-reactive agent(s) as a potential therapy for AS.

Biochemical Characterization of 13-Lipoxygenases of Arabidopsis thaliana.

13-lipoxygenases (13-LOX) catalyze the dioxygenation of various polyunsaturated fatty acids (PUFAs), of which α-linolenic acid (LeA) is converted to 13-S-hydroperoxyoctadeca-9, 11, 15-trienoic acid (13-HPOT), the precursor for the prostaglandin-like plant hormones cis-(+)-12-oxophytodienoic acid (12-OPDA) and methyl jasmonate (MJ). This study aimed for characterizing the four annotated A. thaliana 13-LOX enzymes (LOX2, LOX3, LOX4, and LOX6) focusing on synthesis of 12-OPDA and 4Z,7Z,10Z)-12-[[-(1S,5S)-4-oxo-5-(2Z)-pent-2-en-1yl] cyclopent-2-en-1yl] dodeca-4,7,10-trienoic acid (OCPD). In addition, we performed interaction studies of 13-LOXs with ions and molecules to advance our understanding of 13-LOX. Cell imaging indicated plastid targeting of fluorescent proteins fused to 13-LOXs-N-terminal extensions, supporting the prediction of 13-LOX localization to plastids. The apparent maximal velocity (Vmax app) values for LOX-catalyzed LeA oxidation were highest for LOX4 (128 nmol·s−1·mg protein−1), with a Km value of 5.8 µM. A. thaliana 13-LOXs, in cascade with 12-OPDA pathway enzymes, synthesized 12-OPDA and OCPD from LeA and docosahexaenoic acid, previously shown only for LOX6. The activities of the four isoforms were differently affected by physiologically relevant chemicals, such as Mg2+, Ca2+, Cu2+ and Cd2+, and by 12-OPDA and MJ. As demonstrated for LOX4, 12-OPDA inhibited enzymatic LeA hydroperoxidation, with half-maximal enzyme inhibition at 48 µM. Biochemical interactions, such as the sensitivity of LOX toward thiol-reactive agents belonging to cyclopentenone prostaglandins, are suggested to occur in human LOX homologs. Furthermore, we conclude that 13-LOXs are isoforms with rather specific functional and regulatory enzymatic features.

Thiol-Mediated Uptake.

This Perspective focuses on thiol-mediated uptake, that is, the entry of substrates into cells enabled by oligochalcogenides or mimics, often disulfides, and inhibited by thiol-reactive agents. A short chronology from the initial observations in 1990 until today is followed by a summary of cell-penetrating poly(disulfide)s (CPDs) and cyclic oligochalcogenides (COCs) as privileged scaffolds in thiol-mediated uptake and inhibitors of thiol-mediated uptake as potential antivirals. In the spirit of a Perspective, the main part brings together topics that possibly could help to explain how thiol-mediated uptake really works. Extreme sulfur chemistry mostly related to COCs and their mimics, cyclic disulfides, thiosulfinates/-onates, diselenolanes, benzopolysulfanes, but also arsenics and Michael acceptors, is viewed in the context of acidity, ring tension, exchange cascades, adaptive networks, exchange affinity columns, molecular walkers, ring-opening polymerizations, and templated polymerizations. Micellar pores (or lipid ion channels) are considered, from cell-penetrating peptides and natural antibiotics to voltage sensors, and a concise gallery of membrane proteins, as possible targets of thiol-mediated uptake, is provided, including CLIC1, a thiol-reactive chloride channel; TMEM16F, a Ca-activated scramblase; EGFR, the epithelial growth factor receptor; and protein-disulfide isomerase, known from HIV entry or the transferrin receptor, a top hit in proteomics and recently identified in the cellular entry of SARS-CoV-2.

Quantitative and comparative liquid chromatography-electrospray ionization-mass spectrometry analyses of hydrogen sulfide and thiol metabolites derivaitized with 2-iodoacetanilide isotopologues

Hydrogen sulfide (H2S), previously known as a toxic gas, is now recognized as a gasotransmitter along with nitric oxide and carbon monoxide. However, only few methods are available for quantitative determination of H2S in biological samples. 2-Iodoacetanilide (2-IAN), a thiol-reacting agent, has been used to tag the reduced cysteine residues of proteins for quantitative proteomics and for detection of cysteine oxidation modification. In this article, we proposed a new method for quantitative analyses of H2S and thiol metabolites using the procedure of pre-column 2-IAN derivatization coupled with liquid chromatography-electrospray ionization-mass spectrometry (LC-ESI–MS). 13C6-Labeled and label-free 2-IAN efficiently react with H2S and thiol compounds at pH 9.5 and 65 °C. The derivatives exhibit excellent stability at alkaline conditions, high resolution on reverse phase liquid chromatography and great sensitivity for ESI–MS detection. The measurement of H2S, l-cysteine, glutathione, and DL-homocysteine derivatives was validated using 13C6-labeled standard in LC-ESI–MS analyses and exhibited 10 nM–1 μM linear ranges for DL-homocysteine and glutathione and 1 nM–1 μM linear ranges for l-cysteine and H2S. In addition, the sequence of derivatization and extraction of metabolites is important in the quantification of thiol metabolites suggesting the presence of matrix effects. Most importantly, labeling with 2-IAN and 13C6-2-IAN isotopologues could achieve quantitative and matched sample comparative analyses with minimal bias using our extraction and labeling procedures before LC–MS analysis.

Role of the Cysteine 81 Residue of Macrophage Migration Inhibitory Factor as a Molecular Redox Switch.

Macrophage migration inhibitory factor (MIF) is a pro-inflammatory and tumor-promoting cytokine that occurs in two redox-dependent immunologically distinct conformational isoforms. The disease-related structural isoform of MIF (oxMIF) can be specifically and predominantly detected in the circulation of patients with inflammatory diseases and in tumor tissue, whereas the ubiquitously expressed isoform of MIF (redMIF) is abundantly expressed in healthy and diseased subjects. In this article, we report that cysteine 81 within MIF serves as a "switch cysteine" for the conversion of redMIF to oxMIF. Modulating cysteine 81 by thiol reactive agents leads to significant structural rearrangements of the protein, resulting in a decreased β-sheet content and an increased random coil content, but maintaining the trimeric quaternary structure. This conformational change in the MIF molecule enables binding of oxMIF-specific antibodies BaxB01 and BaxM159, which showed beneficial activity in animal models of inflammation and cancer. Crystal structure analysis of the MIF-derived EPCALCS peptide, bound in its oxMIF-like conformation by the Fab fragment of BaxB01, revealed that this peptide adopts a curved conformation, making the central thiol protein oxidoreductase motif competent to undergo disulfide shuffling. We conclude that redMIF might reflect a latent zymogenic form of MIF, and formation of oxMIF leads to a physiologically relevant, i.e., enzymatically active, state.

Mechanism and Potential Inhibitors of GlmU: A Novel Target for Antimicrobial Drug Discovery.

Multidrug resistant Gram negative pathogens pose a persistent threat to the health care system and require investigation of new targets and molecules for the development of antibiotics to treat infections caused by MDR bacterial pathogens. It is essential to work on multidisciplinary approaches and diverse strategies for developing new compounds acting on novel antibacterial targets. N-acetylglucosamine-1-phosphateuridyltransferase/ glucosamine-1-phosphate-acetyltransferase (GlmU) is one such target which is involved in the synthesis of both peptidoglycan and Lipopolysaccharide in Gram negative and Gram positive bacteria making GlmU an attractive target for developing antibacterials. GlmU, as revealed by X- ray crystallographic studies, is made up of two domains connected by α helical arm; the N-terminal uridyltransferase domain resembles a dinucleotide Rossmann fold and the C- terminal acetyltransferase domain adopts a left handed parallel β helix structure. The GlmU molecules are arranged in a trimeric array, the acetyltransferase active site being formed at the junction of adjacent LβH domain. Many potent inhibitors of both the acetyltransferase and uridyltransferase activity of GlmU have been identified. Inhibitors of the acetyltransferase activity of GlmU include nonspecific thiol reactive agents, 2-phenylbenzofurans, arylamines and arylsulfonamides. A aminopiperidine based inhibitor has also been reported to inhibit uridyltransferase activity of hiGlmU. The present review provides an insight of the structure of GlmU and its reported inhibitors which make GlmU a potential target for drug designing. The GlmU is a promising target for drug discovery against Gram negative pathogens and future studies should focus on GlmU for the development of more potent compounds for treating Gram negative infections.

The fifth subunit of the (α4β2)2 β2 nicotinic ACh receptor modulates maximal ACh responses.

The fifth subunit in the (α4β2)2 α4 nicotinic ACh receptor (nAChR) plays a determining role in the pharmacology of this nAChR type. Here, we have examined the role of the fifth subunit in the ACh responses of the (α4β2)2 β2 nAChR type. The role of the fifth subunit in receptor function was explored using two-electrode voltage clamp electrophysiology, along with subunit-targeted mutagenesis and the substituted cysteine scanning method applied to fully linked (α4β2)2 β2 receptors. Covalent modification of the cysteine-substituted fifth subunit with a thiol-reactive agent (MTS) caused irreversible inhibition of receptor function. ACh reduced the rate of the reaction to MTS, but the competitive inhibitor dihydro-β-erythroidine had no effect. Alanine substitution of conserved residues that line the core of the agonist sites on α4(+)/β2(-) interfaces did not impair receptor function. However, impairment of agonist binding to α4(+)/β2(-) agonist sites by mutagenesis modified the effect of ACh on the rate of the reaction to MTS. The extent of this effect was dependent on the position of the agonist site relative to the fifth subunit. The fifth subunit in the (α4β2)2 β2 receptor isoform modulates maximal ACh responses. This effect appears to be driven by a modulatory, and asymmetric, association with the α4(+)/β2(-) agonist sites. This article is part of a themed section on Nicotinic Acetylcholine Receptors. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v175.11/issuetoc.

Detection of S-Acylated CD95 by Acyl-Biotin Exchange.

S-acylation is the covalent addition of a fatty acid, most generally palmitate onto cysteine residues of proteins through a labile thioester linkage. The death receptor CD95 is S-palmitoylated and this post-translational modification plays a crucial role on CD95 organization in cellular membranes and thus on CD95-mediated signaling. Here, we describe the nonradioactive detection of CD95 S-acylation by acyl-biotin exchange chemistry in which a biotin is substituted for the CD95-linked fatty acid. This sensitive technique, which depends on the ability of hydroxylamine to specifically cleave the thioester linkage between fatty acids and proteins, relies on three chemical steps: (1) blockage of free thiols of non-modified cysteine residues, (2) hydroxylamine-mediated cleavage of thioester-linked fatty acids to restore free thiols and (3) biotinylation of free thiols with a thiol reactive biotinylation agent. Resulting biotinylated proteins can be easily purified by an avidin capture and analyzed by SDS-PAGE and immunoblotting.

Semi-Automated Synthesis of [F-18]FBAM, a Thiol Reactive Prosthetic Group, Using Continuous Flow Chemistry

[F-18]FBAM, a thiol reactive bifunctional agent, was successfully synthesized using continuous flow chemistry in a micro reactor that is part of Advion NanoTek Micro-fluidic Synthesizer. As the radiofluorination was carried out microfluidically, a very small amount of precursor was used and over all radiochemical yield was 38% ± 4% (n = 8, decay corrected) and the radiochemical purity was ≥98% with specific activity of 430 mC/μmol. The total reaction time including HPLC purification was 55 min that is 14 min more than manual synthesis and 6 min less than fully automated synthesis.

Fluorine-18 Radiochemistry: A Novel Thiol-Reactive Prosthetic Group, [18F]FBAMPy

A novel thiol-reactive bifunctional agent, an analogue of fluorobenzaldehyde-O-[6-(2,5-dioxo-2,5- dihydro-pyrrol-1-yl)-hexyl]oxime, (FBAM) has been synthesized. The new prosthetic group, [18F]- FBAMPy, replaces the 4-fluorophenyl moiety with a 2-fluoropyridinyl moiety leading to increased polarity (FBAM analytical HPLC Rf = 6.4 min; FBAMPy Rf = 4.8 min) while retaining the sulfur-reactive pendant. By altering the polarity of the molecule, this new prosthetic group should have significant impact in coupling it with small peptides and other biomolecules.

Non-Proteolytic Regulation of the Multimerization of Von Willebrand Factor By ADAMTS13 Based on a Novel Cysteine Thiol Redundancy

The platelet dependent-clotting process is a highly complex pathway that needs to be tightly controlled by a variety of soluble and cellular components. Failure to regulate the activity of multimeric von Willebrand factor (VWF) by ADAMTS13 for instance causes thrombotic thrombocytopenia purpura (TTP). Regulation is achieved through the established function of ADAMTS13 as a VWF-cleaving protease; however, it has been reported that ADAMTS13 may additionally curtail VWF multimer fibrillation by forming disulfide bridges with VWF. Since the latter mechanism remained ill-defined, we aimed to directly visualize disulfide bond formation between ADAMTS13 and VWF using multimer gel electrophoresis. Covalent interaction between ADAMTS13 and VWF was time-, concentration-, temperature-, and shear-stress dependent. The covalent linkage was independent of the proteolytic activity of ADAMTS13 and could be assigned to a C-terminal fragment comprising TSP1 domains 5 to 8 plus the CUB domains. This interaction was blocked by thiol-reactive agents, indicating that association was accomplished by a thiol/disulfide exchange reaction. Furthermore, a polyclonal anti-ADAMTS13 antibody that inhibited the protease in a FRETS-VWF73 activity assay also inhibited the formation of VWF-ADAMTS13 adducts.Using a coupled reversed phase HPLC-ESI-QTOF-MS system, several partially reduced free thiols were identified in ADAMTS13, with cysteines 1254 and 1275 being the most prominent. Together with the observation that a C1275S point mutation retained the ability to form covalent linkages with VWF, this result indicated that ADAMTS13 has disulfide plasticity. The same conditions that led to VWF complex formation also caused a hitherto undetected homo-oligomerization of ADAMTS13. An even more pronounced oligomerization was noted in the presence of thiol-sensitive agents such as glutathione.We propose a dynamic network of redundant, partially free thiols in ADAMTS13 that undergo intra- and inter-molecular redox reactions capable not only of depolymerizing VWF, but also to prevent further VWF multimerization by facilitating the aggregation of ADAMTS13 around the monomers. DisclosuresRottensteiner:Baxalta Innovations GmbH: Employment. Skalicky:Baxalta Innovations GmbH: Employment. Seyfried:Baxalta Innovations GmbH: Employment. Kaufmann:Baxalta Innovations GmbH: Employment. Fiedler:Baxalta Innovations GmbH: Employment. Hasslacher:Baxalta Innovations GmbH: Employment. Plaimauer:Baxalta Innovations GmbH: Employment. Scheiflinger:Baxalta Innovations GmbH: Employment.

Neuronal acid-induced [Zn²⁺]i elevations calibrated using the low-affinity ratiometric probe FuraZin-1.

The experiments were carried out on primary cultures of murine cortical neurons from cryopreserved preparations obtained from embryonic-day-16 fetuses. To calibrate acid-induced intracelluar [Zn(2+) ] ([Zn(2+) ]i ) elevations, a low affinity (Kd = 39 μM at pH 6.1) ratiometric Zn(2+) probe, FuraZin-1, was used. A pHi drop from 7.2 to 6.1 caused [Zn(2+) ]i elevations reaching 2 μM; when the thiol-reactive agent N-ethylmaleimide (NEM) was subsequently applied, [Zn(2+) ]i increased further to 5.6 μM; analogous acid- and NEM-induced [Zn(2+) ]i elevations could also be detected but not calibrated, using the high affinity Zn(2+) probe FluoZin-3. The data indicate that NEM causes Zn(2+) release from ligands that chelate Zn(2+) at pH 6.1. ATP could also chelate Zn(2+) at pH 6.1 because its pKa is about 6.8. Therefore, it was tested whether an ATP depletion affects the acid-induced [Zn(2+) ]i elevations. The ATP depletion was induced by inhibiting mitochondrial and glycolytic ATP production. Interestingly, an almost complete ATP depletion (confirmed using a luciferin/luciferase assay) failed to affect the acid-induced [Zn(2+) ]i increases. These data suggest that the total amount of Zn(2+) accumulated in intracellular ATP-dependent stores (Zn(2+) -ATP complexes and organelles that accumulate Zn(2+) in an ATP-dependent manner) is negligible compared to the amount of Zn(2+) accumulated in the acid-sensitive intracellular ligands. In vitro, upon acidification, Zn(2+) -cysteine complexes release Zn(2+) and ATP chelates the released Zn(2+) . However, in vivo (cultured neurons), an ATP depletion failed to enhance acid-induced [Zn(2+) ]i elevations. These [Zn(2+) ]i elevations were calibrated using a low affinity ratiometric probe FuraZin-1; they reached 2 µM levels and increased to 5 µM when a thiol-reactive agent, N-ethylmaleimide, compromised Zn(2+) binding by cysteines.

Role of Cys3602 in the function and regulation of the cardiac ryanodine receptor

The cardiac Ca²⁺ release channel [ryanodine receptor type 2 (RyR2)] is modulated by thiol reactive agents, but the molecular basis of RyR2 modulation by thiol reagents is poorly understood. Cys³⁶³⁵ in the skeletal muscle RyR1 is one of the most hyper-reactive thiols and is important for the redox and calmodulin (CaM) regulation of the RyR1 channel. However, little is known about the role of the corresponding cysteine residue in RyR2 (Cys³⁶⁰²) in the function and regulation of the RyR2 channel. In the present study, we assessed the impact of mutating Cys³⁶⁰² (C³⁶⁰²A) on store overload-induced Ca²⁺ release (SOICR) and the regulation of RyR2 by thiol reagents and CaM. We found that the C³⁶⁰²A mutation suppressed SOICR by raising the activation threshold and delayed the termination of Ca²⁺ release by reducing the termination threshold. As a result, C³⁶⁰²A markedly increased the fractional Ca²⁺ release. Furthermore, the C³⁶⁰²A mutation diminished the inhibitory effect of N-ethylmaleimide on Ca²⁺ release, but it had no effect on the stimulatory action of 4,4'-dithiodipyridine (DTDP) on Ca²⁺ release. In addition, Cys³⁶⁰² mutations (C³⁶⁰²A or C³⁶⁰²R) did not abolish the effect of CaM on Ca²⁺-release termination. Therefore, RyR2-Cys³⁶⁰² is a major site mediating the action of thiol alkylating agent N-ethylmaleimide, but not the action of the oxidant DTDP. Our data also indicate that residue Cys³⁶⁰² plays an important role in the activation and termination of Ca²⁺ release, but it is not essential for CaM regulation of RyR2.

Bacillithiol is a major buffer of the labile zinc pool in Bacillus subtilis.

Intracellular zinc levels are tightly regulated since zinc is an essential cofactor for numerous enzymes, yet can be toxic when present in excess. The majority of intracellular zinc is tightly associated with proteins and is incorporated during synthesis from a poorly defined pool of kinetically labile zinc. In Bacillus subtilis, this labile pool is sensed by equilibration with the metalloregulator Zur, as an indication of zinc sufficiency, and by CzrA, as an indication of zinc excess. Here, we demonstrate that the low-molecular-weight thiol bacillithiol (BSH) serves as a major buffer of the labile zinc pool. Upon shift to conditions of zinc excess, cells transiently accumulate zinc in a low-molecular-weight pool, and this accumulation is largely dependent on BSH. Cells lacking BSH are more sensitive to zinc stress, and they induce zinc efflux at lower external zinc concentrations. Thiol reactive agents such as diamide and cadmium induce zinc efflux by interfering with the Zn-buffering function of BSH. Our data provide new insights into intracellular zinc buffering and may have broad relevance given the presence of BSH in pathogens and the proposed role of zinc sequestration in innate immunity.

X-ray crystal structures of thiol-reactive agents in complex with Mycobacterium tuberculosis secreted antigen 85-C (fbpC; ag85C)

X-ray crystal structures of thiol-reactive agents in complex with Mycobacterium tuberculosis secreted antigen 85-C (fbpC; ag85C)

NitroDIGE analysis reveals inhibition of protein S-nitrosylation by epigallocatechin gallates in lipopolysaccharide-stimulated microglial cells

BackgroundNitric oxide (NO) is a signaling molecule regulating numerous cellular functions in development and disease. In the brain, neuronal injury or neuroinflammation can lead to microglial activation, which induces NO production. NO can react with critical cysteine thiols of target proteins forming S-nitroso-proteins. This modification, known as S-nitrosylation, is an evolutionarily conserved redox-based post-translational modification (PTM) of specific proteins analogous to phosphorylation. In this study, we describe a protocol for analyzing S-nitrosylation of proteins using a gel-based proteomic approach and use it to investigate the modes of action of a botanical compound found in green tea, epigallocatechin-3-gallate (EGCG), on protein S-nitrosylation after microglial activation.Methods/ResultsTo globally and quantitatively analyze NO-induced protein S-nitrosylation, the sensitive gel-based proteomic method, termed NitroDIGE, was developed by combining two-dimensional differential in-gel electrophoresis (2-D DIGE) with the modified biotin switch technique (BST) using fluorescence-tagged CyDye™ thiol reactive agents to label S-nitrosothiols. The NitroDIGE method showed high specificity and sensitivity in detecting S-nitrosylated proteins (SNO-proteins). Using this approach, we identified a subset of SNO-proteins ex vivo by exposing immortalized murine BV-2 microglial cells to a physiological NO donor, or in vivo by exposing BV-2 cells to endotoxin lipopolysaccharides (LPS) to induce a proinflammatory response. Moreover, EGCG was shown to attenuate S-nitrosylation of proteins after LPS-induced activation of microglial cells primarily by modulation of the nuclear factor erythroid 2-related factor 2 (Nrf2)-mediated oxidative stress response.ConclusionsThese results demonstrate that NitroDIGE is an effective proteomic strategy for “top-down” quantitative analysis of protein S-nitrosylation in multi-group samples in response to nitrosative stress due to excessive generation of NO in cells. Using this approach, we have revealed the ability of EGCG to down-regulate protein S-nitrosylation in LPS-stimulated BV-2 microglial cells, consistent with its known antioxidant effects.

Comparison of three thiol probes for determination of apoptosis‐related changes in cellular redox status

An early step in apoptosis is extrusion of reduced glutathione (GSH). Current assays for measuring apoptosis involve a number of incubation and washing steps, making them time consuming and laborious. Using two novel thiol reactive agents (VitaBright-43 and VitaBright-48) and a GSH specific probe; monochlorobimane, we investigated whether changes in the level of free thiols can be used as an apoptotic marker. Upon addition to cells the probes permeate the cell membrane and react with intracellular thiols, causing cellular fluorescence. Cytometric quantification of the cell fluorescence (without washing) can then be used to determine the population's cellular thiol level at the single cell level. Apoptotic traits such as phosphatidylserine externalisation, caspase activity and mitochondrial potential were investigated at different time points after induction of apoptosis and correlated to changes detected using the thiol probes. We found that though all three thiol probes could be used to detect changes in the level of free thiols correlating well with apoptotic markers, other properties such as detection of early versus late apoptosis and staining kinetics differed among the three probes. However, we suggest adding evaluation of the level of free thiols to the list of phenotypes which may be measured in order to detect apoptosis, as this provides a reliable and easy way of assaying apoptosis.

Nrf2 Activators Attenuate the Progression of Nonalcoholic Steatohepatitis–Related Fibrosis in a Dietary Rat Model

Oxidative stress is considered to be a key mechanism of hepatocellular injury and disease progression in patients with nonalcoholic steatohepatitis (NASH). The transcription factor Nrf2 (nuclear factor-erythroid-2-related factor 2) plays a central role in stimulating expression of various antioxidant-associated genes in the cellular defense against oxidative stress. As the cytosolic repressor kelch-like ECH-associated protein 1 (Keap1) negatively regulates Nrf2, activation of Nrf2 facilitated by its release from Keap1 may represent a promising strategy in the treatment of NASH. To test this hypothesis, we used two chemically distinct types of Nrf2 activator. One is the thiol-reactive agent oltipraz (OPZ), a typical Nrf2 activator, and the other is a novel biaryl urea compound, termed NK-252 (1-(5-(furan-2-yl)-1,3,4-oxadiazol-2-yl)-3-(pyridin-2-ylmethyl)urea). NK-252 exhibits a greater Nrf2-activating potential than OPZ. Furthermore, in vitro binding studies revealed that NK-252 interacts with the domain containing the Nrf2-binding site of Keap1, whereas OPZ does not. This finding indicates that NK-252 is more potent than OPZ due to its unique mechanism of action. For in vivo animal model studies, we used rats on a choline-deficient L-amino acid-defined (CDAA) diet, which demonstrate pathologic findings similar to those seen in human NASH. The administration of OPZ or NK-252 significantly attenuated the progression of histologic abnormalities in rats on a CDAA diet, especially hepatic fibrosis. In conclusion, by using Nrf2 activators with independent mechanisms of action, we show that, in a rat model of NASH, the activation of Nrf2 is responsible for the antifibrotic effects of these drugs. This strategy of Nrf2 activation presents new opportunities for treatment of NASH patients with hepatic fibrosis.