Fluorometric quantitation of cellular and nonprotein thiols

Quorum Sensing in Emulsion Droplet Swarms Driven by a Surfactant Competition System

Quorum sensing enables unicellular organisms to probe their population density and perform behavior that exclusively occurs above a critical density. Quorum sensing is established in emulsion droplet swarms that float at a water surface and cluster above a critical density. The design involves competition between 1) a surface tension gradient that is generated upon release of a surfactant from the oil droplets, and thereby drives their mutual repulsion, and 2) the release of a surfactant precursor from the droplets, that forms a strong imine surfactant which suppresses the surface tension gradient and thereby causes droplet clustering upon capillary (Cheerios) attraction. The production of the imine-surfactant depends on the population density of the droplets releasing the precursor so that the clustering only occurs above a critical population density. The pH-dependence of the imine-surfactant formation is exploited to trigger quorum sensing upon a base stimulus: dynamic droplet swarms are generated that cluster and spread upon spatiotemporally varying acid and base conditions. Next, the clustering of two droplet subpopulations is coupled to a chemical reaction that generates a fluorescent signal. It is foreseen that quorum sensing enables control mechanisms in droplet-based systems that display collective responses in contexts of, e.g., sensing, optics, or dynamically controlled droplet-reactors.

Universal platform for the generation of thermostabilized GPCRs that crystallize in LCP

Structural studies of G-protein-coupled receptors (GPCRs) are often limited by difficulties in obtaining well-diffracting crystals suitable for high-resolution structure determination. During the past decade, crystallization in lipidic cubic phase (LCP) has become the most successful and widely used technique for obtaining such crystals. Despite often intense efforts, many GPCRs remain refractory to crystallization, even if receptors can be purified in sufficient amounts. To address this issue, we have developed a highly efficient screening and stabilization strategy for GPCRs, based on a fluorescence thermal stability assay readout, which seems to correlate particularly well with those GPCR constructs that remain native during incorporation into the LCP. Detailed protocols are provided for rapid and cost-efficient mutant and construct generation using sequence- and ligation-independent cloning, high-throughput magnetic bead-based protein purification from small-scale expressions in mammalian cells, the screening and optimal combination of mutations for increased receptor thermostability and the rapid identification of suitable chimeric fusion protein constructs for successful crystallization in LCP. We exemplify the method on three receptors from two different classes: the neurokinin 1 receptor, the oxytocin receptor and the parathyroid hormone 1 receptor.

Fluorescent thermal shift-based method for detection of NF-κB binding to double-stranded DNA

The nuclear factor kappa B (NF-κB) family of dimeric transcription factors regulates a wide range of genes by binding to their specific DNA regulatory sequences. NF-κB is an important therapeutic target linked to a number of cancers as well as autoimmune and inflammatory diseases. Therefore, effective high-throughput methods for the detection of NF-κB DNA binding are essential for studying its transcriptional activity and for inhibitory drug screening. We describe here a novel fluorescence-based assay for quantitative detection of κB consensus double-stranded (ds) DNA binding by measuring the thermal stability of the NF-κB proteins. Specifically, DNA binding proficient NF-κB probes, consisting of the N-terminal p65/RelA (aa 1-306) and p50 (aa 1-367) regions, were designed using bioinformatic analysis of protein hydrophobicity, folding and sequence similarities. By measuring the SYPRO Orange fluorescence during thermal denaturation of the probes, we detected and quantified a shift in the melting temperatures (ΔTm) of p65/RelA and p50 produced by the dsDNA binding. The increase in Tm was proportional to the concentration of dsDNA with apparent dissociation constants (KD) of 2.228 × 10-6 M and 0.794 × 10-6 M, respectively. The use of withaferin A (WFA), dimethyl fumarate (DMF) and p-xyleneselenocyanate (p-XSC) verified the suitability of this assay for measuring dose-dependent antagonistic effects on DNA binding. In addition, the assay can be used to analyse the direct binding of inhibitors and their effects on structural stability of the protein probe. This may facilitate the identification and rational design of new drug candidates interfering with NF-κB functions.

The cystic fibrosis transmembrane conductance regulator (CFTR) and its stability

The cystic fibrosis transmembrane conductance regulator (CFTR) is responsible for the disease cystic fibrosis (CF). It is a membrane protein belonging to the ABC transporter family functioning as a chloride/anion channel in epithelial cells around the body. There are over 1500 mutations that have been characterised as CF-causing; the most common of these, accounting for ~70 % of CF cases, is the deletion of a phenylalanine at position 508. This leads to instability of the nascent protein and the modified structure is recognised and then degraded by the ER quality control mechanism. However, even pharmacologically ‘rescued’ F508del CFTR displays instability at the cell’s surface, losing its channel function rapidly and it is rapidly removed from the plasma membrane for lysosomal degradation. This review will, therefore, explore the link between stability and structure/function relationships of membrane proteins and CFTR in particular and how approaches to study CFTR structure depend on its stability. We will also review the application of a fluorescence labelling method for the assessment of the thermostability and the tertiary structure of CFTR.

Time-Dependent Protein Thermostability Assay

Membrane protein purification often yields rather unstable proteins impeding functional and structural protein characterization. Low protein stability also leads to low purification yields as a result of protein degradation, aggregation, precipitation, and folding instability. It is often required to optimize buffer conditions through numerous iterations of trial and error to improve the homogeneity, stability, and solubility of the protein sample demanding high amounts of purified protein. Therefore we have set up a fast, simple, and high-throughput time-dependent thermostability-based assay at low protein cost to identify protein stabilizing factors to facilitate the handling and characterization of membrane proteins by subsequent structural and functional studies.

Ellman's and Aldrithiol Assay as Versatile and Complementary Tools for the Quantification of Thiol Groups and Ligands on Nanomaterials

Simple, fast, and versatile methods for the quantification of thiol groups are of considerable interest not only for protein analysis but also for the characterization of the surface chemistry of nanomaterials stabilized with thiol ligands or bearing thiol groups for the subsequent (bio-) functionalization via maleimide-thiol chemistry. Here, we compare two simple colorimetric assays, the widely used Ellman's assay performed at alkaline pH and the aldrithiol assay executed at acidic and neutral pH, with respect to their potential for the quantification of thiol groups and thiol ligands on different types of nanoparticles like polystyrene nanoparticles, semiconductor nanocrystals (SC NC), and noble metal particles, and we derive criteria for their use. In order to assess the underlying reaction mechanisms and to obtain stoichiometry factors mandatory for reliable thiol quantification, both methods were studied photometrically and with electrospray ionization time-of-flight mass spectrometry (ESI-TOF-MS), thereby demonstrating the influence of different thiols on the reaction mechanism. Our results underline the suitability of both methods for the quantification of directly accessible thiol groups or ligands on the surface of 2D- and 3D-supports, here exemplarily polystyrene nanoparticles. Moreover, we could derive strategies for the use of these simple assays for the determination of masked (i.e., not directly accessible) thiol groups like disulfides such as lipoic acid and thiol stabilizing ligands coordinatively bound to Cd and/or Hg surface atoms of II/VI and ternary SC NC and to gold and silver nanoparticles.

Metallothionein regulates intracellular zinc signaling during CD4(+) T cell activation

BACKGROUND

The ultra-low redox potential and zinc binding properties of the intracellular pool of mammalian metallothioneins (MT) suggest a role for MT in the transduction of redox signals into intracellular zinc signals. Increased expression of MT after exposure to heavy metals, oxidative stress, or inflammatory cytokines leads to an increased intracellular redox-mobilizable zinc pool that can affect downstream zinc-sensitive signaling pathways. CD4(+) T helper cells are poised to be influenced by MT transduced zinc signaling because they produce intracellular reactive oxygen species following activation through the T cell receptor and are sensitive to small changes in intracellular [Zn(2+)].

RESULTS

MT expression and intracellular [Zn(2+)] are both increased during primary activation and expansion of naïve CD4(+) T cells into the Tr1 phenotype in vitro. When Tr1 cells from wildtype mice are compared with congenic mice lacking functional Mt1 and Mt2 genes, the expression of intracellular MT is associated with a greater increase in intracellular [Zn(2+)] immediately following exposure to reactive oxygen species or upon restimulation through the T cell receptor. The release of Zn(2+) from MT is associated with a greater increase in p38 MAPK activation following restimulation and decreased p38 MAPK activation in MT knockout Tr1 cells can be rescued by increasing intracellular [Zn(2+)]. Additionally, IL-10 secretion is increased in MT knockout Tr1 cells compared with wildtype controls and this increase is prevented when the intracellular [Zn(2+)] is increased experimentally.

CONCLUSIONS

Differences in zinc signaling associated with MT expression appear to be a result of preferential oxidation of MT and concomitant release of Zn(2+). Although zinc is released from many proteins following oxidation, release is greater when the cell contains an intracellular pool of MT. By expressing MT in response to certain environmental conditions, CD4(+) T cells are able to more efficiently release intracellular zinc and regulate signaling pathways following stimulation. The link between MT expression and increased zinc signaling following activation represents an important immunomodulatory mechanism of MT and illuminates the complex role MT plays in shaping immune responses.

General qPCR and Plate Reader Methods for Rapid Optimization of Membrane Protein Purification and Crystallization Using Thermostability Assays

This unit describes rapid and generally applicable methods to identify conditions that stabilize membrane proteins using temperature-based denaturation measurements as a proxy for target time-dependent stability. Recent developments with thiol-reactive dyes sensitive to the unmasking of cysteine residues upon protein unfolding have allowed for routine application of thermostability assays to systematically evaluate the stability of membrane protein preparations after various purification procedures. Test conditions can include different lipid cocktails, lipid-detergent micelles, pH, salts, osmolytes, and potential active-site ligands. Identification and use of conditions that stabilize the structure have proven successful in enabling the structure determination of numerous families of membrane proteins that otherwise were intractable.

Thioredoxin reductase-2 is essential for keeping low levels of H(2)O(2) emission from isolated heart mitochondria

Respiring mitochondria produce H(2)O(2) continuously. When production exceeds scavenging, H(2)O(2) emission occurs, endangering cell functions. The mitochondrial peroxidase peroxiredoxin-3 reduces H(2)O(2) to water using reducing equivalents from NADPH supplied by thioredoxin-2 (Trx2) and, ultimately, thioredoxin reductase-2 (TrxR2). Here, the contribution of this mitochondrial thioredoxin system to the control of H(2)O(2) emission was studied in isolated mitochondria and cardiomyocytes from mouse or guinea pig heart. Energization of mitochondria by the addition of glutamate/malate resulted in a 10-fold decrease in the ratio of oxidized to reduced Trx2. This shift in redox state was accompanied by an increase in NAD(P)H and was dependent on TrxR2 activity. Inhibition of TrxR2 in isolated mitochondria by auranofin resulted in increased H(2)O(2) emission, an effect that was seen under both forward and reverse electron transport. This effect was independent of changes in NAD(P)H or membrane potential. The effects of auranofin were reproduced in cardiomyocytes; superoxide and H(2)O(2) levels increased, but similarly, there was no effect on NAD(P)H or membrane potential. These data show that energization of mitochondria increases the antioxidant potential of the TrxR2/Trx2 system and that inhibition of TrxR2 results in increased H(2)O(2) emission through a mechanism that is independent of changes in other redox couples.

Determination of thiols and disulfides via HPLC quantification of 5-thio-2-nitrobenzoic acid

This work presents an assay for total thiols and total disulfides in biological samples via HPLC quantification of 5-thio-2-nitrobenzoic acid (TNB) derived from the reaction of thiols with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB, Ellman's reagent). This method also provides simultaneous quantification of glutathione (GSH) via the measurement of the GSH-DTNB adduct (GSH-TNB). By using 326nm as the detecting wavelength, the HPLC detection limit for TNB and the GSH-TNB adduct was determined to be 15 and 7.5pmol respectively. A recovery study with OVCAR-3 cells revealed that the recovery yields for TNB in the procedures for determining non-protein thiols, protein thiols, non-protein disulfides, and protein disulfides were 99.4+/-1.2% (n=3), 98.1+/-5.0% (n=3), 95.6+/-0.9% (n=3), and 96.6+/-2.3% (n=3) respectively. The recovery yield for GSH-TNB in the procedures for determining non-protein thiols, protein thiols, non-protein disulfides, and protein disulfides was 99.0+/-0.3% (n=3), 95.1+/-4.9% (n=3), 96.8+/-0.6% (n=3), and 95.1+/-2.9% (n=3) respectively. The reproducibility, expressed as the relative standard deviation for the analyte, for TNB was determined to be 2.8% (n=6) for non-protein thiols, 3.9% (n=6) for protein thiols, 3.6% (n=6) for non-protein disulfides and 4.6% (n=6) for protein disulfides. The reproducibility for GSH-TNB was determined to be 1.6% (n=6) for non-protein thiols and 2.6% (n=6) for non-protein disulfides. By comparing the amount of GSH determined in a biological sample before NaBH(4) reduction with that after the reduction, this method can provide information associated with thiol glutathionylation which would be useful for protein glutathionylation study. This method should be applicable to cellular, subcellular, protein, or other biomatrix samples for thiol and disulfide quantification and will be a useful analytical method in the study of thiol redox state and thiol glutathionylation.

A coupled fluorescent assay for histone methyltransferases

Histone methyltransferases (HMTs) catalyze the S-adenosylmethionine (AdoMet)-dependent methylation of lysines and arginines in the nucleosomal core histones H3 and H4 and the linker histone H1b. Methylation of these residues regulates either transcriptional activation or silencing, depending on the residue modified and its degree of methylation. Despite an intense interest in elucidating the functions of HMTs in transcriptional regulation, these enzymes have remained challenging to quantitatively assay. To characterize the substrate specificity of HMTs, we have developed a coupled-fluorescence-based assay for AdoMet-dependent methyltransferases. This assay utilizes S-adenosylhomocysteine hydrolase (SAHH) to hydrolyze the methyltransfer product S-adenosylhomocysteine (AdoHcy) to homocysteine (Hcy) and adenosine (Ado). The Hcy concentration is then determined through conjugation of its free sulfhydryl moiety to a thiol-sensitive fluorophore. Using this assay, we have determined the kinetic parameters for the methylation of a synthetic histone H3 peptide (corresponding to residues 1-15 of the native protein) by Schizosaccharomyces pombe CLR4, an H3 Lys-9-specific methyltransferase. The fluorescent SAHH-coupled assay allows rapid and facile determination of HMT kinetics and can be adapted to measure the enzymatic activity of a wide variety of AdoMet-dependent methyltransferases.

Application of a fluorescent histone acetyltransferase assay to probe the substrate specificity of the human p300/CBP-associated factor

Histone N-acetyltransferases (HATs) are a group of enzymes which acetylate specific lysine residues in the N-terminal tails of nucleosomal histones to promote transcriptional activation. Recent structural and enzymatic work on the GCN5/PCAF HAT family has elucidated the structure of their catalytic domain and mechanism of histone acetylation. However, the substrate specificity of these enzymes has not been quantitatively investigated. Utilizing a novel microplate fluorescent HAT assay which detects the enzymatic production of coenzyme A (CoA), we have compared the activities of the HAT domains of human PCAF and its GCN5 homologue from yeast and Tetrahymena and found that they have similar kinetic parameters. PCAF was further assayed with a series of different length histone H3 peptide substrates, which revealed that the determinants for substrate recognition lie within a 19-residue sequence. Finally, we evaluated the acetylation of three putative PCAF substrates, histones H3 and H4 and the transcription factor p53, and have determined that histone H3 is significantly preferred over the histone H4 and p53 substrates. Taken together, the fluorescent acetyltransferase assay presented here should be widely applicable to other HAT enzymes, and the results obtained with PCAF demonstrate a strong substrate preference for the N-terminal residues of histone H3.

Oxidative stress induced by iron in Hydrilla verticillata (l.f.) Royle: response of antioxidants

The effect of iron (FeCl3) on chlorophyll content, lipid peroxidation product, potassium ion leakage (a measure of damage to the permeability barrier), and antioxidants was studied in Hydrilla verticillata. The effect of iron-induced damage to the plant was compared with those of N-ethyl maleimide (NEM), a sulfhydryl reagent, and cumene hydroperoxide (CHP), an organic peroxide known to induce lipid peroxidation by free radical formation. The level of lipid peroxidation product was increased in the plants treated with Fe, CHP, and CHP + NEM but not with NEM alone. A significant increase in potassium ion leakage to the external solution was observed by the addition of Fe, CHP, and CHP + NEM, while this did not increase significantly in NEM-treated plants. When NEM and CHP were added simultaneously, the results were the same as those obtained with high iron concentrations, suggesting a combined effect of thiol depletion and lipid peroxidation by Fe ions. In addition, the results indicated loss of glutathione (GSH) and increased oxidized glutathione (GSSG) under Fe stress, indicative of oxidative stress. The oxidative stress may increase the production of free radicals and subsequently resulted in peroxidation of lipids. Further, addition of iron increased the activity of superoxide dismutase (SOD) which may be due to enhanced production of oxygen free radical and related tissue damage. The results suggest that iron-induced damage in plants can be ascribed to a direct metal action on thiols and by toxic oxygen species. An increase in lipid peroxidation product and K+ leakage are the primary responses of iron toxicity on membrane damage. However, the decrease in chlorophyll content is part of the overall expression of iron toxicity.

Membrane disposition of the M5-M6 hairpin of Na+,K(+)-ATPase alpha subunit is ligand dependent

Extensive proteolytic digestion of Na+,K(+)-ATPase (EC 3.6.1.37) by trypsin produces a preparation where most of the extramembrane portions of the alpha subunit have been digested away and the beta subunit remains essentially intact. The fragment Gln-737-Arg-829 of the Na+,K(+)-ATPase alpha subunit, which includes the putative transmembrane hairpin M5-M6, is readily, selectively, and irreversibly released from the posttryptic membrane preparation after incubation at 37 degrees C for several minutes. Once released from the membrane, the fragment aggregates but remains water soluble. Occlusion of K+ or Rb+ specifically prevents release of the Gln-737-Arg-829 fragment into the supernatant. Labeling of the posttryptic membrane preparation with cysteine-directed reagents revealed that Cys-802 (which is thought to be located within the M6 segment) is protected against the modification by Rb+ while this fragment is in the membrane but can be readily modified upon release. Cation occlusion apparently alters the folding and/or disposition of the M5-M6 fragment in the membrane in a way that does not occur when the fragment migrates to the aqueous phase. The ligand-dependent disposition of the M5-M6 hairpin in the membrane along with recent labeling studies suggest a key role for this segment in cation pumping by Na+,K(+)-ATPase.

Immunomodulatory activities of extracellular metallothionein. I. Metallothionein effects on antibody production

Extracellular metallothionein (Zn,Cd-MT) has previously been shown to be a potent inducer of lymphocyte proliferation and to synergize with polyclonal activators in proliferation assays. In this report, the effects of metallothionein on the development of humoral responsiveness are examined. In vivo, the specific anti-ovalbumin (OVA) IgG response was diminished by co-injection of Zn, Cd-MT, while total IgG levels remained unchanged. A similar reduction was also observed when Zn,Cd-MT was administered during the development of an anti-sheep red blood cell (sRBC) humoral response. When amounts of Zn and Cd equimolar to that associated with the Zn, Cd-MT were co-injected with OVA, humoral responsiveness was enhanced, in contrast to the suppression seen with Zn, Cd-MT. Apothionein lacking the available thiols associated with native Zn, Cd-MT had no effect on the development of humoral immunity. These results point to the thiols associated with the protein as the important determinants in the observed immunosuppression and this is supported by the capacity of UC1MT, a new monoclonal anti-MT antibody, to reverse MT mediated immunosuppression. No evidence was found to suggest that Zn,Cd-MT was interacting directly with OVA. Finally, in vitro experiments with LPS-stimulated splenocyte production of IgM correlated with the in vivo observations of Zn,Cd-MT. These data provide evidence for a significant role for MT in the development of metal-mediated immunomodulation and suggest that MT may also possess immunomodulatory functions under circumstances where MT is synthesized in the absence of heavy metal stress. Furthermore, it may be possible to take advantage of this system to exogenously manipulate the development of the immune response.

Effects of 2-mercaptoethanol and buthionine sulfoximine on cystine metabolism by and proliferation of mitogen-stimulated human and mouse lymphocytes

Cysteine is an essential amino acid for lymphocytes and its anabolic products are intimately involved in lymphocyte activation. The purpose of this study was to assess the uptake and subsequent utilization of cyst(e)ine by mitogen-stimulated human peripheral blood mononuclear cells (PBMC), to evaluate the effect of an exogenous thiol, 2-mercaptoethanol (2ME), on these processes, and to compare human and mouse lymphocyte reactivities. Unlike mouse lymphocytes, the proliferation of human T-cells was inhibited by addition of 2ME although 2ME enhanced cystine uptake. Optimal responses to T-cell mitogens (Con A and PHA) were obtained with a cystine concentration of greater than or equal to 25 and 200 microM for human and mouse cells, respectively, and 2ME enhanced DNA synthesis of Con A-stimulated mouse cells regardless of the cystine dose; however, 2ME enhanced the response of human cells only in the presence of suboptimal doses of cystine. To assess whether 2ME's inability to enhance human PBMC responses was related to their glutathione (GSH) content, the human PBMC were pretreated with buthionine sulfoximine (BSO, an inhibitor of GSH synthesis). Even when the initial intracellular GSH concentration was lowered to below that of mouse lymphocytes, 2ME still inhibited proliferation. In contrast, addition of 2ME to human PBMC maintained in the presence of BSO enhanced the proliferative response suggesting that a critical level of thiols is needed for proliferation. The ability of 2ME to enhance proliferative responses in cystine deficient medium supports this contention. Consistent with thiol involvement in activation, Con A increased [35S]cystine uptake 2-fold within 4 h of incubation and enhanced subsequent conversion of cystine into cysteine and GSH. Interestingly, BSO treatment only slightly inhibited Con A-induced protein synthesis (5%), but it significantly suppressed conversion of cystine into cysteine or GSH (80-95%) and blocked DNA synthesis (90%). Overall, the results indicate that various differential thiol characteristics must exist between human and mouse lymphocytes and that a reducing equivalent is necessary for DNA synthesis but not lymphocyte activation.

Extracellular metallothionein effects on lymphocyte activities

Metal cation influences on the immune response have been reported in a wide variety of experimental systems. These influences can either result in the augmentation or suppression of immunological activities. In order to investigate possible mechanisms of these influences, we examined the role that a metal cation-induced protein, metallothionein (MT), might play. Our findings suggest that thioneins, either as apoproteins or when complexed as Cd,Zn-MT, Zn-MT, or Cd-MT, are capable of inducing lymphocyte proliferation. This level of induction is substantially reduced when Zn,Cd-MT is added to lymphocyte cultures in the presence of 50 microM 2-mercaptoethanol. Apoprotein, Zn,Cd-MT, Zn-MT and Cd-MT also augment LPS-induced proliferation of splenic lymphocytes. Only the Zn,Cd-MT preparation significantly augmented ConA-induced proliferation. Hg-MT and Cu-MT were inhibitory as additions in either LPS or ConA mitogen proliferation assays, and did not stimulate proliferation when added alone to lymphocyte cultures. The capacity to induce proliferation correlates with the measurable thiol level of the particular thionein. Interestingly, Zn,Cd-MT and apothionein had an equivalent number of accessible thiols. Although Zn, Pb, Hg and Cu lowered the number of these sites, the immunoreactivity of these MTs was not altered substantially except by Pb. These results suggest that some metal influences on lymphocytes might be through a thionein intermediary. Our results also demonstrate that thioneins complexed with certain metal cations are detrimental to the normal cellular activities of lymphocytes. At least in these circumstances, MT does not play a role as a protective agent.

Glutathione measurement by high-performance liquid chromatography separation and fluorometric detection of the glutathione-orthophthalaldehyde adduct

Glutathione reacts with orthophthalaldehyde to form a stable, highly fluorescent tricyclic derivative which is easily separated and quantitated by high-performance liquid chromatography. Separation of the glutathione adduct is achieved by isocratic elution over a reverse-phase column with 7.5% methanol/92.5% 0.15 M sodium acetate, pH 7.00. The adduct is detected fluorometrically and quantitated by integration of peak area. Detection of 0.1 to 200 pmol glutathione produces a linear response and the recovery of reduced and oxidized glutathione from rat liver homogenate, bile, and plasma is quantitative. The chemical identity of the adduct was confirmed by mass spectrometry.

Measurement of cyst(e)amine in physiological samples by high performance liquid chromatography

Two methods for measurement of cyst(e)amine in physiological samples are described. One method involves reduction of disulfides present in the sample with tributylphosphine, reversed phase chromatography of thiols, and electrochemical detection of cysteamine and other thiols. The other method involves reduction of disulfides with dithiothreitol, derivatization of thiols with 7-diethylamino-3-(4'-maleimidylphenyl)-4-methylcoumarin, separation of these derivatives by reversed phase chromatography, and fluorometric detection of the thiol adducts. The endogenous concentration of cysteamine in rat liver was estimated to be less than 2.5 nmol/g. Cysteamine is produced in tissues postmortem; rapid sampling/freezing of tissues and rapid inactivation of enzymes during tissue preparation are essential for accurate measurement of endogenous cysteamine concentrations.

Four sulfhydryl-modifying compounds cause different structural damage but similar functional damage in murine lymphocytes

Four thiol-modifying compounds were used to inhibit murine lymphocyte mitogenesis. The compounds were a copper sulfate/O-phenanthroline complex (CuP) to oxidize surface thiols, N-ethyl maleimide (NEM) to alkylate surface and intracellular thiols, D,L-buthionine-S,R-sulfoximine (BSO) to prevent synthesis of glutathione, and hydrogen peroxide, which reacts with various cellular constituents, including sulfhydryls. Splenic lymphocytes were incubated with one of the four compounds, washed, and then stimulated with the B cell mitogen, LPS, or the T cell mitogen, Con A. In spite of their differing chemical reactivities and differing effects on cell viability, lipids, and total, protein, and non-protein thiols, the four sulfhydryl-modifying compounds had very similar effects on the kinetics and inhibition of lymphocyte growth. All compounds had complex effects on mitogenesis, causing enhanced, delayed, or inhibited tritiated thymidine incorporation. Although the total thiol contents of untreated T cells and B cells were found to be equivalent, the LPS response consistently was inhibited by lower concentrations than the Con A response, suggesting that B cells were more sensitive than T cells to thiol modification. To compare compounds the efficiency of inhibition was determined by functionally relating reductions in mitogenesis with reductions in thiol content of the cells. The compounds differed in inhibitory efficiency; thus, damage to some thiols must be more important than damage to others. CuP ablated mitogenesis with the least change in thiol content. Therefore, surface sulfhydryls appear critical in lymphocyte mitogenesis. With all compounds inhibition of mitogenesis occurred over a very narrow range of thiol content, suggesting that the thiols important in inhibition were few in number relative to the total thiol content of the cell.

Differential inhibition of human T-lymphocyte activation by maleimide probes

Cellular thiols are known to be involved in lymphocyte activation, differentiation, and growth. In theory, alkylation of selective cellular thiols could be used to regulate specific processes in the activation sequence by inactivating particular enzymes or structural proteins, although to date specific alkylating probes have not been reported. N-Ethylmaleimide (NEM) is a lipophilic sulfhydryl-alkylating agent that is known to block the in vitro proliferative response of T lymphocytes. NEM (10 microM) was found to be fully inhibitory in PHA, Con A, and MLC assays only when added prior to or simultaneously with the mitogens or allogeneic cells; the addition of NEM only 15 sec after stimulating the cells with PHA resulted in a loss of greater than 50% of the inhibitory activity. The addition of 50 microM 2-ME 10 min after treating the cells with NEM failed to block the inhibitory effect. NEM (10-20 microM) had no adverse effect on lymphocyte viability, but completely blocked lymphocyte agglutination in response to mitogens or allogeneic cells. The lymphocytes overcame the inhibitory effects of NEM after 48 hr in both the PHA and MLC experiments. Resumption of the proliferative response was associated with the onset of agglutination in the PHA assay. In experiments using various analogs of NEM, we noted that the presence of a nonpolar N-linked side group was necessary for inhibitory activity. Pretreatment of PBMC with NEM decreased the total cellular thiols by 50% and blocked proliferation by 99%, whereas N-hydroxymaleimide decreased the total cellular thiols by 38% but had no effect on the proliferative response. The additional 12% of the cellular thiols that react with NEM, but not NHM, account for the inhibitory effect of NEM on lymphocyte proliferation. These findings suggest that selective cellular thiols are critical for T-cell activation.