Highly tunable thiosulfonates as a novel class of cysteine protease inhibitors with anti-parasitic activity against Schistosoma mansoni

The development of a new class of cysteine protease inhibitors utilising the thiosulfonate moiety as an SH specific electrophile is described. This moiety has been introduced into suitable amino acid derived building blocks, which were incorporated into peptidic sequences leading to very potent i.e. sub micromolar inhibitors of the cysteine protease papain in the same range as the vinyl sulfone based inhibitor K11777. Therefore, their inhibitory effect on Schistosoma mansoni, a human blood parasite, that expresses several cysteine proteases, was evaluated. The homophenylalanine side chain containing compounds 27-30 and especially 36 showed promising activities compared with K11777 and warrant further investigations of these peptidic thiosulfonate inhibitors as new potential anti-parasitic compounds.

The gene expression profile of a drug metabolism system and signal transduction pathways in the liver of mice treated with tert-butylhydroquinone or 3-(3'-tert-butyl-4'-hydroxyphenyl)propylthiosulfonate of sodium

Tert-butylhydroquinone (tBHQ) is a highly effective phenolic antioxidant used in edible oils and fats in foods as well as in medicines and cosmetics. TBHQ has been shown to have both chemoprotective and carcinogenic effects. Furthermore, it has potential anti-inflammatory, antiatherogenic, and neuroprotective activities. TBHQ induces phase II detoxification enzymes via the Keap1/Nrf2/ARE mechanism, which contributes to its chemopreventive functions. Nonetheless, there is growing evidence that biological effects of tBHQ may be mediated by Nrf2-independent mechanisms related to various signaling cascades. Here, we studied changes in gene expression of phase I, II, and III drug metabolizing enzymes/transporters as well as protein levels and activities of cytochromes P450 (CYPs) elicited by tBHQ and its structural homolog TS-13 in the mouse liver. Next, we carried out gene expression analysis to identify signal transduction pathways modulated by the antioxidants. Mice received 100 mg/kg tBHQ or TS-13 per day or only vehicle. The liver was collected at 12 hours and after 7 days of the treatment. Protein and total RNA were extracted. Gene expression was analyzed using Mouse Drug Metabolism and Signal Transduction PathwayFinder RT2Profiler™PCR Arrays. A western blot analysis was used to measure protein levels and a fluorometric assay was employed to study activities of CYPs. Genes that were affected more than 1.5-fold by tBHQ or TS-13 treatment compared with vehicle were identified. Analysis of the gene expression data revealed changes in various genes that are important for drug metabolism, cellular defense mechanisms, inflammation, apoptosis, and cell cycle regulation. Novel target genes were identified, including xenobiotic metabolism genes encoding CYPs, phase II/III drug metabolizing enzymes/transporters. For Cyp1a2 and Cyp2b, we observed an increase in protein levels and activities during tBHQ or TS-13 treatment. Changes were found in the gene expression regulated by NFκB, androgen, retinoic acid, PI3K/AKT, Wnt, Hedgehog and other pathways.

THE SEARCH OF COMPOUNDS WITH ANTIAGGREGATION ACTIVITY AMONG S-ESTERS OF THIOSULFONIC ACIDS

According to the current understanding, the hyperactivation of platelets may lead to increased intravascular coagulation and thrombosis. Today a relevant issue is the search for new anti-thrombotic agents that are able to modulate the activity of platelet receptors, thus, influence the processes of activation and aggregation of platelets. The aim of this study was to investigate the effects of newly synthesized thiosulfonate derivatives on platelet aggregation. The activity of the compounds was tested in vitro using platelet-rich plasma. As a result of the screening test, structural formulas of four agents with high antiaggregative activity were established. These compounds inhibited ADP- and collagen-induced platelet aggregation in a dose-dependent manner. Two of these compounds were shown to be more effective inhibitors of aggregation induced by ADP (IC50 - 8-10 μM), as well as collagen (IC50 - 1.5-2.0 μM).

[Phenolic antioxidant TS-13 regulating ARE-dependent genes induces tumor cell death by mitochondria-dependent pathway]

Effects of water-soluble phenolic antioxidant sodium 3-(3'-tret-butyl-4'-hydroxyphenyl)-propyl thiosulfonate (TS-13), potassium 3,5-dimethyl-4-hydroxybenzyl thioetanoate (BEP-11-K) and potassium 3-(3',5'-ditretbutyl-4'-hydroxyphenyl)-propionate (potassium phenosan) on tumor cells proliferative activity and the role of redox-dependent and calcium-dependent signaling mechanisms in realization of tumor cell response to the antioxidant action were studied. Potassium phenosan and BEP-11-K were found to stimulate proliferation and ARE-inducing phenolic antioxidant TS-13 was found to inhibit tumor cell growth in culture. The tumor cell growth rate depended on the rate of intracellular reactive oxygen species production and was decreased by apocynin (a NADPH-oxidase inhibitor) and antimycin A (an ubiquinol-cytochrome c oxidoreductase inhibitor). TS-13 action on tumor cells was accompanied by a transient increase in intracellular reactive oxygen species production and the intracellular calcium concentration, whereas cell incubation with potassium phenosan and BEP-11-K did not influence the reactive oxygen species level and intracellular calcium ions. Cyclosporine A blocked the inhibitory effect of TS-13. Thus, it can be reasonably speculated that phenolic antioxidant TS-13 starts mitochondria-dependent apoptosis in tumor cells by the opening of permeability transition pores.

[Effect of antioxidant responsive element inducing phenol on D. melanogaster life span]

The effect of water-soluble synthetic antioxidant TS-13 (sodium 3-(3'-tert-butyl-4'-hydroxyphenyl) propyl thiosulfonate) on life span of different lines of Drosophila melanogaster under normal conditions and survival under oxidative stress induced by hydrogen peroxide and paraquat has been investigated. Introduction to the diet of 1% TS-13 prolonged the life span of males and females of D. melanogaster long-living line Canton S, had no effect on short-living Oregon R life span and reduced the life span of male D. melanogaster line IgI(558)OR/Cy, heterozygous on tumor suppressor recessive lethal mutation. When flies were exposed to hydrogen perexide, TS-13 significantly enhanced Canton Smale and Oregon R female survival. Under the influence of paraquat antioxidant protected Canton S female and Oregon R flies of both sexes. Despite the fact that the anti-aging and protective properties of synthetic phenol antioxidant TS-13 depend essentially on the genotype and gender, in the extreme conditions of oxidative stress its positive effect pronounced.

[Variability of the exogenic antioxidant effect on survival: modeling in Drosophila lines with different lifespan and l(2)gl-tumor suppressor dosage]

Different exogenic antioxidants and geroprotectors are used to decrease age abnormalities and enhance the human life span. However, the antioxidant effect on lifespan is variable and requires detailed analysis. In the present report, we modeled in Drosophila the peculiar character of action of various doses of a new phenol antioxidant TC-13. We studied the TC-13 effect on aging of two Drosophila lines with genetically determined contrast lifespan dynamics. In addition, we tested the TC-13 antioxidant influence on the background of heterozygozity on the loss-of-function mutation of the l(2)gl tumor suppressor. The differing effect of TS-13 on LS, the character of which depends on the antioxidant dosage, genotype of line, and sex of Drosophila, was found. TS-13 in the concentration 0.2% did not affect the lifespan in all studied lines and decreased survival, whereas the antioxidant in a concentration of 1% positively affected the lifespan in both males and females of long-living lines. The antioxidant effect on animal lines with a smaller dose of tumor suppressor l(2)gl resulted in a decrease of the lifespan.

Cysteine and glutathione mixed-disulfide conjugates of thiosulfinates: chemical synthesis and biological activities

The chemical syntheses of cysteine (CYS) and glutathione (GSH) mixed -disulfide conjugates (CySSR, GSSR, respectively) of mercapto residues representing most of the R groups of thiosulfinates (R = methyl, ethyl, propyl, and allyl) are described. Gram-scale conjugates were prepared as >98% pure preparations, with 80% reaction yield for each of the two seminal synthesis steps, with structures confirmed by (1)H NMR and high-resolution MS analyses. These conjugates are derivatives of thiosulfinates that may be evolved in processed foods, in the digestive tract, and through in vivo metabolism. The prepared conjugates were found to be able to induce quinone reductase (QR, a representative phase II enzyme) in murine hepatoma cells (Hepa 1c1c7) and to inhibit nitric oxide (NO) production in lipopolysaccharide (LPS)-stimulated macrophage cells (RAW 264.7), indicating they have potential cancer preventive and anti-inflammatory activities. Among the prepared conjugates, the allyl conjugates of CYS and GSH, S-allylmercaptocysteine (CySSA) and S-allylmercaptoglutathione (GSSA), showed the most potent activity regarding QR induction and NO production inhibition. The conjugates with saturated R groups were also active and conferred biological activity as cystine and oxidized glutathione exhibited no effects in these cellular assays.

Thiosulfinates modulate platelet activation by reaction with surface free sulfhydryls and internal thiol-containing proteins

Thiosulfinates are characteristic flavors of Allium vegetables, with a highly reactive S-S=O group, that we previously showed to inhibit platelet aggregation through calpain-dependent mechanisms. With the aim to clarify the mode of action of these redox phytochemicals, we studied their effect on extracellular free sulfhydryls in relation to their effect on platelet responses (Ca2+ signals, release reaction, and aIIb3 integrin activation state). At the platelet surface, thiosulfinate dose-dependently increased the basal level of free sulfhydryls, independently of protein disulfide isomerase activity. This generation of new free sulfhydryls was associated with: (i) a three fold increase in labeling of resting platelets with an anti ligand-induced binding site antibody and (ii) marked inhibition of subsequent aIIb3 activation by agonists. Thiosulfinates increased the basal intracellular Ca2+ level of platelets. In activated platelets, they markedly inhibited the Ca2+ mobilization independently of the external Ca2+, the calpain-induced SNAP-23 cleavage and the granule release. In platelet free systems, thiosulfinates inhibited the activity of purified calpain and the free sulfhydryl of glutathione without any reducing properties on disulfides. The results demonstrate for the first time that thiosulfinates rapidly interact with sulfhydryls both at the platelet surface and inside the cell on intracellular cysteine-proteins, especially calpain. Inhibition of free cysteine and glutathione in whole blood may also contribute to their anti-aggregant properties. Such sulfur compounds are of interest for the development of a new class of antithrombotic agents.

N-thiolated beta-lactams: Studies on the mode of action and identification of a primary cellular target in Staphylococcus aureus

This study focuses on the mechanism of action of N-alkylthio beta-lactams, a new family of antibacterial compounds that show promising activity against Staphylococcus and Bacillus microbes. Previous investigations have determined that these compounds are highly selective towards these bacteria, and possess completely unprecedented structure-activity profiles for a beta-lactam antibiotic. Unlike penicillin, which inhibits cell wall crosslinking proteins and affords a broad spectrum of bacteriocidal activity, these N-thiolated lactams are bacteriostatic in their behavior and act through a different mechanistic mode. Our current findings indicate that the compounds react rapidly within the bacterial cell with coenzyme A (CoA) through in vivo transfer of the N-thio group to produce an alkyl-CoA mixed disulfide species, which then interferes with fatty acid biosynthesis. Our studies on coenzyme A disulfide reductase show that the CoA thiol-redox buffer is not perturbed by these compounds; however, the lactams appear to act as prodrugs. The experimental evidence that these beta-lactams inhibit fatty acid biosynthesis in bacteria, and the elucidation of coenzyme A as a primary cellular target, offers opportunities for the discovery of other small organic compounds that can be developed as therapeutics for MRSA and anthrax infections.

Bruguiesulfurol, a new sulfur compound from Bruguiera gymnorrhiza

A new cyclic 4-hydroxy-dithiosulfonate, bruguiesulfurol (1), as well as two known 4-hydroxydithiolane 1-oxides, brugierol (2) and isobrugierol (3) were isolated from the flowers of Bruguiera gymnorrhiza. With stably-transfected HepG2 cells, the three isolates activated antioxidant response element (ARE) luciferase activation with (EC(50)) values of 56.7, 3.7 and 1.8 microM, respectively. Compounds 2 and 3 also inhibited phorbol ester-induced NF-kappaB (nuclear factor-kappaB) luciferase activity with IC (50) values of 85.0 and 14.5 microM, respectively. In addition, compound 2 inhibited enzyme cyclooxygenase-2 (COX-2) activity with an IC(50) value of 6.1 microM. The structures of these isolates were determined by spectral data, and that of compound 1 was confirmed by X-ray crystallographic analysis.

Evidence of both extra- and intracellular cysteine targets of protein modification for activation of RET kinase

By use of a specifically sulfhydryl group-reactive chemical, 1,4-butanediyl-bismethanethiosulfonate (BMTS), we studied the localization of oxidative stress-responsive target cysteines for activation of a receptor-type protein tyrosine kinase, c-RET. The chemical, which reacted with RET proteins on the cell surface for sulfhydryl-linked aggregation, induced autophosphorylation and activation of RET kinase. When extracellular domain-deleted RET mutant (RET-PTC-1) cells were exposed to BMTS, neither the molecular status nor the activity of the enzyme was affected, suggesting that the target cysteines of BMTS to which cells were exposed for reaction are located in the cysteine-rich region of the extracellular domain of RET kinase. Despite this result, the exposure of a subcellular form of c-RET or RET-PTC-1 kinase isolated by immunoprecipitation to BMTS did induce activation of the enzyme. These results suggest that cysteines in both the extracellular and the intracellular domains of RET can work as target sites of accessible BMTS and possibly other oxidative elements for structural modification and activation of RET kinase.

Side chain orientation in the selectivity filter of a voltage-gated Ca2+ channel

Four glutamate residues (EEEE locus) are essential for ion selectivity in voltage-gated Ca(2+) channels, with ion-specific differences in binding to the locus providing the basis of selectivity. Whether side chain carboxylates or alternatively main chain carbonyls of these glutamates project into the pore to form the ion-binding locus has been uncertain. We have addressed this question by examining effects of sulfhydryl-modifying agents (methanethiosulfonates) on 20 cysteine-substituted mutant forms of an L-type Ca(2+) channel. Sulfhydryl modifiers partially blocked whole oocyte Ba(2+) currents carried by wild type channels, but this block was largely reversed with washout. In contrast, each of the four EEEE locus glutamate --> cysteine mutants (0 position) was persistently blocked by sulfhydryl modifiers, indicating covalent attachment of a modifying group to the side chain of the substituted cysteine. Cysteine substitutions at positions immediately adjacent to the EEEE locus glutamates (+/-1 positions) were also generally susceptible to sulfhydryl modification. Sulfhydryl modifiers had lesser effects on channels substituted one position further from the EEEE locus (+/-2 positions). These results indicate that the carboxylate-bearing side chains of the EEEE locus glutamates and their immediate neighbors project into the water-filled lumen of the pore to form an ion-binding locus. Thus the structure of the Ca(2+) channel selectivity filter differs substantially from that of ancestral K(+) channels.

Effect of sulfhydryl reagents on the regulatory system of the L-type Ca channel in frog ventricular myocytes

The effects of sulfhydryl (SH) reagents on the L-type Ca current (ICa) were studied in frog ventricular myocytes using the whole-cell patch-clamp method. Methanethiosulfonate ethylammonium (MTSEA+) was found to enter the cell through the membrane and cause a remarkable increase in Ica from the intracellular side. Methanethiosulfonate ethyltrimethylammonium (MTSET+) and methanethiosulfonate ethylsulfonate (MTSES-) could not penetrate the membrane and were effective only when directly applied to the intracellular side. In addition, suppressive effects on ICa of these MTS reagents were indicated by the following observation. A progressive decay in the peak amplitude of ICa after establishing maximal ICa, stimulated by intracellular MTSET+, was prevented by adding extracellular dithiothreitol (DTT). The SH-oxidizing agents N-ethylmaleimide (NEM), chloramine-T (CL-T), 2,2'-dithiodipyridine (DTDP) and 2,2'-dithio-bis-5-nitropyridine (DTBNP) also exerted a stimulatory effect on Ica. The effect of SH reagents persisted even when cAMP production was inhibited with Rp-cAMP-S, or when G-protein was inhibited with 1 mM GDPbetaS, indicating that the effect is not due to cAMP production or G-protein stimulation. It is concluded that there are sites on the Ca channels that are subject to direct modification by SH reagents.

Altering the specificity of subtilisin Bacillus lentus through the introduction of positive charge at single amino acid sites

The use of methanethiosulfonates as thiol-specific modifying reagents in the strategy of combined site-directed mutagenesis and chemical modification allows virtually unlimited opportunities for creating new protein surface environments. As a consequence of our interest in electrostatic manipulation as a means of tailoring enzyme activity and specificity, we have recently adopted this approach for the controlled incorporation of multiple negative charges at single sites in the representative serine protease, subtilisin Bacillus lentus (SBL). We now describe the use of this strategy to introduce multiple positive charges. A series of mono-, di- and triammonium methanethiosulfonates were synthesized and used to modify cysteine mutants of SBL at positions 62 in the S2 site, 156 and 166 in the S1 site and 217 in the S1' site. Kinetic parameters for these chemically modified mutants (CMM) enzymes were determined at pH 8.6. The presence of up to three positive charges in the S1, S1' and S2 subsites of SBL resulted in up to 77-fold lowered activity, possibly due to interference with the histidinium ion formed in the transition state of the hydrolytic reactions catalyzed.

Restoration of fast inactivation in an inactivation-defective human heart sodium channel by the cysteine modifying reagent benzyl-MTS: analysis of IFM-ICM mutation

It has been suggested that the region linking domain III and IV of voltage-gated sodium channels forms the inactivation gate. A combination of site-directed mutagenesis, cysteine covalent modification, and electrophysiological recording techniques was used to identify the role of the Phe1486, a conserved phenylalanine residue located in the III-IV linker of Na+ channels. This Phe1486 is part of a hydrophobic amino acid cluster (IFM) that was proposed to play an essential role in the fast inactivation of voltage-gated sodium channels. Expression in tsA201 cells of an altered human heart 1 Na+ channel (hH1/F1486C) in which Phe1486 was replaced by a cysteine is associated with the appearance of a residual current, a loss of voltage-dependence of the time constants of inactivation, a shift of the steady-state inactivation to more depolarized voltages, and a recovery from inactivation that is faster than the wild-type hH1. Exposure of the cytoplasmic surface of mutant F1486C to the methanthiosulfonate reagents, MTSEA, MTSET, and MTSES, further disrupted macroscopic inactivation, but exposure to MTSBN completely restores fast inactivation and the voltage-dependence of fast inactivation. These findings support the formulation that the IFM motif of the III-IV-linker of voltage-gated sodium channels serves as an essential component of the inactivation particle and that the phenyl group of Phe1486 may play a crucial role in inactivation gate closure.

Species-specific inhibition of homologous enzymes by modification of nonconserved amino acids residues. The cysteine residues of triosephosphate isomerase

The possibility of using non-conserved amino acid residues to produce selective inhibition of homologous enzymes from different species has been further explored with triosephosphate isomerase. S-phenyl-p-toluenethiosulfonate (MePhSO2-SPh), which produces phenyl disulfides with accessible Cys residues, inhibits the activity of rabbit triosephosphate isomerase. The inhibition is due to derivatization of one of the five Cys residues of rabbit triosephosphate isomerase. The effect of MePhSO2-SPh on triosephosphate isomerase from Saccharomyces cerevisiae, Escherichia coli, chicken and Schizosaccharomyces pombe was also determined. MePhSO2-SPh did not affect the activity of triosephosphate isomerase from S. cerevisiae and E. coli but it inhibited triosephosphate isomerase from chicken and S. pombe. From an analysis of the Cys content of the various triosephosphate isomerases, it was evident that amongst the ones studied only those that have a Cys in position 217 (or in an equivalent position) were sensitive to MePhSO2-SPh. Methyl metanethiosulfonate (MeSO2-SMe), which produces methyl disulfides, had no effect on triosephosphate isomerases that lack Cys217 (S. cerevisiae and E. coli). In triosephosphate isomerases that have Cys217, MeSO2-SMe inhibited by 40-50% the activity of that from S. pombe, 20-25% that from rabbit but had no effect on the chicken enzyme. In the three latter triosephosphate isomerases, MeSO2-SMe protected against the strong inhibiting action of MePhSO2-SPh. The latter observations suggest that MeSO2-SMe and MePhSO2-SPh derivatize the same Cys and that significant inhibition of activity requires perturbation by the relatively large phenyl group. The intrinsic fluorescence of rabbit triosephosphate isomerase that had been derivatized to a phenyl disulfide was almost identical to that of the native enzyme. Thus, modification of Cys217 did not produce gross structural alterations, albeit it brought about important kinetic alterations, i.e. a nearly fivefold increase in the K(m) for glyceraldehyde 3-phosphate and a 65% decrease in Vmax. The effect of derivatizating Cys217 differs markedly from that produced by derivatization of Cys14 (another non-conserved cysteine). The differences may be explained from their position in the three-dimensional structure of the enzyme.

Use of methanethiolation to investigate the catalytic role of sulphydryl groups in rabbit skeletal muscle pyruvate kinase

Incubation of rabbit skeletal muscle pyruvate kinase (ATP:pyruvate 2-O-phosphotransferase, EC 2.7.1.40) with methyl methanethiosulphonate resulted in the time- and inhibitor concentration-dependent loss of enzyme activity. Substrates or products of the catalytic reaction prevented the loss of activity caused by methanethiolation. Their effectiveness as protecting agents was placed in the order ADP greater than ATP greater than Mg2+ greater than phosphoenolpyruvate greater than pyruvate. The essential catalytic cation, K+, had no effect on the methanethiolation reaction. [Me-3H]Methanethiosulphonate modified all the available cysteine thiol groups which correlated to the incorporation of four SC3H3 groups per protomer. Four radioactive peptides were obtained on tryptic peptide mapping. When methanethiolation was carried out in the presence of Mg2+ alone or with Mg2+ and ATP together, then only three SC3H3 groups were incorporated into each subunit. If MgATP protected methanethiolated pyruvate kinase was reacted with iodo[2-3H]acetic acid then 1.37 +/- 0.2 groups per protomer were carboxymethylated. 70% of the radioactivity was located in a single peptide on tryptic peptide mapping. This peptide was isolated and contained the segment carboxymethyl cysteine (Glx, Asx, Ser) Arg. Collectively these data indicate that although all thiol groups are equally accessible to methyl methanethiosulphonate, only a single thiol group participates in the catalytic event. An additional role in the maintenance of structure for this thiol group was also shown in studied of reduction and thermal denaturation of the enzyme.

Reactions of benzenesulfonohydrazides and benzenesulfonamides with hydrogen chloride or hydrogen bromide in acetic acid

Benzenesulfonohydrazides capable of yielding a sulfinic acid intermediate by virtue of a basic nitrogen atom in the second position of the hydrazide moiety produced thiosulfonates when treated with 1 N hydrogen chloride in acetic acid and produced disulfides when treated with 1 N hydrogen bromide in the same solvent. In two cases, a crystalline mixture of P-nitrophenyl p-nitrobenzenethiosulfonate and bis(p-nitrophenyl) disulfide was isolated from the hydrogen chloride reactions. No reaction product was obtained from either the hydrogen chloride or hydrogen bromide reaction with benzenesulfonohydrazides that were unable to form a sulfinic acid intermediate. Reduction of benzenesulfonamides to disulfides appeared to be possible only with hydrogen bromide in acetic acid. No thiosulfonate was isolated from the treatments of benzenesulfonamides with 1 N hydrogen chloride in acetic acid. p-Nitrophenyl p-nitrobenzenethiosulfonate and p-bromophenyl p-bromobenzenethiosulfonate exhibited some antimicrobial activities against Gram-positive bacteria. The latter compound also showed analgesic properties in the phenylquinone test.

Modification of pig heart lactate dehydrogenase with methyl methanethiosulphonate to produce an enzyme with altered catalytic activity

Methyl methanethiosulphonate was used to produce a modification of the essential thiol group in lactate dehydrogenase which leaves the enzyme catalytically active. Methyl methanethiosulphonate produced a progressive inhibition of enzyme activity, with 2mM-pyruvate and 0.14mM-NADH as substrates, which ceased once the enzyme had lost 70-90% of its activity. In contrast, with 10mM-lactate and 0.4mM-NAD+ as substrates the enzyme was virtually completely inhibited. The observed inhibition was critically dependent on the chosen substrate concentration, since methanethiolation with methyl methanethiosulphonate resulted in a large decrease in affinity for pyruvate. At 0.14mM-NADH, methanethiolation increased the apparent KmPyr from from 40micronM for the control enzyme to 12mM for the modified enzyme. Steady-state kinetics showed that there was not a statistically significant change in either KmNADH or KsNADH. At saturating NADH and pyruvate concentrations, the Vmax. was virtually unaffected for the methanethiolated enzyme. However, a decrease in Vmax. was observed when the modified enzyme was incubated in dilute solution. The modification of lactate dehydrogenase by methyl methanethiosulphonate involved the active site, since inhibition was completely prevented by substrate-analogue pairs such as NADH and oxamate or NAD+ and oxalate. The formation of complexes between methanethiolated lactate dehydrogenase and substrates or substrate analogues can also be shown by re-activation experiments. The methanethiolated enzyme was re-activated in a time-dependent reaction by dithiothreitol and this was prevented by oxamate, by NADH and by NADH plus oxamate in increasing order of effectiveness. The results of this work are interpreted in terms of a role for the essential thiol group in the binding of substrates.

Synthesis and preliminary antimicrobial screening of two thiosulfonates

Tetramethylene bis(methanethiosulfonate), the S-ester analog of busulfan, was prepared by reacting 1,4-dibromobutane with potassium methanethiosulfonate. 2,4-Dichlorophenyl methanethiosulfonate was prepared by reacting sodium methanesulfinate with 2,4-dichlorobenzenesulfenyl chloride. Neither compound showed antifungal activity against Microsporum audouini or Trichophyton mentagrophytes. Although tetramethylene bis(methanethiosulfonate) was more active against Staphylococcus aureus than was 2,4-dichlorophenyl methanethiosulfonate, neither compound was as active as the streptomycin control.