Effect of various detergents on protein migration in the second dimension of two-dimensional gels.

Two-dimensional gel electrophoresis (2D)1 is a powerful technique used to separate complex protein mixtures. The technique involves the separation of proteins by charge in the first dimension and by molecular weight in the second dimension. The effect of substituting various detergents for sodium dodecyl sulfate (SDS) in the second dimension (PAGE) was investigated. Individual C-10 through C-14 alkyl sulfates, C-11 through C-14 alkyl sulfonates, sodium N-lauroyl-N-methyl-taurine, N-lauroylsarcosine, sodium laurate, or benzyldimethyl-n-hexadecylammonium chloride were substituted for SDS in equilibration buffer, gel buffer, and upper running buffer. The cationic benzyldimethyl-n-hexadecylammonium chloride system was run with reversed polarity. Dramatic effects on protein migration from human mesothelial cell extracts were observed when different detergents were utilized. The C-12 (SDS) through C-14 alkyl sulfates and sulfonates resulted in anomalous migration of the simple epithelial keratins. Unlike SDS, the C-10 and C-11 alkyl sulfates and C-11 sulfonate resulted in gels in which the keratins were separated accurately with respect to their gene sequence-determined molecular weights. However, with these shorter chain alkyl sulfates and sulfonate, resolution was compromised, especially with respect to the high-molecular-weight polypeptides. The C-12 alkyl sulfate (SDS) and alkyl sulfonate provided the best resolution of polypeptides. Mixtures of C-11 sulfate and SDS resulted in gels with better sequence molecular weight estimates and high resolution. In addition, trace amounts of sodium tetradecyl sulfate/sodium heptadecyl sulfate in commercial SDS preparations had an effect on polypeptide resolution.     

Activity and flexibility of alcohol dehydrogenase in organic solvents

The oxidation of cinnamyl alcohol to cinnamaldehyde by horse liver alcohol dehydrogenase (LADH) was carried out in nearly anhydrous organic solvents and in solvents containing from 0.1 to 10% added water. In nearly anhydrous solvents containing less than 0.02% water, the oxidation rate increased as the water solubility in the solvent decreased, but the reaction did not require active LADH. Moreover, the highest activity in nearly anhydrous heptane was obtained by lyophilizing the enzyme from a solution of pH 2.0, even though LADH exhibits virtually no enzymatic activity in water at this pH. The catalytic activity of LADH was restored and increased dramatically as small amounts of water were added to each solvent. In conjunction with the activity measurements, electron paramagnetic resonance (EPR) spectroscopy and two active-site directed spin labels were used to examine solvent-dependent structural features of LADH. The EPR spectra indicated that LADH became more rigid as the dielectric constant of the solvent decreased. The degree of rigidity also depended on the pH from which the enzyme was lyophilized, indicating that the ionization state of the enzyme can have an important influence on its dynamics in organic solvents. Finally, adding 1% water to organic solvents had no apparent effect on the enzyme's conformation or flexibility near the spin label, even though enzyme activity was an order of magnitude higher when 1% water was present.     

Moonlighting protein in Starkeyomyces koorchalomoides: Characterization of dihydrolipoamide dehydrogenase as a protein acetyltransferase utilizing acetoxycoumarin as the acetyl group donor

In this report we have identified for the first time a transacetylase (TAase) in a mesophilic fungi Starkeyomyces koorchalomoides catalyzing the transfer of acetyl group from polyphenolic acetate (PA) to a receptor protein glutathione S-transferase (GST). An elegant assay procedure was established for TAase based on its ability to mediate inhibition of GST by 7,8-diacetoxy-4-methylcoumarin (DAMC), a model PA. Utilizing this assay procedure, S. koorchalomoides TAase was purified to homogeneity. TAase was found to have MW of 50 kDa. The purified enzyme exhibited maximum activity at 45 °C at pH 6.8. The N-terminal sequence of purified fungal TAase (ANDASTVED) showed identity with corresponding N-terminal sequence of dihydrolipoamide dehydrogenase (LADH), a mitochondrial matrix enzyme and an E3 component of pyruvate dehydrogenase complex (PDHC). TAase was found to have all the properties of LADH and avidly interacted with the anti-LADH antibody. TAase catalyzed acetylation of GST by DAMC was identified by LC–MS/MS and a single lysine residue (Lys-113) was found to be acetylated. Further, recombinant LADH from Streptococcus pneumoniae lacking lipoyl domain was found to exhibit little TAase activity, suggesting the role of lipoyl domain in the TAase activity of LADH. These observations bear evidence for the protein acetyltransferase activity of LADH. Such an activity of LADH can be attributed as a moonlighting function of the enzyme.     

Properties of a bacterial enzyme preparation of alkylsulfatase

A preparation of primary alkyl sulfatase was obtained from the culture of Pseudomonas species 2T/1. It can hydrolyze alkyl sulfates, which belong to anion surface-active compounds, to sulfate ion and fatty alcohol, and as a result the harmful for biosphere property of the surface activity is gone. pH and temperature of the incubation mixture, the presence of ions of some bivalent metals and components of synthetic detergents (SD), composition of the buffer mixture and substrate concentration affect the rate of sodium dodecylsulfate (SDS) hydrolysis. The alkyl sulfatase preparation is relatively stable. The maximum rate of SDS hydrolysis was found to be at 70 degrees C. The preparation catalyzes the hydrolysis of some alkyl sulfate homologues and industrial alkyl sulfates. The temperature optimum of the preparation is 40 degrees C, the pH-optimum is 8.0-9.0.     

Analysis of alkyl sulfates in protein solutions by isocratic and gradient ion chromatography

An ion-chromatographic analysis for separation and quantitation of long-chain alkyl sulfates in both commercial samples of sodium dodecyl sulfate (SDS) (lauryl sodium sulfate) and protein solutions was developed. The separation was performed on a hydrophobic resin-based column utilizing tetrabutylammonium hydroxide as an ion-pair reagent and acetonitrile as an organic modifier. Sensitive and selective detection of alkyl sulfates was achieved with an anion suppressor and a conductivity detector. Gradient elution with acetonitrile was developed for the detection of a broad range of alkyl chain lengths (C-10--C-20) at high sensitivity. Because of the wide linear range of this method (0.2-700 micrograms/ml), trace levels of C-10, C-14, C-16, C-18, and C-20 alkyl sulfates can be accurately measured in the presence of high concentrations of C-12 alkyl sulfate (SDS). Thus the alkyl sulfate purity of commercial SDS solutions can be accurately and precisely determined without any sample treatment. For analysis of alkyl sulfates from protein solutions, sample treatment consisted of a one-step ion-pair extraction prior to chromatographic resolution and quantitation. Alkyl sulfates from 2-150 micrograms/ml were recovered in high yield from wide variety of protein solutions.     

Molecular dynamics study of the structural basis of dysfunction and the modulation of reactive oxygen species generation by pathogenic mutants of human dihydrolipoamide dehydrogenase

Human dihydrolipoamide dehydrogenase (LADH, E3) is a component in the pyruvate-, alpha-ketoglutarate- and branched-chain ketoacid dehydrogenase complexes and in the glycine cleavage system. The pathogenic mutations of LADH cause severe metabolic disturbances, called E3 deficiency that often involve cardiological and neurological symptoms and premature death. Our laboratory has recently shown that some of the known pathogenic mutations augment the reactive oxygen species (ROS) generation capacity of LADH, which may contribute to the clinical presentations. A recent report concluded that elevated oxidative stress generated by the above mutants turns the lipoic acid cofactor on the E2 subunits dysfunctional. In the present contribution we generated by molecular dynamics (MD) simulation the conformation of LADH that is proposed to be compatible with ROS generation. We propose here for the first time the structural changes, which are likely to turn the physiological LADH conformation to its ROS-generating conformation. We also created nine of the pathogenic mutants of the ROS-generating conformation and again used MD simulation to detect structural changes that the mutations induced in this LADH conformation. We propose the structural changes that may lead to the modulation in ROS generation of LADH by the pathogenic mutations.     

Inactivation of Lipoamide Dehydrogenase by Cobalt(II) and Iron(II) Fenton Systems: Effect of Metal Chelators, Thiol Compounds and Adenine Nucleotides

Fe(II)-and Co(II)-Fenton systems (FS) inactivated the lipoamide reductase activity but not the diaphorase activity of pig-heart lipoamide dehydrogenase (LADH). The Co(II) system was the more effective as LADH inhibitor. Phosphate ions enhanced the Fe(II)-FS activity. EDTA, DETAPAC, DL-histidine, DL-cysteine, glutathione, DL-dithiothreitol, DL-lipoamide, DL-thioctic acid, bathophenthroline, trypanothione and ATP, but not ADP or AMP, prevented LADH inactivation. Reduced disulfide compounds were more effective protectors than the parent compounds. Mg ions counteracted ATP protective action. Glutathione and DL-dithiothreitol partially restored the lipoamide dehydrogenase activity of the Fe(II)-FS-inhibited LADH. DL-histidine exerted a similar action on the Co(II)-FS-inhibited enzyme. Ethanol, mannitol and benzoate did not prevent LADH inactivation by the assayed Fenton systems and, accordingly, it is postulated that site-specific generated HO'radicals were responsible for LADH inactivation. With the Co(II)-FS, oxygen reactive species other than HO, might contribute to LADH inactivation.     

Trypanosoma cruzi dihydrolipoamide dehydrogenase is inactivated by myeloperoxidase-generated "reactive species"

Dihydrolipoamide dehydrogenase (LADH) from Trypanosoma cruzi was inactivated by treatment with myeloperoxidase (MPO)-dependent systems. With MPO/H₂O₂/NaCl, LADH lipoamide reductase and diaphorase activities significantly decreased as a function of incubation time. Iodide, bromide, thiocyanide and chloride effectively supplemented the MPO/H₂O₂ system, KI and NaCl being the most and the least effective supplements, respectively. LADH inactivation by MPO/H₂O₂/NaCl and by NaOCl was similarly prevented by thiol compounds such as GSH, L-cysteine, N-acetylcysteine, penicillamine and N-(2-mercaptopropionyl-glycine) in agreement with the role of HOCl in LADH inactivation by MPO/H₂O₂/NaCl. LADH was also inactivated by MPO/NADH/halide, MPO/H₂O₂/NaNO₂ and MPO/NADH/NaNO₂ systems. Catalase prevented the action of the NADH-dependent systems, thus supporting H₂O₂ production by NADH-supplemented LADH. MPO inhibitors (4-aminobenzoic acid hydrazide, and isoniazid), GSH, L-cysteine, L-methionine and L-tryptophan prevented LADH inactivation by MPO/H₂O₂/NaNO₂. Other MPO systems inactivating LADH were (a) MPO/H₂O₂/chlorpromazine; (b) MPO/H₂O₂/monophenolic systems, including L-tyrosine, serotonin and acetaminophen and (c) MPO/H₂O₂/di- and polyphenolic systems, including norepinephrine, catechol, nordihydroguaiaretic acid, caffeic acid, quercetin and catechin. Comparison of the above effects and those previously reported with pig myocardial LADH indicates that both enzymes were similarly affected by the MPO-dependent systems, allowance being made for T. cruzi LADH diaphorase inactivation and the greater sensitivity of its LADH lipoamide reductase activity towards the MPO/H₂O₂/NaCl system and NaOCl.     

Periplasmic cold expression and one-step purification of human dihydrolipoamide dehydrogenase

Dihydrolipoamide dehydrogenase (LADH) is a FAD-linked subunit of alpha-ketoglutarate, pyruvate and branched-chain amino acid dehydrogenases and the glycine cleavage system. As an oxidoreductase it transfers electrons from the dihydrolipoic acid prosthetic group to the NAD(+) cofactor via its FAD center. Besides its physiological function it is capable of generating harmful reactive oxygen species (ROS) in pathological settings therefore it is implicated in neurodegeneration, ischemia-reperfusion, cancer and several other disorders. Pathological mutants of the enzyme cause severe, sometimes lethal syndromes like hypotonia, metabolic acidosis or inefficiency in development. Recently it has been revealed that LADH is a moonlighting protease when specific mutations in the dimerization surface destabilize the functional homodimer and expose a serine-protease-like catalytic dyad. As the basis of versatile functions of LADH is far from elucidation, there is a constant need for a pure and functional enzyme product for investigations. Several studies used recombinant human LADH before, however, it was generated by more complicated and/or physiologically less compatible protocols than reported here; most papers on functional and structural studies do not even report detailed protocols and characteristics (most importantly the purity) of their protein products. Here we describe the details of an optimized, easy-to-use periplasmic expression and one-step purification protocol for obtaining a highly pure, active and authentic (tag-cleaved) enzyme with the characterization of the protein product. The purified LADH can be used in biophysical and structural studies while the published protocol is easily convertible to a protein labeling procedure.     

In vivo inhibition of liver alcohol dehydrogenase by ethanol administration

The activity of liver alcohol dehydrogenase (LADH) from rats sacrificed two hours after the administration of ethanol 3, 4 or 5 g/kg intraperitoneally was significantly inhibited compared to the activity of LADH from control rats. LADH activity was inversely related to the dose of ethanol administered, to the concentration of ethanol in the liver, and to the concentration of ethanol in the blood. The clearance of blood ethanol in rats was dose-dependent and was inversely related to the dose administered. The half-life of ethanol elimination increased as the dose of ethanol increased. These results suggest that ethanol-induced inhibition of LADH can occur in vivo and that the level of activity of this enzyme determines the rate of oxidation of ethanol.     

pH-dependent substrate preference of pig heart lipoamide dehydrogenase varies with oligomeric state: response to mitochondrial matrix acidification

Cycling of intracellular pH has recently been shown to play a critical role in ischemia-reperfusion injury. Ischemia-reperfusion also leads to mitochondrial matrix acidification and dysfunction. However, the mechanism by which matrix acidification contributes to mitochondrial dysfunction, oxidative stress, and the resultant cellular injury has not been elucidated. We observe pH-dependent equilibria between monomeric, dimeric, and a previously undescribed tetrameric form of pig heart lipoamide dehydrogenase (LADH), a mitochondrial matrix enzyme. Dynamic light scattering studies of native LADH in aqueous solution indicate that lowering pH favors a shift in average molecular mass from higher oligomeric states to monomer. Sedimentation velocity of LADH entrapped in reverse micelles reveals dimer and tetramer at both pH 5.8 and 7.5, but monomer was observed only at pH 5.8. Enzyme activity measurements in reverse Aerosol OT micelles in octane indicate that LADH dimer and tetramer possess lipoamide dehydrogenase and diaphorase activities at pH 7.5. Upon acidification to pH 5.8 only the LADH monomer is active and only the diaphorase activity is observed. These results indicate a correlation between pH-dependent changes in the LADH reaction specificity and its oligomeric state. The acidification of mitochondrial matrix that occurs during ischemia-reperfusion injury is sufficient to alter the structure and enzymatic specificity of LADH, thereby reducing mitochondrial defenses, increasing oxidative stress, and slowing the recovery of energy metabolism. Matrix acidification may also disrupt the quaternary structure of other mitochondrial protein complexes critical for cellular homeostasis and survival.     

Inactivation of myocardial dihydrolipoamide dehydrogenase by myeloperoxidase systems: effect of halides, nitrite and thiol compounds

Dihydrolipoamide dehydrogenase (LADH) lipoamide reductase activity decreased whereas enzyme diaphorase activity increased after LADH treatment with myeloperoxidase (MPO) dependent systems (MPO/H₂O₂/halide, MPO/NADH/halide and MPO/H₂O₂/nitrite systems. LADH inactivation was a function of the composition of the inactivating system and the incubation time. Chloride, iodide, bromide, and the thiocyanate anions were effective complements of the MPO/H₂O₂ system. NaOCl inactivated LADH, thus supporting hypochlorous acid (HOCl) as putative agent of the MPO/H₂O₂/NaCl system. NaOCl and the MPO/H₂O₂/NaCl system oxidized LADH thiols and NaOCl also oxidized LADH methionine and tyrosine residues. LADH inactivation by the MPO/ NADH/halide systems was prevented by catalase and enhanced by superoxide dismutase, in close agreement with H₂O₂ production by the LADH/NADH system. Similar effects were obtained with lactoperoxidase and horseradish peroxidase suplemented systems. L-cysteine, N-acetylcysteine, penicillamine, N-(2-mercaptopropionylglycine), Captopril and taurine protected LADH against MPO systems and NaOCl. The effect of the MPO/H₂O₂/NaNO₂ system was prevented by MPO inhibitors (sodium azide, isoniazid, salicylhydroxamic acid) and also by L-cysteine, L-methionine, L-tryptophan, L-tyrosine, L-histidine and reduced glutathione. The summarized observations support the hypothesis that peroxidase-generated “reactive species” oxidize essential thiol groups at LADH catalytic site.     

Lysis of yeast protoplasts under sodium alkyl sulfates treatment]

The lytic action of homologous series of sodium alkyl sulfates on yeast protoplasts was studied. The concentration dependences study allowed to estimate the lytic concentrations C50 of the agents required for the 50% lysis of protoplasts in the suspension. The data concerning the agents micelle formation in the lytic medium allowed to make some suggestions and to produce a model of the lytic action of alkyl sulfates on the plasma membrane of the protoplasts. The amounts of the agents absorbed on the membrane and involved in the interaction followed by the membrane breakdown in the model are evaluated. On the basis of the data obtained it is concluded that sodium dodecyl sulfate displays the highest lytic activity to the yeast protoplast plasma membrane as compared to the other alkyl sulfates used in the study. The results obtained are discussed in terms of the effect of yeast cell wall on the extraction of intracellular proteins from intact yeast cell under sodium alkyl sulfates action.     

Catecholamines Enhance Dihydrolipoamide Dehydrogenase Inactivation by the Copper Fenton System. Enzyme Protection by Copper Chelators

Catecholamines (CAs: epinephrine, norepinephrine, dopamine, L-DOPA, 6-hydroxydopamine) and o-diphenols (DOPAC and catechol) enhanced dihydrolipoamide dehydrogenase (LADH) inactivation by Cu(II) /H₂O₂ (Cu-Fenton system). The inhibition of LADH activity correlated with Cu(II), H₂O₂ and CA concentrations. Similar inhibitions were obtained wit! the assayed CAs and o-diphenols. CAs enhanced HO radical production by Cu(II) /H₂O₂, as demonstrated by benzoate hydroxylation and deoxyribose oxidation; LADH counteracted the pro-oxidant effect of CAs by scavenging hydroxyl radicals. Captopril, dihydrolipo amide, dihydrolipoic acid, DL-dithiothreitol, GSSG, try-panothione and histidine effectively preserved LADH from oxidative damage, whereas N-acetylcysteine, N-(2-mercaptopropionylglycine) and lipoamide were less effective protectors. Catalase (though neither bovine serum albumin nor superoxide dismutase) protected LADH against the Cu(II)/H₂O₂/CAs systems. Dena tured catalase protected less than the native enzyme, its action possibly depending on Cu-binding. LADH in creased and Captopril inhibited epinephrine oxidation by Cu(II)/H₂O₂ and Cu(II). The summarized evidence supports the following steps for LADH inactivation: (1) reduction of LADH linked-Cu(II) to Cu(I) by CAs; (2) production of HO^* from H₂O₂ by LADH-linked Cu(I) (Haber-Weiss reaction) and (3) oxidation of aminoacid residues at the: enzyme active site by site-specifically generated HO^* radicals. Hydrogen peroxide formation from CAs autoxidation may contribute to LADH inactivation.     

Mechanism of freeze-thaw damage to liver alcohol dehydrogenase and protection by cryoprotectants and amino acids

Multiple freeze-thaw (FT) cycles, with complete melting between cycles, resulted in an exponential decline in liver alcohol dehydrogenase (LADH) enzyme activity. The reduction in activity of LADH as a result of FT damage was proportional to the decrease in the intensity of the tryptophan fluorescence of the enzyme. Treatment with urea resulted in a similar relationship between tryptophan fluorescence intensity and inactivation. Evidence from fluorescence and activity studies from the same sample, as well as gel electrophoresis, indicates that damage to LADH from a FT cycle, resulting in inactivation, is likely an unfolding of the enzyme rather than separation of subunits or aggregation of enzymes at the enzyme concentrations and cooling rates used. A nonexponential decline in enzyme activity, as a function of the number of FT cycles, can be achieved if complete melting between cycles is not allowed or if the samples are stored at +4 degrees C for 24 hr following the last FT cycle, prior to assay. In the latter case, a partial recovery in enzyme activity is seen. "Seeding," while lowering the enzyme activity, is desirable to achieve consistent results without the artifacts that are introduced if not used. Amino acids were tested for their effectiveness as cryoprotectants. From the results of this study, the mean fractional area loss of amino acid residues upon incorporation in globular proteins (f) is inversely proportional to the FT protection by these free amino acids. Thus, amino acid residues which tend to be found at the surface of proteins (e.g., glutamate) improve the FT survival of LADH, when added as the free amino acid, while those amino acids which are found in the interior of proteins (e.g., valine, leucine) sensitize LADH to FT damage. The pattern of protection ("fingerprint") of LADH by various amino acids is different from that of living cells. Furthermore, unlike the case with cells, glutamine and DMSO do not act independently when protecting LADH.     

Trypanosoma cruzi dihydrolipoamide dehydrogenase is inactivated by myeloperoxidase-generated “reactive species”

Dihydrolipoamide dehydrogenase (LADH) from Trypanosoma cruzi was inactivated by treatment with myeloperoxidase (MPO)-dependent systems. With MPO/H₂O₂/NaCl, LADH lipoamide reductase and diaphorase activities significantly decreased as a function of incubation time. Iodide, bromide, thiocyanide and chloride effectively supplemented the MPO/H₂O₂ system, KI and NaCl being the most and the least effective supplements, respectively. LADH inactivation by MPO/H₂O₂/NaCl and by NaOCl was similarly prevented by thiol compounds such as GSH, L-cysteine, N-acetylcysteine, penicillamine and N-(2-mercaptopropionyl-glycine) in agreement with the role of HOCl in LADH inactivation by MPO/H₂O₂/NaCl. LADH was also inactivated by MPO/NADH/halide, MPO/H₂O₂/NaNO₂ and MPO/NADH/NaNO₂ systems. Catalase prevented the action of the NADH-dependent systems, thus supporting H₂O₂ production by NADH-supplemented LADH. MPO inhibitors (4-aminobenzoic acid hydrazide, and isoniazid), GSH, L-cysteine, L-methionine and L-tryptophan prevented LADH inactivation by MPO/H₂O₂/NaNO₂. Other MPO systems inactivating LADH were (a) MPO/H₂O₂/chlorpromazine; (b) MPO/H₂O₂/monophenolic systems, including L-tyrosine, serotonin and acetaminophen and (c) MPO/H₂O₂/di- and polyphenolic systems, including norepinephrine, catechol, nordihydroguaiaretic acid, caffeic acid, quercetin and catechin. Comparison of the above effects and those previously reported with pig myocardial LADH indicates that both enzymes were similarly affected by the MPO-dependent systems, allowance being made for T. cruzi LADH diaphorase inactivation and the greater sensitivity of its LADH lipoamide reductase activity towards the MPO/H₂O₂/NaCl system and NaOCl.     

Nucleolar protein B23 has molecular chaperone activities

Protein B23 is an abundant, multifunctional nucleolar phosphoprotein whose activities are proposed to play a role in ribosome assembly. Szebeni et al. (1997) showed stimulation of nuclear import in vitro by protein B23 and suggested that this effect was due to a molecular chaperone-like activity. Protein B23 was tested for chaperone activities using several protein substrates. The temperature-dependent and -independent aggregation of the HIV-1 Rev protein was measured using a zero angle light scattering (turbidity) assay. Protein B23 inhibited the aggregation of the Rev protein, with the amount of inhibition proportional to the concentration of B23 added. This activity was saturable with nearly complete inhibition when the molar ratio of B23:Rev was slightly above one. Protein B23 also protected liver alcohol dehydrogenase (LADH), carboxypeptidase A, citrate synthase, and rhodanese from aggregation during thermal denaturation and preserved the enzyme activity of LADH under these conditions. In addition, protein B23 was able to promote the restoration of activity of LADH previously denatured with guanidine-HCl. Protein B23 preferentially bound denatured substrates and exposed hydrophobic regions when complexed with denatured proteins. Thus, by several criteria, protein B23 behaves like a molecular chaperone; these activities may be related to its role in ribosome biogenesis.     

Phenothiazine radicals inactivate Trypanosoma cruzi dihydrolipoamide dehydrogenase: enzyme protection by radical scavengers

Phenothiazine cation radicals (PTZ + •) irreversibly inactivated Trypanosoma cruzi dihydrolipoamide dehydrogenase (LADH). These radicals were obtained by phenothiazine (PTZ) peroxidation with myeloperoxidase (MPO) or horseradish peroxidase (HRP/H 2 O 2 ) systems. LADH inactivation depended on PTZ structure and incubation time. After 10 min incubation of LADH with the MPO-dependent systems, promazine, trimeprazine and thioridazine were the most effective; after 30 min incubation, chlorpromazine, prochlorperazine and promethazine were similarly effective. HRP-dependent systems were equally or more effective than the corresponding MPO-dependent ones. Chloro, trifluoro, propionyl and nitrile groups at position 2 of the PTZ ring significantly decreased molecular activity, specially with the MPO/H 2 O 2 systems. Comparison of inactivation values for LADH and T. cruzi trypanothione reductase demonstrated a greater sensitivity of LADH to chlorpromazine and perphenazine and a 10-fold lower sensitivity to promazine, thioridazine and trimeprazine. Alkyl-amino, alkyl-piperidinyl or alkyl-piperazinyl groups at position 10 modulated PTZ activity to a limited degree. Production of PTZ + • radicals was demonstrated by optical and ESR spectroscopy methods. PTZ + • radicals stability depended on their structure as demonstrated by promazine and thioridazine radicals. Thiol compounds such as GSH and N -acetylcysteine, l -tyrosine, l -tryptophan, the corresponding peptides, ascorbate and Trolox, prevented LADH inactivation by the MPO/H 2 O 2 /thioridazine system, in close agreement with their action as PTZ + • scavengers. NADH (not NAD + ) produced transient protection of LADH against thioridazine and promazine radicals, the protection kinetics being affected by the relatively fast rate of NADH oxidation by these radicals. The role of the observed effects of PTZ radicals for PTZ cytotoxicity is discussed.     

Reactivity-selectivity correlations: I. The reactivity of alkyl aryl sulfates towards papain and ficin

A series of alkyl aryl sulfates has been investigated as inhibitors of papain and ficin activity. The results show that the percentage of residual enzymatic activity depends on several factors, including the solvolytic reactivity of the alkylating agent. It is possible to correlate the reactivities of the sulfates with a selectivity parameter which is based on product ratio results. The resulting correlations indicate that the reactivity-selectivity principle is applicable to this system. It is shown, however, from the results of amino acid analyses that specific methylation of active-site cysteine or histidine residues is not effective with the enzymes in the native or denatured state. This phenomenon contrasts with reported work on methyl p-nitrobenzenesulfonate in which extensive methylation of papain in the denatured state was observed. The finding that the nonspecific methylation of the enzymes by the alkyl aryl sulfates leads to inhibition of enzymic activity is discussed in terms of conformational and other effects.     

Primary Alcohol Sulfatase in a Pseudomonas Species

An ammonium sulfate-precipitated fraction from cell-free extracts of Pseudomonas C12B grown on a medium containing sodium dodecyl sulfate (SDS) contained alkyl sulfatase increased fourfold in specific activity over the crude. Optimal pH (7.5) and temperature (70 C) for sulfate release were determined with SDS labeled with radioactive sulfur (SDS(35)) as test substrate. Phosphate, arsenate, and certain heavy metal ions inhibited desulfation, whereas Mg(++) and Mn(++) stimulated activity of preparations which had been dialyzed against ethylenediaminetetraacetic acid. Dodecanol was recovered in semiquantitative yield from reaction mixtures containing enzyme and SDS(35). Aryl sulfates, secondary alcohol sulfates, and a phenoxyethyl sulfate failed to serve as substrate for this enzyme.