Myeloperoxidase oxidation states involved in myeloperoxidase-oxidase oxidation of thiols.

The human red-blood-cell glyoxalase system was modified by incubation with high concentrations of glucose in vitro. Red-blood-cell suspensions (50%, v/v) were incubated with 5 mM- and 25 mM-glucose to model normal and hyperglycaemic glucose metabolism. There was an increase in the flux of methylglyoxal metabolized to D-lactic acid via the glyoxalase pathway with high glucose concentration. The increase was approximately proportional to initial glucose concentration over the range studied (5-100 mM). The activities of glyoxalase I and glyoxalase II were not significantly changed, but the concentrations of the glyoxalase substrates, methylglyoxal and S-D-lactoylglutathione, and the percentage of glucotriose metabolized via the glyoxalase pathway, were significantly increased. The increase in the flux of intermediates metabolized via the glyoxalase pathway during periodic hyperglycaemia may be a biochemical factor involved in the development of chronic clinical complications associated with diabetes mellitus.     

N-hydroxy peptides as substrates for alpha-chymotrypsin.

An N-hydroxylated peptide bond was found to be cleaved faster by an endopeptidase than the corresponding peptide bond. This preferred enzymatic cleavage was detected during proteolytic studies of the N-hydroxy peptide SIINFpsi[CO-N(OH)]GKL in the presence of the serine protease alpha-chymotrypsin in comparison with the natural SIINFEKL epitope and related analogs. For the first time, the replacement of the peptide bond by another motif afforded an oligomer which is degraded faster than the natural peptide. The N-hydroxy peptide is also more sensitive to the enzymatic degradation than the Gly-containing analog SIINFGKL. A tentative explanation for the unexpected higher cleavage rate of the CO-N(OH) bond is given on the basis of the N-OH intramolecular H-bonding capacity as indicated by NMR experiments. This property of the hydroxamate group may be of particular advantage for the introduction of a specific cleavage site within peptidomimetics or in prodrugs.     

Organic Thiols as Organolithotrophic Substrates for Growth of Phototrophic Bacteria

Rhodopseudomonas sp. strain BB1, isolated from a coastal marine sediment, immediately metabolized mercaptomalate when grown on mercaptomalate. Sulfide was detected as an intermediate. Extracts of cells grown on mercaptomalate converted mercaptomalate or 3-mercaptopropionate to equimolar amounts of sulfide and either fumarate or acrylate, respectively. Rhodopseudomonas sp. strain BB1 gave higher growth yields on mercaptomalate than on sulfide or malate, consistent with metabolism of the carbon chain of the thiol and the liberated sulfide; i.e., the organic thiol was an organolithotrophic substrate. In contrast, Thiocapsa roseopersicina, isolated previously from a marine microbial mat, had similar growth yields on sulfide, mercaptomalate, or 3-mercaptopropionate, with fumarate or acrylate accumulation from the thiols. T. roseopersicina did not grow photoorganotrophically on fumarate or acrylate, and the thiols were only a source of sulfide for photolithoautotrophic growth.     

RNA tetraloops as minimalist substrates for aminoacylation.

Previous work established that seven-base-pair hairpin microhelices with sequences based on the acceptor stems of alanine, glycine, methionine, and histidine tRNAs can be aminoacylated specifically with their cognate amino acids. To obtain "minimalist" substrates with fewer base pairs, we took advantage of the high thermodynamic stability of RNA tetraloop motifs that are found in ribosomal RNAs. We show here that rationally designed RNA tetraloops with as few as four base pairs are substrates for aminoacylation. Major nucleotide determinants for recognition by the class II synthetases were incorporated into each of the respective tetraloop substrates, resulting in specific aminoacylation by the alanine, glycine, and histidine tRNA synthetases. An analysis of the kinetics of aminoacylation shows that, for the alanine system, the majority of the transition-state stabilization provided by the synthetase-tRNA interaction is reproduced by the interaction of the synthetase with nucleotides in its minimalist tetraloop substrate. In an extension of this work, we also observed specific aminoacylation with the class I methionine tRNA synthetase of RNA tetraloops based on sequences in the acceptor stem of methionine tRNA. Thus, the results demonstrate four different examples where specific aminoacylation is directed by sequences/structures contained in less than half of a turn of an RNA helix.     

Serum Thiols as a Biomarker of Disease Activity in Lupus Nephritis

Lupus Nephritis (LN) develops in more than half of the Systemic Lupus Erythematous (SLE) patients. However, lack of reliable, specific biomarkers for LN hampers clinical management of patients and impedes development of new therapeutics. The goal of this study was to investigate whether oxidative stress biomarkers in patients with SLE is predictive of renal pathology. Serum biochemical and oxidative stress markers were measured in patients with inactive lupus, active lupus with and without nephritis and compared to healthy control group. To assess the predictive performance of biomarkers, Receiver Operating Characteristic (ROC) curves were constructed and cut-offs were used to identify SLE patients with nephritis. We observed an increased oxidative stress response in all SLE patients compared to healthy controls. Among the several biomarkers tested, serum thiols had a significant inverse association with SLE Disease Activity Index (SLEDAI). Interestingly, thiols were able too aptly differentiate between SLE patients with and without renal pathology, and serum thiol levels were not affected by immunosuppressive drug therapy. The decreased thiols in SLE correlated significantly with serum creatinine and serum C3 levels. Further retrospective evaluation using serum creatinine or C3 levels in combination with thiol’s cutoff values from ROC analysis, we could positively predict chronicity of renal pathology in SLE patients. In summary, serum thiols emerge as an inexpensive and reliable indicator of LN, which may not only help in early identification of renal pathology but also aid in the therapeutic management of the disease, in developing countries with resource poor settings.     

Alternate substrates of dopamine beta-hydroxylase. I. Kinetic investigations of benzyl cyanides as substrates and inhibitors

A series of benzyl cyanide analogs have been studied as substrates and inhibitors of dopamine beta-hydroxylase to extend our initial report (Baldoni, J. M., and Villafranca, J. J. (1980) J. Biol. Chem. 255, 8987-8990) which showed that p-hydroxybenzyl cyanide was a suicide substrate of dopamine beta-hydroxylase. Thus, the appVmax values for benzyl cyanide analogs decrease in the order p-OH greater than m-OH greater than H much greater than p-OCH3,m-OCH3; the m-OH, m-OCH3 and p-OCH3 analogs are competitive inhibitors versus tyramine in initial velocity studies. The Vmax values for tyramine and p-hydroxybenzyl cyanide are nearly identical at saturating O2 and ascorbate (pH 5.0, 37 degrees C) but the Km for O2 is 0.14 and 2.8 mM, respectively, with tyramine and p-hydroxybenzyl cyanide. Studies of the pH dependence of log V/K for tyramine show two pKa values of 5.2 and 5.8 while for m-hydroxybenzyl cyanide the values are 5.3 and 5.9. The log Vmax profile shows one pKa of 5.9 with tyramine as substrate. Thus, nearly identical enzymic groups are involved in binding and/or catalysis with these two substrates. All the benzyl cyanide analogs are suicide inactivators of dopamine beta-hydroxylase. With m-hydroxybenzyl cyanide, the partition between catalysis and inactivation (kcat/kinact) changed from approximately 600 to approximately 17 as the pH varied from 5.0 to 6.7. The log kinact versus pH profile shows one pKa value of 6.0, suggesting that an enzymic group must be deprotonated for maximal inactivation. Copper was essential for the suicide inactivation of dopamine beta-hydroxylase by benzyl cyanides and kinetic studies of partially inhibited dopamine beta-hydroxylase (approximately 50%) showed that inactive enzyme molecules were completely inactive. The following papers in this series discuss the partial reactivation of suicide-inhibited dopamine beta-hydroxylase and the stoichiometry of inactivation by benzyl cyanide analogs.     

Sulfur-Containing Amino Acids as Precursors of Thiols in Anoxic Coastal Sediments

Sulfur-containing amino acids were examined as precursors for thiols in anoxic coastal sediments. Substrates (10 to 100 μM) were anaerobically incubated with sediment slurries; thiols were assayed as isoindole derivatives by high-performance liquid chromatography; and microbial transformations of thiols, in contrast to their chemical binding by sediment particles, were identified by inhibition with a mixture of chloramphenicol and tetracycline. Methionine and homocysteine were transformed to methanethiol and 3-mercaptopropionate (3-MPA); methionine stimulated mainly methanethiol production, whereas homocysteine generated more 3-MPA than methanethiol. 2-Keto-4-methiolbutyrate yielded results similar to those with methionine, indicating that demethiolation yields methanethiol at the keto-acid level. Glutathione gave rise to cysteine, which was further transformed to 3-mercaptopyruvate and thence to mercaptoacetate and mercaptoethanol. Mercaptoethanol was oxidized to mercaptoacetate, which was biologically consumed. In conclusion, sulfurcontaining amino acids contribute to the range of thiols that occur in anoxic coastal sediments. New metabolic and environmental transformations were identified: the production of 3-MPA as a metabolite of methionine and the transformation of mercaptopyruvate to mercaptoethanol and mercaptoacetate.     

15-Hydroxy-prostanoate dehydrogenase. Prostaglandins as substrates and inhibitors

Determination of Michaelis constnats and maximum reaction rates for a series of prostaglandin dehydrogenase substrates showed that the enzyme is stereospecific with regard to configuration at C-15. Substituents of the cyclopentane ring did not markedly affect the properties as a substrate, whereas the nature of the carboxyl side chain proved important. A noncompetitive inhibition was produced between prostaglandin B compounds and a synthetic epimer of prostaglandin E1, 15-R-prostaglandin E1.     

Thiols attached to rat liver non-histone nuclear proteins.

Up to 88% of the total thiol present in isolated rat liver nuclei can be extracted with 8 M urea 50 mM phosphate pH 7.6. There is approx. 5–10% disulphide material present in this extract. When the thiols were labelled with ¹⁴C-N-ethyl maleimide (¹⁴C-NEM) the thiol material co-electrophoresed with the protein material. If a mixed disulphide was formed with ³⁵S-labelled 5-thio-2-nitrobenzoic acid (Ellman's reagent) the thiol compounds could be removed from the protein by isoelectric focusing in polyacrylamide gel. The mixed disulphides obtained could be resolved into at least 10 components on DEAE cellulose. One of the major components had an estimated molecular weight of 3 000 and did not contain peptide material.     

Thiols in the Melanocyte

Melanocytes contain several substances formed by the nucleophilic addition of cysteine to dopaquinone. 5-S-Cysteinyldopa is the quantitatively dominant catecholic amino acid belonging to this group of compounds. Glutathione is the thiol most abundantly present in all cells studied, and the reactivity of the SH-group of this tripeptide with dopaquinone is about one-third that of cysteine. However, the amount of glutathionyldopa is at least two orders of magnitude less than that of cysteinyldopa in the melanocyte. A rapid metabolism of glutathionyldopa has therefore been suggested as an explanation for the above-mentioned findings. The enzyme responsible for hydrolysis of the γ-glutamyl bond of glutathione, γ-glutamyltranspeptidase, is present in the melanocyte, but in small quantities. Furthermore, S-cysteinylglycinyldopa, which is the product of hydrolysis by γ-glutamyltranspeptidase, is found in only very small amounts. These facts taken together contradict the hypothesis that S-cysteinyldopas in the melanocyte are formed from S-glutathionyldopas. The present investigation on IGR1 melanoma cells was performed by in situ derivatization of thiols with monobromobimane. Quantitation of the stable bimane adducts of cysteine and glutathione was achieved by reverse-phase high-performance liquid chromatography with fluorimetric detection. The concentration of reduced cysteine in the melanocytes was found to be a few percent of that of reduced glutathione. The quantities of 5-S-cysteinyldopa, 5-S-glutathionyldopa, cysteine, and glutathione observed in the cultured melanoma cells could best be explained by a pronounced compartmentalization of cysteine within the melanocyte, with a high cysteine concentration at the site of the dopaquinone formation.     

A new type of ultrasensitive bioluminogenic enzyme substrates. I. Enzyme substrates with D-luciferin as leaving group

Derivatives of D-luciferin, D-luciferin methyl ester, D-luciferin O-sulfate, D-luciferin O-phosphate, D-luciferyl-L-N alpha-arginine and D-luciferyl-L-phenylalanine were used as highly sensitive substrates for carboxylic esterase, arylsulfatase, alkaline phosphatase and carboxypeptidases A, B and N. Enzymatic cleavage of the compounds by enzymes leading to the release of D-luciferin was demonstrated. Kinetic constants have been determined for D-luciferin methyl ester and carboxylic esterase, for D-luciferin O-sulfate and arylsulfatase, for D-luciferin O-phosphate and alkaline phosphatase, for D-luciferyl-L-phenylalanine and carboxypeptidase A, and for carboxypeptidases B and N and D-luciferyl-L-N alpha-arginine. All compounds proved to be highly sensitive substrates for the respective enzymes, permitting a limit of detection for enzymes between 10 and 500 fg per assay.     

Hydrolytic enzyme substrates. 3. Phosphomonoesterase substrates

This report documents the use of a new and sensitive colorimetric method for measuring phosphomonoesterase activity. The substrates are the phosphate esters of 4-(p-nitrophenoxy)-1,2-butanediol (PNB), 4-(2,4-dinitrophenoxy)-1,2-butanediol (DNB) and 3-(p-nitrophenoxy)-1,2-propanediol (PNG). The key intermediate in the assay is the nitrophenoxy diol which is obtained by enzyme hydrolysis of its phosphate ester. Periodate oxidation of this substance in solution containing methylamine quantitatively yields its nitrophenolate ion whose concentration is determined colorimetrically. The amount of nitrophenolate ion is thus equivalent to the amount of nitrophenoxy diol whose concentration is a function of the phosphomonoesterase activity in the assay sample. The unhydrolyzed phosphomonoester is completely stable to periodate and the hydrolytic conditions used in the assay. The enzymes used to test the substrates were E. coli alkaline phosphomonoesterase and wheat germ phosphomonoesterase. These new esters were all better substrates than the glycerol phosphate esters. Their Michaelis-Menten constants were determined for E. coli phosphomonoesterase.