Ryan N Vogt scite author profile

When grown in culture Mycobacterium smegmatis metabolized S-nitrosoglutathione to oxidized glutathione and nitrate, which suggested a possible involvement of an S-nitrosothiol reductase and mycobacterial haemoglobin. The mycothiol-dependent formaldehyde dehydrogenase from M. smegmatis was purified by a combination of Ni2+-IMAC (immobilized metal ion affinity chromatography), hydrophobic interaction, anion-exchange and affinity chromatography. The enzyme had a subunit molecular mass of 38263 kDa. Steady-state kinetic studies indicated that the enzyme catalyses the NAD+-dependent conversion of S-hydroxymethylmycothiol into formic acid and mycothiol by a rapid-equilibrium ordered mechanism. The enzyme also catalysed an NADH-dependent decomposition of S-nitrosomycothiol (MSNO) by a sequential mechanism and with an equimolar stoichiometry of NADH:MSNO, which indicated that the enzyme reduces the nitroso group to the oxidation level of nitroxyl. Vmax for the MSNO reductase reaction indicated a turnover per subunit of approx. 116700 min(-1), which was 76-fold faster than the formaldehyde dehydrogenase activity. A gene, Rv2259, annotated as a class III alcohol dehydrogenase in the Mycobacterium tuberculosis genome was cloned and expressed in M. smegmatis as the C-terminally His6-tagged product. The purified recombinant enzyme from M. tuberculosis also catalysed both activities. M. smegmatis S-nitrosomycothiol reductase converted MSNO into the N -hydroxysulphenamide, which readily rearranged to mycothiolsulphinamide. In the presence of MSNO reductase, M. tuberculosis HbN (haemoglobin N) was converted with low efficiency into metHbN [HbN(Fe3+)] and this conversion was dependent on turnover of MSNO reductase. These observations suggest a possible route in vivo for the dissimilation of S-nitrosoglutathione.

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The biosynthesis of ovothiol A (N¹‐methyl‐4‐mercaptohistidine)

Vogt

Spies

Steenkamp

2001

European Journal of Biochemistry

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Crude extracts of Crithidia fasciculata catalyse the formation of 4‐mercapto‐l‐histidine, an intermediate in the biosynthesis of ovothiol A (N1‐methyl‐4‐mercaptohistidine), in the presence of histidine, cysteine, Fe2+ and pyridoxal phosphate. This activity was present in a 35–55% ammonium sulfate fraction that was shown to produce a transsulfuration intermediate in the absence of pyridoxal phosphate. The transsulfuration intermediate was isolated and identified as S‐(4′‐l‐histidyl)‐l‐cysteine sulfoxide. The synthase activity, partially purified by anion‐exchange chromatography, was shown to require oxygen and could be used to synthesize a number of isotopically labeled S‐(4′‐l‐histidyl)‐l‐cysteine sulfoxides. Sulfoxide lyase activity was partially resolved from the synthase by anion‐exchange chromatography. The phenylhydrazone of the product derived from the cysteine moiety of the sulfoxide coeluted with the phenylhydrazone of pyruvate on HPLC, but this assignment could not be confirmed by mass spectral analysis. S‐(4′‐[14C]l‐histidyl)‐[U‐13C3,15N]l‐cysteine sulfoxide was synthesized and converted to products of the lyase reaction in the presence of lactate dehydrogenase and NADH. The 13C‐labeled product was identified by 13C‐NMR spectroscopy as lactate and the primary product of the lyase reaction is therefore pyruvate. With S‐(4′[3H]l‐histidyl)‐[14C]l‐cysteine sulfoxide as the substrate [14C]lactate, [14C]cysteine and [3H]4‐mercaptohistidine could be detected as products of the lyase reaction, but the sum of the two thiol species exceeded the amount of sulfoxide substrate used. Evidence is presented that this anomaly was due to the utilization of sulfur from dithiothreitol for the formation of cysteine.

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The metabolism of S-nitrosothiols in the trypanosomatids: the role of ovothiol A and trypanothione

Vogt

Steenkamp

2003

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It has recently been established that nitrosoglutathione is the preferred substrate of the glutathione-dependent formaldehyde dehydrogenase from divergent organisms. Trypanosomatids produce not only glutathione, but also glutathionylspermidine, trypanothione and ovothiol A. The formaldehyde dehydrogenase activity of Crithidia fasciculata was independent of these thiols and extracts possessed very low levels of nitrosothiol reductase activity with glutathione or its spermidine conjugates as the thiol component. Although ovothiol A did not form a stable nitrosothiol, it decomposed the S -nitroso groups of nitrosoglutathione (GSNO) and dinitrotrypanothione [T(SNO)(2)] with second-order rate constants of 19.12 M(-1) x s(-1) and 8.67 M(-1) x s(-1) respectively. The reaction of T(SNO)(2) with ovothiol A, however, accelerated to a rate similar to that seen with GSNO. Ovothiol A can act catalytically to decompose these nitrosothiols, although non-productive mechanisms exist. The catalytic phase of the reaction was dependent on the production of thiyl radicals, since it was abolished in the presence of 5,5-dimethyl-1-pyrroline- N -oxide and the formation of nitric oxide could be detected by means of the conversion of oxyhaemoglobin into methaemoglobin. The rate-limiting step in the catalytic process was the reduction of oxidized ovothiol species and, in this respect, T(SNO)(2) is a more efficient substrate than GSNO. Trypanothione decomposed GSNO with a second-order rate constant of 0.786 M(-1) x s(-1) and the major nitrogenous end product changed from nitrite to ammonia as the ratio of thiol to nitrosothiol increased. The results indicate that ovothiol A acts in synergy with trypanothione in the decomposition of T(SNO)(2).

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Preparation and utilization of a reagent for the isolation and purification of low-molecular-mass thiols

Steenkamp

Vogt

2004

Analytical Biochemistry

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The effect of buthionine sulfoximine on the growth ofLeishmania donovaniin culture

Weldrick

Chodacka

Vogt

et al. 1999

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Changes in composition of the principal low molecular mass thiols of Leishmania donovani were monitored during the transformation of promastigotes, first to stationary phase metacyclic forms and then to amastigotes. No consistent variation in the thiol composition of the parasite which could account for the known increase in resistance of metacyclic and amastigote lifecycle forms to oxidant stress could be established. Amastigotes cultivated at 37 degrees C also produced ovothiol A, as judged by incorporation of radiolabel from [3-methyl]methionine and [14C]histidine, and the incorporation of radiolabel from [35S]cysteine into ovothiol A represented about 10-15% of the total label recovered in ovothiol A, glutathione and trypanothione. Amastigotes were less susceptible than promastigotes to the effects of the redox cyclers paraquat and menadione and grew in culture in the presence of up to 20 mM buthionine sulfoximine, which completely blocked the synthesis of glutathione and its spermidine conjugates. Glutathione and trypanothione biosynthesis is, therefore, not necessary for the replication of L. donovani amastigotes in culture. Inhibition of the formation of glutathione and trypanothione did not result in an upregulation of ovothiol A production.

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Ryan N Vogt

The metabolism of nitrosothiols in the mycobacteria: identification and characterization of S-nitrosomycothiol reductase

The biosynthesis of ovothiol A (N¹‐methyl‐4‐mercaptohistidine)

The metabolism of S-nitrosothiols in the trypanosomatids: the role of ovothiol A and trypanothione

Preparation and utilization of a reagent for the isolation and purification of low-molecular-mass thiols

The effect of buthionine sulfoximine on the growth ofLeishmania donovaniin culture

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Ryan N Vogt

The metabolism of nitrosothiols in the mycobacteria: identification and characterization of S-nitrosomycothiol reductase

The biosynthesis of ovothiol A (N1‐methyl‐4‐mercaptohistidine)

The metabolism of S-nitrosothiols in the trypanosomatids: the role of ovothiol A and trypanothione

Preparation and utilization of a reagent for the isolation and purification of low-molecular-mass thiols

The effect of buthionine sulfoximine on the growth ofLeishmania donovaniin culture

Contact Info

Product

Resources

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The biosynthesis of ovothiol A (N¹‐methyl‐4‐mercaptohistidine)