Purification by affinity chromatography of yeast glutathione reductase, the enzyme responsible for the NADPH-dependent reduction of the mixed disulfide of coenzyme A and glutathione.

Glutathione reductase (NAD(P)H : oxidised-glutathione oxidoreductase, EC 1.6.4.2) was purified from baker's yeast by a new procedure involving affinity chromatography on 2',5'-ADP-Sepharose 4B. The yield was 65% of essentially homogeneous enzyme. The activity was assayed with both glutathione disulfide (GSSG) and the mixed disulfide of coenzyme A and glutathione (CoAssg). The two disulfide substrates gave coinciding activity profiles and a constant ratio of the activities in different chromatographic and electrophoretic systems. No evidence was obtained for the existence of a reductase specific for CoASSG distinct from glutathione reductase. It is concluded that normal baker's yeast contains a single reductase active with both GSSG and CoASSG.     

Trapping of an intermediate in the reaction catalyzed by 5-oxoprolinase

Bacterial 5-oxoprolinase is composed of two protein components: Component A, which catalyzes 5-oxoproline-dependent ATP-hydrolysis and Component B, which couples the hydrolysis of ATP with the decyclization of 5-oxoproline to form glutamate (Seddon, A. P., Li, L., and Meister, A. (1984) J. Biol. Chem. 259, 8091-8094). Studies on this unusual enzyme system have led to evidence that an intermediate is formed by Component A. Application of the isotope-trapping method demonstrated an activated 5-oxoproline intermediate, whose formation requires ATP, Mg2+, and Component A. The amount of ATP-dependent trapping was close to the number of enzyme active sites. The intermediate formed by Component A was shown to be reducible by potassium borohydride to proline in low yield; when Component B was added, the formation of proline was abolished. Treatment of reaction mixtures containing Component A, 5-oxoproline, and [gamma-32P] ATP with diazomethane led to appearance of a 32P-labeled compound (found on thin layer chromatography), whose formation was significantly reduced when Component B was present. The new compound, which is labile, breaks down to form dimethyl[32P]phosphate. The total amount of dimethyl[32P]phosphate formed after breakdown is close to the number of active sites of Component A. The data are consistent with the conclusion that a phosphorylated form of 5-oxoproline is formed by Component A and suggest that Component B is required for conversion of this intermediate to glutamate.     

L-myo-inosose-1 as a probable intermediate in the reaction catalyzed by myo-inositol oxygenase

In previous investigations, it was necessary to have Fe(II) and cysteine present in order to assay the catalytic activity of purified hog kidney myo-inositol oxygenase. In the present study it was found that, if this purified nonheme iron enzyme is slowly frozen in solution with glutathione and stored at -20 degrees C, it is fully active in the absence of activators if catalase is present to remove adventitious H2O2. With this simpler assay system it was possible to clarify the effects of several variables on the enzymic reaction. Thus, the maximum velocity is pH-dependent with a maximum around pH 9.5, but the apparent Km for myo-inositol (air atmosphere) remains constant at 5.0 mM throughout a broad pH range. The enzyme is quite specific for its substrate myo-inositol, is very sensitive to oxidants and reductants, but is not affected by a variety of complexing agents, nucleotides, sulfhydryl reagents, etc. In other experiments it was found that L-myo-inosose-1, a potential intermediate in the enzymic reaction, is a potent competitive inhibitor (Ki = 62 microM), while other inososes and a solution thought to contain D-glucodialdehyde, another potential intermediate, are weak inhibitors. Also, both a kinetic deuterium isotope effect (kH/kD = 2.1) and a tritium isotope effect (kH/kT = 7.5) are observed for the enzymic reaction when [1-2H]- and [1-3H]-myo-inositol are used as reactants. These latter results are considered strong evidence that the oxygenase reaction proceeds by a pathway involving L-myo-inosose-1 as an intermediate rather than by an alternative pathway that would have D-glucodialdehyde as the intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

A proposed reaction mechanism for rice NADPH thioredoxin reductase C, an enzyme with protein disulfide reductase activity

NADPH thioredoxin reductase C (NTRC) is an interesting NTR with a thioredoxin (Trx) domain at the C-terminus, able to conjugate both activities for 2-Cys peroxiredoxin (Prx) reduction. NTRC is dimeric in the presence of NADPH and interacted with dimeric 2-Cys Prx through the Trx module by a mixed disulfide between Cys377 of NTRC and Cys61 of the 2-Cys Prx. NTRC variants of both NTR and Trx active sites were inactive, but 1:1 mixtures of both variants allowed partial recovery of activity suggesting inter-subunit transfer of electrons during catalysis. Based on these results we propose a model for the reaction mechanism of NTRC.

Structured summary

MINT-7017333: 2cys Prx (uniprotkb:Q6ER94) and 2cys Prx (uniprotkb:Q6ER94) bind (MI:0407) by molecular sieving (MI:0071)MINT-7017101, MINT-7017183: NTRC (uniprotkb:Q70G58) and 2cys Prx (uniprotkb:Q6ER94) bind (MI:0407) by enzymatic studies (MI:0415)     

Aldol reaction catalyzed by a hydrophilic catalyst in aqueous micelle as an enzyme mimic system

Chitosan-supported L-proline complex was synthesized and applied as a catalyst for the direct asymmetric aldol reaction in various organic solvents and water as well. It was found that the novel synthesized catalyst was able to efficiently catalyze the aldol reaction in various media. The catalytic capacity and stereoselectivity of the catalyst were obviously improved with the introduction of aqueous micelle, possibly because the micelle functioned as a hydrophobic pocket, like the hydrophobic portion in enzymes. Moreover, the present synthetic catalyst showed performance similar to that of enzymes and could be used as a model of enzyme catalysis to help better understand the mystic mechanism of enzymes.     

Stereochemistry of the reaction catalyzed by mevaldate reductase

3RS-[5-D₁]Mevalonate was prepared by the reduction of RS-mevaldate with [4R-4-D₁]NADH and mevaldate reductase and was resolved enzymically into the 3R- and 3S-isomers. Spectropolarimetric measurements gave nearly mirror-image optical rotatory dispersion curves with a minimum and maximum at 240 nm and a negative and positive Cotton effect, λ₀ being at 227 nm, for the 3R- and 3S-lactone, respectively. Since the H-atoms at C-5 of mevalonolactone form a virtual ABX₂ system in nmr, the chemical shifts of the equatorial and axial H-atoms being at δ 4.33 and 4.58, respectively, it was possible to show by nmr that the two [5-D₁]-lactones were diastereoisomers, both having the 5R absolute configuration. This conclusion was confirmed by the finding that speciments of 3-methyl[5-D₁]pent-2-eno-5-lactone made by the dehydration of 3S-[5-D₁]mevalonolactone and of 3RS-[5-D₁]mevalonolactone had identical optical activities and of the same sign. The implications of the observations and a correlation between the stereochemistry of the reactions catalyzed by mevaldate reductase and 3-hydroxy-3-methylglutaryl-CoA reductase are discussed.     

Glutathione oxidation by hypochlorous acid in endothelial cells produces glutathione sulfonamide as a major product but not glutathione disulfide

Treatment of cells with hypochlorous acid (HOCl) at sublethal doses causes a concentration-dependent loss in reduced glutathione (GSH) levels. We have investigated the products of the reaction of HOCl with GSH in human umbilical vein endothelial cells. Despite a complete loss of GSH, there were only very small increases in intracellular and extracellular glutathione disulfide and glutathione sulfonic acid after exposure to HOCl. (35)S labeling of the GSH pool showed only a minimal increase in protein-bound GSH, suggesting that S-thiolation was not a major contributor to HOCl-mediated loss of GSH in endothelial cells. Rather, the products of the reaction were mostly exported from cells and included a peak that co-eluted with the cyclic sulfonamide that is a product of the reaction of GSH with reagent HOCl. Evidence of this species in endothelial cell supernatants after HOCl treatment was also obtained using electrospray mass spectrometry. In conclusion, exposure to HOCl causes the irreversible loss of cellular GSH with the formation of novel products that are rapidly exported from the cell, and resynthesis of GSH will be required to restore levels. The loss of GSH would alter the redox state of the cell and compromise its defenses against further oxidative stress.     

Identification of a new type of mammalian peroxiredoxin that forms an intramolecular disulfide as a reaction intermediate

Peroxidases of the peroxiredoxin (Prx) family contain a Cys residue that is preceded by a conserved sequence in the NH(2)-terminal region. A new type of mammalian Prx, designated PrxV, has now been identified as the result of a data base search with this conserved Cys-containing sequence. The 162-amino acid PrxV shares only approximately 10% sequence identity with previously identified mammalian Prx enzymes and contains Cys residues at positions 73 and 152 in addition to that (Cys(48)) corresponding to the conserved Cys. Analysis of mutant human PrxV proteins in which each of these three Cys residues was individually replaced with serine suggested that the sulfhydryl group of Cys(48) is the site of oxidation by peroxides and that oxidized Cys(48) reacts with the sulfhydryl group of Cys(152) to form an intramolecular disulfide linkage. The oxidized intermediate of PrxV is thus distinct from those of other Prx enzymes, which form either an intermolecular disulfide or a sulfenic acid intermediate. The disulfide formed by PrxV is reduced by thioredoxin but not by glutaredoxin or glutathione. Thus, PrxV mutants lacking Cys(48) or Cys(152) showed no detectable thioredoxin-dependent peroxidase activity, whereas mutation of Cys(73) had no effect on activity. Immunoblot analysis revealed that PrxV is widely expressed in rat tissues and cultured mammalian cells and is localized intracellularly to cytosol, mitochondria, and peroxisomes. The peroxidase function of PrxV in vivo was demonstrated by the observations that transient expression of the wild-type protein, but not that of the Cys(48) mutant, in NIH 3T3 cells inhibited H(2)O(2) accumulation and activation of c-Jun NH(2)-terminal kinase induced by tumor necrosis factor-alpha.     

Triosephosphate isomerase: energetics of the reaction catalyzed by the yeast enzyme expressed in Escherichia coli

Triosephosphate isomerase from bakers' yeast, expressed in Escherichia coli strain DF502(p12), has been purified to homogeneity. The kinetics of the reaction in each direction have been determined at pH 7.5 and 30 degrees C. Deuterium substitution at the C-2 position of substrate (R)-glyceraldehyde phosphate and at the 1-pro-R position of substrate dihydroxyacetone phosphate results in kinetic isotope effects on kcat of 1.6 and 3.4, respectively. The extent of transfer of tritium from [1(R)-3H]dihydroxyacetone phosphate to product (R)-glyceraldehyde phosphate during the catalyzed reaction is only 3% after 66% conversion to product, indicating that the enzymic base that mediates proton transfer is in rapid exchange with solvent protons. When the isomerase-catalyzed reaction is run in tritiated water in each direction, radioactivity is incorporated both into the remaining substrate and into the product. In the "exchange-conversion" experiment with dihydroxyacetone phosphate as substrate, the specific radioactivity of remaining dihydroxyacetone phosphate rises as a function of the extent of reaction with a slope of about 0.3, while the specific radioactivity of the products is 54% that of the solvent. In the reverse direction with (R)-glyceraldehyde phosphate as substrate, the specific radioactivity of the product formed is only 11% that of the solvent, while the radioactivity incorporated into the remaining substrate (R)-glyceraldehyde phosphate also rises as a function of the extent of reaction with a slope of 0.3. These results have been analyzed according to the protocol described earlier to yield the free energy profile of the reaction catalyzed by the yeast isomerase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism of the reaction catalyzed by dehydroascorbate reductase from spinach chloroplasts.

Dehydroascorbate reductase (DHAR) reduces dehydroascorbate (DHA) to ascorbate with glutathione (GSH) as the electron donor. We analyzed the reaction mechanism of spinach chloroplast DHAR, which had a much higher reaction specificity for DHA than animal enzymes, using a recombinant enzyme expressed in Escherichia coli. Kinetic analysis suggested that the reaction proceeded by a bi-uni-uni-uni-ping-pong mechanism, in which binding of DHA to the free, reduced form of the enzyme was followed by binding of GSH. The Km value for DHA and the summed Km value for GSH were determined to be 53 +/- 12 micro m and 2.2 +/- 1.0 mm, respectively, with a turnover rate of 490 +/- 40 s-1. Incubation of 10 microm DHAR with 1 mm DHA and 10 microm GSH resulted in stable binding of GSH to the enzyme. Bound GSH was released upon reduction of the GSH-enzyme adduct by 2-mercaptoethanol, suggesting that the adduct is a reaction intermediate. Site-directed mutagenesis indicated that C23 in DHAR is indispensable for the reduction of DHA. The mechanism of catalysis of spinach chloroplast DHAR is proposed.     

Inhibition of yeast glutathione reductase by trehalose: possible implications in yeast survival and recovery from stress

Accumulation of trehalose has been implicated in the tolerance of yeast cells to several forms of stress, including heat-shock and high ethanol levels. However, yeast lacking trehalase, the enzyme that degrades trehalose, exhibit poor survival after exposure to stress conditions. This suggests that optimal cell viability also depends on the capacity to rapidly degrade the high levels of trehalose that build up under stress. Here, we initially examined the effects of trehalose on the activity of an important antioxidant enzyme, glutathione reductase (GR), from Saccharomyces cerevisiae. At 25 degrees C, GR was inhibited by trehalose in a dose-dependent manner, with 70% inhibition at 1.5M trehalose. The inhibition was practically abolished at 40 degrees C, a temperature that induces a physiological response of trehalose accumulation in yeast. The inhibition of GR by trehalose was additive to the inhibition caused by ethanol, indicating that enzyme function is drastically affected upon ethanol-induced stress. Moreover, two other yeast enzymes, cytosolic pyrophosphatase and glucose 6-phosphate dehydrogenase, showed temperature dependences on inhibition by trehalose that were similar to the temperature dependence of GR inhibition. These results are discussed in terms of the apparent paradox represented by the induction of enzymes involved in both synthesis and degradation of trehalose under stress, and suggest that the persistence of high levels of trehalose after recovery from stress could lead to the inactivation of important yeast enzymes.     

A 'branched' mechanism of the reverse reaction of yeast glutathione reductase. An estimation of the enzyme standard potential values from the steady-state kinetics data

The reduced glutathione-linked NADP+ reduction, catalyzed by yeast glutathione reductase, follows a 'sequential' or 'ping-pong' mechanism at high or low NADP+ concentrations, respectively. The pattern of the NADPH and NADP+ cross-inhibition reflects not only the competition for the binding site, but the shift of the reaction equilibrium as well. A 'branched' scheme of the glutathione reductase reaction is presented. The enzyme standard potential (-255 mV, pH 7.0) was estimated from the ratio of the NADPH and NADP+ rate constants corresponding to the ping-pong mechanism.     

Multiple-turnover thio-ATP hydrolase and phospho-enzyme intermediate formation activities catalyzed by an RNA enzyme

Ribozymes that phosphorylate internal 2′-OH positions mimic the first mechanistic step of P-type ATPase enzymes by forming a phospho-enzyme intermediate. We previously described 2′-autophosphorylation and autothiophosphorylation by the 2PTmin3.2 ribozyme. In the present work we demonstrate that the thiophosphorylated form of this ribozyme can de-thiophosphorylate in the absence of ATPγS. Identical ionic conditions yield a thiophosphorylated strand when ATPγS is included, thus effecting a net ATPγS hydrolysis. The de-thiophosphorylation step is nearly independent of pH over the range of 6.3–8.5 and does not require a specifically folded RNA structure, but this step is greatly stimulated by transition metal ions. By monitoring thiophosphate release, we observe 29–46 ATPγS hydrolyzed per ribozyme strand in 24 h, corresponding to a turnover rate of 1.2–2.0 h⁻¹. The existence of an ATP- (or thio-ATP-)powered catalytic cycle raises the possibility of using ribozymes to transduce chemical energy into mechanical work for nucleic acid nanodevices.     

High-yield extraction and purification of glutathione reductase from baker's yeast.

Glutathione reductase was extracted from toluene-treated baker's yeast cells by a two-stage buffer autolysis method. The yeast cells were treated with toluene for 1 h at 40 degrees C. After removal of the toluene, the cells were then allowed to autolysis in buffer for 72 h at 4 degrees C. The cells were collected and resuspended in buffer. A second stage autolysis was carried out for another 96 h at 4 degrees C. The enzyme was purified to 786-fold from the second stage cell autolysate by using two steps of affinity chromatography with triazine dyes (Yellow H-E4G and Yellow H-E6G) coupled to Sepharose CL-4B. By using this simplified method, 1.44 mg (165 units/mg) of glutathione reductase was obtained from 65 g (wet weight) of yeast cells, equivalent to 80% enzyme recovery.