Reinvestigation of the roles of the carboxyl groups of glutathione with yeast glyoxalase I (original) (raw)
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A number of carboxyl-substituted S-blocked glutathiones have been shown to be competitive inhibitors of yeast glyoxalase I at 25°C pH 6.6. Amidation of the glycyl carboxyl group of S-@-bromobenzyl)glutathione has no appreciable effect on binding whilst methylation reduces binding by 8.9-fold, indicating a steric constraint and the possible presence of a hydrogen bond in this region of the enzyme. Amidation of both carboxyl groups of S-(p-bromobenzyl)glutathione reduces binding significantly by 237-fold; this result agrees with electrostatic interaction of the Glu COO-group with a group located within the enzyme surface as opposed to the Gly COO-group, previously proposed.
Role of the N -terminus of glutathione in the action of yeast glyoxalase I
Biochemical Journal, 1982
A number of S-substituted glutathiones and the corresponding N-substituted S-substituted analogues have been found to be linear competitive inhibitors of yeast glyoxalase I at 26 degrees C over the pH range 4.6-8.5. N-Acetylation of S-(p-bromobenzyl)glutathione weakens binding by 13.7-fold. N-benzoylation by 25.6-fold, N-trimethylacetylation by 53.3-fold and N-carbobenzoxylation by 7.8-fold, indicating a minor steric component in the binding at the N-site. The Ki-weakening effect of N-substitution of glutathione depends on the chemical nature of the S-substituent, indicating flexibility in the glutathione and/or glyoxalase I contributions to the binding site for glutathione derivatives. The effect of N-acylation on Ki is in accord with a charge interaction of the free enzyme with S-blocked glutathione in a region of reasonably high dielectric constant. There is a slight pH effect on Ki for S-(m-trifluoromethylbenzyl)glutathione but not for S-(p-bromobenzyl)glutathione.
Role of the N-terminus of glutathione on the action of yeast glyoxalase I.
A number of S-substituted glutathiones and the corresponding ,V-substituted S substituted analogues have been found to be linear competitive inhibitors of yeast glyoxalase I at 25oC over the pH range 4.6-8.5. N-Acetylation of S-(p-bromobenzyl)glutathione weakens binding by 13.7-fo1d. N-benzoylation by 25.6-fold. N-trimethylacetylation by 53.3-foid and i/-carbobenzoxylation by 7.8 fold. indicating a
Archives of Biochemistry and Biophysics, 2003
In an effort to probe the inhibition of glyoxalase II (GLX2-2) from Arabidopsis thaliana, a series of N- and S-blocked glutathione compounds containing 9-fluorenylmethoxycarbonyl (FMOC) and Cbz protecting groups were synthesized and tested. The di-FMOC and di-Cbz compounds were the best inhibitors of GLX2-2 with K(i) values of 0.89+/-0.05 and 2.3+/-0.5 microM, respectively. The removal of protecting groups from either position resulted in comparable, diminished binding affinities. Analyses of site-directed mutants of GLX2-2 demonstrated that tight binding of these inhibitors is not due to interactions of the protecting groups with hydrophobic amino acids on the surface of the enzyme. Instead, MM2 calculations predict that the lowest energy structures of the unbound, doubly substituted inhibitors are similar to those of a bound inhibitor. These studies represent the first systematic attempt to understand the peculiar inhibition of GLX2 by N- and S-blocked glutathiones.
Biochimica et Biophysica Acta (BBA) - Protein Structure and Molecular Enzymology, 2000
Tyrosine-175 located in the active site of human glyoxalase II was replaced by phenylalanine in order to study the contribution of this residue to catalysis. The mutation had a marginal effect on the k cat value determined using S-Dlactoylglutathione as substrate. However, the Y175F mutant had an 8-fold higher K m value than the wild-type enzyme. The competitive inhibitor S-(N-hydroxy-N-bromophenylcarbamoyl)glutathione had a 30-fold higher K i value towards the mutant, than that of the wild-type. Pre-equilibrium fluorescence studies with the inhibitor showed that this was due to a significantly increased off-rate for the mutant enzyme. The phenolic hydroxyl group of tyrosine-175 is within hydrogen bonding distance of the amide nitrogen of the glycine in the glutathione moiety and the present study shows that this interaction makes a significant contribution to the binding of the active-site ligand. ß
Cell biochemistry and function, 2016
Glyoxalase II, the second of 2 enzymes in the glyoxalase system, is a hydroxyacylglutathione hydrolase that catalyses the hydrolysis of S-d-lactoylglutathione to form d-lactic acid and glutathione, which is released from the active site. The tripeptide glutathione is the major sulfhydryl antioxidant and has been shown to control several functions, including S-glutathionylation of proteins. S-Glutathionylation is a way for the cells to store reduced glutathione during oxidative stress, or to protect protein thiol groups from irreversible oxidation, and few enzymes involved in protein S-glutathionylation have been found to date. In this work, the enzyme glyoxalase II and its substrate S-d-lactoylglutathione were incubated with malate dehydrogenase or with actin, resulting in a glutathionylation reaction. Glyoxalase II was also submitted to docking studies. Computational data presented a high propensity of the enzyme to interact with malate dehydrogenase or actin through its catalytic ...
The Journal of biological chemistry, 1984
The conformations of four derivatives of glutathione bound at the active site of the metalloenzyme glyoxalase I have been determined by NMR measurements and by computer model building using a distance geometry approach. Paramagnetic effects of Mn2+-glyoxalase I on the longitudinal relaxation rates of the carbon-bound protons of the substrate analog S-(acetonyl)-glutathione at three frequencies, the hydrophobic competitive inhibitor S-(propyl)glutathione at four frequencies, and the charged competitive inhibitor S-(carboxymethyl)glutathione at a single frequency were used to calculate Mn2+ to proton distances in each complex. These and previously determined distances from Mn2+ to the protons and 13C-enriched carbon atoms of the product S-(D-lactoyl)glutathione were used in a distance geometry program to compute the conformations of each enzyme-bound derivative which best fit the measured distances and other known constraints such as bond lengths, van der Waals radii, planar and trans...
Biochemical Journal, 1990
The GSH-binding site of glutathione S-transferase (GST) isoenzymes was studied by investigating their substrate-specificity for three series of GSH analogues; further, a model of the interactions of GSH with the G-site is proposed. Twelve glycyl-modified GSH analogues, four ester derivatives of GSH and three cysteinyl-modified GSH analogues were synthesized and tested with purified forms of rat liver GST (1-1, 2-2, 3-3 and 4-4). The glycyl analogues exhibited spontaneous chemical reaction rates with 1-chloro-2,4-dinitrobenzene comparable with the GSH rate. In contrast, the enzymic rates (Vmax.) differed greatly, from less than 1 up to 140 mumol/min per mg; apparently, a reaction mechanism is followed that is very sensitive to substitutions at the glycyl domain. No correlation exists between the chemical rates and Vmax. values for the analogues. Analogues of GSH in which L-cysteine was replaced by D-cysteine, L-homocysteine or L-penicillamine showed little or no capacity to replace G...
2000
Potential inhibitors of the enzyme glyoxalase I from Escherichia coli have been evaluated using a combination of electrospray mass spectrometry and conventional kinetic analysis. An 11-membered library of potential inhibitors included a glutathione analogue resembling the transition-state intermediate in the glyoxalase I catalysis, several alkyl-glutathione, and one flavonoid. The E. coli glyoxalase I quaternary structure was found to be predominantly dimeric, as is the homologous human glyoxalase I. Binding studies by electrospray revealed that inhibitors bind exclusively to the dimeric form of glyoxalase I. Two specific binding sites were observed per dimer. The transition-state analogue was found to have the highest binding affinity, followed by a newly identified inhibitor; S-{2-[3-(hexyloxy)benzoyl]-vinyl}glutathione. Kinetic analysis confirmed that the order of affinity established by mass spectrometry could be correlated to inhibitory effects on the enzymatic reaction. This study shows that selective inhibitors may exist for the E. coli homologue of the glyoxalase I enzyme.