Chemical modification of tyrosine residues in glyoxalase I from yeast and human erythrocytes

1. Yeast glyoxalase I was inactivated by N-acetylimidazole and tetranitromethane, the latter process following pK app 7.31 and irreversibly producing a protein with a spectrum typical of 3-nitrotyrosine. 2. For yeast glyoxalase I, amino-acid analysis and protection studies with S-(p-bromobenzyl)glutathione, a competitive inhibitor, indicated two classes of tetranitromethane-reactive tyrosine residues, fast- and slow-reacting, with the latter class containing the crucial tyrosine(s). 3. Human erythrocyte glyoxalase I was inactivated by tetranitromethane in fast and slow processes, protection studies in this case indicating the important tyrosine(s) as fast-reacting.     

Characterization of glyoxalase I purified from pig erythrocytes by affinity chromatography

The linear order of nine fragments generated by the action of endonuclease AvaI on the DNA of bacteriophage lambda was determined from the altered fragmentation patterns of bacteriophages containing known deletions and of hybrids of bacteriophages lambda and phi80. Digestion of 5'-terminally 32P-labelled bacteriophage-lambda DNA was used to identify the terminal fragments. Measurement of relative fragment lengths permitted rough mapping of the endonuclease-AvaI cleavage sites relative to the ends of the bacteriophage-lambda chromosome. The fragment order was confirmed and the map refined by analysis of the fragmentation of derivative phages containing single cleavage sites for endonuclease EcoRI.     

Role of the N-terminus of glutathione in the action of yeast glyoxalase I.

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.     

pH Dependence of the inhibition of yeast glyoxalase I by porphyrins

A number of porphyrin derivatives have been found to inhibit yeast glyoxalase I (EC 4.4.1.5) at 25 degrees C, including haemin, protoporphyrin IX, coproporphyrin III, haematoporphyrin, deuteroporphyrin as well as meso-(tetrasubstituted) porphines. Bilirubin and chlorophyllin were also inhibitory, but not cobalamin, adipic, pimelic or suberic acids. Whilst the Ki value for linear competitive inhibition by meso-tetra(4-methylpyridyl)porphine was pH-dependent, analogous Ki values for meso-tetra(4-carboxyphenyl)- and meso-tetra(4-sulphonatophenyl)porphines followed the Henderson-Hasselbalch equation with pKapp values of 7.10 and 6.50, respectively. Protoporphyrin showed similar behaviour (pKapp 7.06) with a deviation at lower pH. The haemin pH profile for Ki showed a maximum at approx. pH 6.5. The redox reaction between haemin and glutathione did not interfere in the inhibition studies. The Ki value for S-(p-bromobenzyl)glutathione was pH-independent. A detailed analysis of porphyrin binding modes was undertaken.     

Purification of glyoxalase I from human erythrocytes by the use of affinity chromatography and separation of the three isoenzymes.

Glyoxalase I has been purified to homogeneity from human erythrocytes. An essential part in the purification procedure involved affinity chromatography on S-hexylglutathione bound to epoxy-activated Sepharose 6B. Three isoenzymes were found, which could be separated by ion-exchange chromatography. Some of the properties of the enzyme are reported.     

Probing the active site of glyoxalase I from human erythrocytes by use of the strong reversible inhibitor S-p-bromobenzylglutathione and metal substitutions

Glyoxalase I from human erythrocytes was studied by use of the strong reversible competitive inhibitor S-p-bromobenzylglutathione. Replacements of cobalt, manganese and magnesium for the essential zinc in the enzyme were made by a new procedure involving 10% methanol as a stabilizer of the enzyme. The K_m value for the adduct of methylglyoxal and glutathione was essentially unchanged by the metal substitutions, whereas the inhibition constant for S-p-bromobenzylglutathione increased from 0.08μm for the Zn-containing enzyme to 1.3, 1.7 and 2.4μm for Co-, Mn- and Mg-glyoxalase I respectively. Binding of the inhibitor to the enzyme caused quenching of the tryptophan fluorescence of the protein, from which the binding parameters could be determined by the use of non-linear regression analysis. The highest dissociation constant was obtained for apoenzyme (6.9μm). The identity of the corresponding kinetic and binding parameters of the native enzyme and the Zn²⁺-re-activated apoenzyme and the clear differences from the parameters of the other metal-substituted enzyme forms give strong support to the previous identification of zinc as the natural metal cofactor of glyoxalase I. Binding to apoenzyme was also shown by the use of S-p-bromobenzylglutathione as a ligand in affinity chromatography and as a protector in chemical modification experiments. The tryptophan-modifying reagent 2-hydroxy-5-nitrobenzyl bromide caused up to 85% inactivation of the enzyme. After blocking of the thiol groups (about 8 per enzyme molecule) 6.1 2-hydroxy-5-nitrobenzyl groups were incorporated. Inclusion of S-p-bromobenzylglutathione with the modifying reagent preserved the catalytic activity of the enzyme completely and decreased the number of modified residues to 4.4 per enzyme molecule. The findings indicate the presence of one tryptophan residue in the active centre of each of the two subunits of the enzyme. Thiol groups appear not to be essential for catalytic activity. The presence of at least two categories of tryptophan residues in the protein was also shown by quenching of the fluorescence by KI.     

Immunological comparison of glyoxalase I from yeast and mammals and quantitative determination of the enzyme in human tissues by radioimmunoassay

Antibodies to glyoxalase I from yeast, rat liver, porcine erythrocytes and human erythrocytes were raised in rabbits. Gel precipitation and immunotitration experiments demonstrated that the mammalian enzymes were immunologically related, but distinct from the yeast enzyme. Fab fragments of the antibodies to human glyoxalase I did not inhibit the catalytic activity, indicating that the antigen binding sites were not directed towards the active site of the enzyme. A radioimmunoassay for glyoxalase I was developed. Quantitative analysis of human adult as well as fetal organs demonstrated that glyoxalase I was present in a concentration of approximately 0.2 micrograms/mg protein in most human tissues.     

Comparison of glyoxalase I purified from yeast (Saccharomyces cerevisiae) with the enzyme from mammalian sources

Glyoxalase I from yeast (Saccharomyces cerevisiae) purified by affinity chromatography on S-hexylglutathione-Sepharose 6B was characterized and compared with the enzyme from rat liver, pig erythrocytes and human erythrocytes. The molecular weight of glyoxalase I from yeast was, like the enzyme from Rhodospirillum rubrum and Escherichia coli, significantly less (approx. 32000) than that of the enzyme from mammals (approx. 46000). The yeast enzyme is a monomer, whereas the mammalian enzymes are composed of two very similar or identical subunits. The enzymes contain 1Zn atom per subunit. The isoelectric points (at 4 degrees C) for the yeast and mammalian enzymes are at pH7.0 and 4.8 respectively; tryptic-peptide ;maps' display corresponding dissimilarities in structure. These and some additional data indicate that the microbial and the mammalian enzymes may have separate evolutionary origins. The similarities demonstrated in mechanistic and kinetic properties, on the other hand, indicate convergent evolution. The k(cat.) and K(m) values for the yeast enzyme were both higher than those for the enzyme from the mammalian sources with the hemimercaptal adduct of methylglyoxal or phenylglyoxal as the varied substrate and free glutathione at a constant and physiological concentration (2mm). Glyoxalase I from all sources investigated had a k(cat.)/K(m) value near 10(7)s(-1).m(-1), which is close to the theoretical diffusion-controlled rate of enzyme-substrate association. The initial-velocity data show non-Michaelian rate saturation and apparent non-linear inhibition by free glutathione for both yeast and mammalian enzyme. This rate behaviour may have physiological importance, since it counteracts the effects of fluctuations in total glutathione concentrations on the glyoxalase I-dependent metabolism of 2-oxoaldehydes.     

Structural variation in bacterial glyoxalase I enzymes: investigation of the metalloenzyme glyoxalase I from Clostridium acetobutylicum

The glyoxalase system catalyzes the conversion of toxic, metabolically produced α-ketoaldehydes, such as methylglyoxal, into their corresponding nontoxic 2-hydroxycarboxylic acids, leading to detoxification of these cellular metabolites. Previous studies on the first enzyme in the glyoxalase system, glyoxalase I (GlxI), from yeast, protozoa, animals, humans, plants, and Gram-negative bacteria, have suggested two metal activation classes, Zn(2+) and non-Zn(2+) activation. Here, we report a biochemical and structural investigation of the GlxI from Clostridium acetobutylicum, which is the first GlxI enzyme from Gram-positive bacteria that has been fully characterized as to its three-dimensional structure and its detailed metal specificity. It is a Ni(2+)/Co(2+)-activated enzyme, in which the active site geometry forms an octahedral coordination with one metal atom, two water molecules, and four metal-binding ligands, although its inactive Zn(2+)-bound form possesses a trigonal bipyramidal geometry with only one water molecule liganded to the metal center. This enzyme also possesses a unique dimeric molecular structure. Unlike other small homodimeric GlxI where two active sites are located at the dimeric interface, the C. acetobutylicum dimeric GlxI enzyme also forms two active sites but each within single subunits. Interestingly, even though this enzyme possesses a different dimeric structure from previously studied GlxI, its metal activation characteristics are consistent with properties of other GlxI. These findings indicate that metal activation profiles in this class of enzyme hold true across diverse quaternary structure arrangements.     

Production of S-lactoylglutathione by organic-solvent-extracted glyoxalase I from Hansenula mrakii

Summary Glyoxalase I was extracted from Hansenula mrakii IFO 0895 by incubating the cells with buffer solution containing 50% acetone (enzyme activity 35 units/g cells) or 50% ethyl acetate (enzyme activity 28 units/g cells) at 30°C for 10 h. Glyoxalase II was also extracted from the cells, although the activity of the enzyme was lost during incubation with organic solvents, especially at higher temperature (30°C). By using the organic-solvent-extracted fraction of H. mrakii, enzymatic production of S-lactoylglutathione was studied, and approximately 82 mmol/l (30 g/l) of S-lactoylglutathione was produced from 120 mmol/l glutathione. Offprint requests to: A. Kimura     

Cloning and characterization of glyoxalase I from soybean

Glyoxalase I and glutathione transferase (GST) are two glutathione-dependent enzymes which are enhanced in plants during cell division and in response to diverse stress treatments. In soybean, a further connection between these two enzymes has been suggested by a clone (Accession No. X68819) resembling a GST being described as a glyoxalase I. To characterize glyoxalase I in soybean, GmGlyox I resembling the dimeric enzyme from animals has been cloned from a cDNA library prepared from soybean suspension cultures. When expressed in Escherichia coli, GmGlyox I was found to be a 38-kDa dimer composed of 21-kDa subunits and unlike the enzyme from mammals showed activity in the absence of metal ions. GmGlyox I was active toward the hemithioacetal adducts formed by reacting methylglyoxal, or phenylglyoxal, with glutathione, homoglutathione, or gamma-glutamylcysteine, showing no preference for homoglutathione adducts over glutathione adducts, even though homoglutathione is the dominant thiol in soybean. When the clone X68819 was expressed in E. coli, the respective recombinant enzyme was active as a GST rather than a glyoxalase and was termed GmGST 3. GmGST 3 was active as a homodimer (45 kDa) composed of 26-kDa subunits and showed a preference for glutathione over homoglutathione when conjugating 1-chloro-2,4-dinitrobenzene. Both enzymes are associated with cell division in soybean cultures, but GmGST 3 (0.4% total protein) was 40 times more abundant than GmGlyox I (0.01%).     

Purification and characterization of glyoxalase I from Hansenula mrakii

Glyoxalase I was purified from Hansenula mrakii IFO 0895 which was resistant to 25 mM methylglyoxal. The molecular weight of the purified enzyme was calculated to be 38,000 by both gel-filtration of Sephadex G-150 and SDS-PAGE. The enzyme was almost specific to methylglyoxal (K_m = 0.91 mM). The activity of the enzyme was not inhibited by metal ion chelators such as EDTA, which is a potent inhibitor for glyoxalase Is from other sources.