Passive cigarette smoke and renal glyoxalase system

Cigarette smoking is associated with a number of fatal diseases, including cancer of different organs. A number of oxoaldehydes are found in cigarette smoke, among which methylglyoxal (MG) is known to cause toxicity to cells upon accumulation. In biological systems, MG is converted to s-d-lactoylglutathione by glyoxalase I with reduced glutathine (GSH) as a cofactor, and s-d-lactoylglutathione is converted to D-lactic acid with simultaneous regeneration of GSH, by glyoxalase II. In the present study, we have investigated the status of the glyoxalase enzymes in kidney tissues from rats exposed to passive cigarette smoke. No significant change has been noted in glyoxalase I activity. Glyoxalase II was decreased during 1 and 2 weeks of exposure, and after that the activity was increased. The initial decrease in the activity of gly II may be due to the excess amount of methylglyoxal generated due to smoke exposure or the adduct formed by MG and GSH which known to inhibit gly II activity. Both enzymes help in the detoxification of cigarette smoke induced chemicals and biochemicals.     

Trypanothione-dependent glyoxalase I in Trypanosoma cruzi

The glyoxalase system, comprizing glyoxalase I and glyoxalase II, is a ubiquitous pathway that detoxifies highly reactive aldehydes, such as methylglyoxal, using glutathione as a cofactor. Recent studies of Leishmania major glyoxalase I and Trypanosoma brucei glyoxalase II have revealed a unique dependence upon the trypanosomatid thiol trypanothione as a cofactor. This difference suggests that the trypanothione-dependent glyoxalase system may be an attractive target for rational drug design against the trypanosomatid parasites. Here we describe the cloning, expression and kinetic characterization of glyoxalase I from Trypanosoma cruzi. Like L. major glyoxalase I, recombinant T. cruzi glyoxalase I showed a preference for nickel as its metal cofactor. In contrast with the L. major enzyme, T. cruzi glyoxalase I was far less fast-idious in its choice of metal cofactor efficiently utilizing cobalt, manganese and zinc. T. cruzi glyoxalase I isomerized hemithio-acetal adducts of trypanothione more than 2400 times more efficiently than glutathione adducts, with the methylglyoxal adducts 2-3-fold better substrates than the equivalent phenylglyoxal adducts. However, glutathionylspermidine hemithioacetal adducts were most efficiently isomerized and the glutathionylspermidine-based inhibitor S-4-bromobenzylglutathionylspermidine was found to be a potent linear competitive inhibitor of the T. cruzi enzyme with a K(i) of 5.4+/-0.6 microM. Prediction algorithms, combined with subcellular fractionation, suggest that T. cruzi glyoxalase I localizes not only to the cytosol but also the mitochondria of T. cruzi epimastigotes. The contrasting substrate specificities of human and trypanosomatid glyoxalase enzymes, confirmed in the present study, suggest that the glyoxalase system may be an attractive target for anti-trypanosomal chemotherapy.     

Yeast glyoxalase I is a monomeric enzyme with two active sites

The tertiary structure of the monomeric yeast glyoxalase I has been modeled based on the crystal structure of the dimeric human glyoxalase I and a sequence alignment of the two enzymes. The model suggests that yeast glyoxalase I has two active sites contained in a single polypeptide. To investigate this, a recombinant expression clone of yeast glyoxalase I was constructed for overproduction of the enzyme in Escherichia coli. Each putative active site was inactivated by site-directed mutagenesis. According to the alignment, glutamate 163 and glutamate 318 in yeast glyoxalase I correspond to glutamate 172 in human glyoxalase I, a Zn(II) ligand and proposed general base in the catalytic mechanism. The residues were each replaced by glutamine and a double mutant containing both mutations was also constructed. Steady-state kinetics and metal analyses of the recombinant enzymes corroborate that yeast glyoxalase I has two functional active sites. The activities of the catalytic sites seem to be somewhat different. The metal ions bound in the active sites are probably one Fe(II) and one Zn(II), but Mn(II) may replace Zn(II). Yeast glyoxalase I appears to be one of the few enzymes that are present as a single polypeptide with two active sites that catalyze the same reaction.     

Role of rpoS in the regulation of glyoxalase III in Escherichia coli

Methylglyoxal is an endogenous electrophile produced in Escherichia coli by the enzyme methylglyoxal synthase to limit the accumulation of phosphorylated sugars. In enteric bacteria methylglyoxal is detoxified by the glutathione-dependent glyoxalase I/II system, by glyoxalase III, and by aldehyde reductase and alcohol dehydrogenase. Here we demonstrate that glyoxalase III is a stationary-phase enzyme. Its activity reached a maximum at the entry into the stationary phase and remained high for at least 20 h. An rpoS- mutant displayed normal glyoxalase I and II activities but was unable to induce glyoxalase III in stationary phase. It thus appears that glyoxalase III is regulated by rpoS and might be important for survival of non-growing E. coli cultures.     

Modification of the glyoxalase system in human HL60 promyelocytic leukaemia cells during differentiation to neutrophils in vitro

The glyoxalase system of human promyelocytic leukaemia HL60 cells was substantially modified during differentiation to neutrophils. The activity of glyoxalase I was decreased and the activity of glyoxalase II was markedly increased relative to the level in control HL60 promyelocytes. There was a decrease in the apparent maximum velocity, Vmax, of glyoxalase I, and an increase in the Vmax of glyoxalase II. The apparent Michaelis constants for both enzymes remained unchanged. The flux of intermediates metabolised via the glyoxalase system increased during differentiation, as judged by the formation of D-lactic acid, whereas the percentage of glucotriose metabolised via the glyoxalase system remained unchanged. The cellular concentrations of the glyoxalase substrates, methylglyoxal and S-D-lactoylglutathione, were markedly decreased during differentiation. The maturation of HL60 promyelocytes is associated with an increased ability to metabolise S-D-lactoylglutathione by glyoxalase II and a concomitant decrease in the mean intracellular concentrations of S-D-lactoylglutathione and methylglyoxal. The maintenance of a high concentration of S-D-lactoylglutathione in HL60 promyelocytes may be related to the status of the microtubular cytoskeleton, since S-D-lactoylglutathione potentiates the GTP-promoted assembly of microtubules.     

Sexual response in Saccharomyces cerevisiae: alteration of enzyme activity in the glyoxalase system by mating factor

Glyoxalase I activity in alpha-type budding yeast of the Saccharomyces cerevisiae strain was increased by exposure of alpha-type cells to supernatant of a culture of a-type yeast cells, although glyoxalase II activity was decreased by the same treatment. The alteration of enzyme activity in the glyoxalase system occurred during the 30-60 min period after exposure of alpha-type cells to a-type culture supernatant. No change of glyoxalase I and II activities was found in the case of the alpha-type strain, S. cerevisiae VQ3 (alpha ste3-1), which is deficient in a-factor receptors.     

The tumor promoting phorbol diester, 12-0-tetradecanoylphorbol-13-acetate (TPA) increases glyoxalase I and decreases glyoxalase II activity in human polymorphonuclear leukocytes

Glyoxalase I and II catalyze the formation and breakdown of S-lactoylglutathione respectively. Recent studies have implicated this com-pound as a possible mediator of immune and inflammatory responses. Incubation of human polymorphonuclear leukocytes with the tumor promoter, 12-0-tetradecanoylphorbol-13-acetate has been found to affect the activities of both glyoxalase enzymes in an interrelated manner. The diester either increases the activity of glyoxalase I or decreases the activity of glyoxalase II or has both effects. It is suggested that a subsequent increase in S-lactoylglutathione might mediate some or all of the effects of the phorbol diesters.     

Identification of immunodominant regions of Brassica juncea glyoxalase I as potential antitumor immunomodulation targets

Glyoxalase I activity has been shown to be directly related to cancer and its inhibitors have been used as anti-cancer drugs. Immunochemical studies have shown immunochemical relatedness among animal and plant glyoxalase I, but its potential application for biomedical research has not been investigated. In order to understand the conserved immunochemical regions of the protein and to determine probable immunomodulation targets, a cellulose-bound scanning peptide library for Brassica juncea glyoxalase I was made using the spot synthesis method. Immuno-probing of the library, using B. juncea anti-glyoxalase I monospecific polyclonal antibodies, revealed three immunodominant regions, epitope I, II, and III. In the homology model of B. juncea glyoxalase I generated by threading its sequence onto the human glyoxalase I, the high accessible surface area and the hydrophilic nature of the epitopes confirmed their surface localization and hence their accessibility for antigen-antibody interaction. Epitopes I and II were specific to B. juncea glyoxalase I. Localizing the epitopes on available glyoxalase I sequences showed that epitope III containing the active site region was conserved across phyla. Therefore, this could be used as a potential immunomodulation target for cancer therapy. Moreover, as the most immunogenic epitopes were mapped on the surface of the protein, this method could be used to discover potential therapeutic targets. It is a simple and fast approach for such investigations. This study, to our knowledge, is the first in epitope mapping of glyoxalase I and has great biomedical potential.     

Induction of mouse liver glyoxalase I by hypobaric hypoxia

Hypobaric hypoxia at 0.45 atm induced a reversible increase of mouse liver glyoxalase I. The levels of this enzyme increased after an exposure of 20 h and 20 + 20 h, whereas the activity decreased to the control values after 20 h at room pressure. Before the treatment, some animals received tritiated leucine (i.p.). Glyoxalase I was purified to homogeneity. The pure enzyme from the treated animals showed 20-times more radioactivity than the controls. Thus, the increase in specific activity is due to new protein synthesized in response to the treatment at 0.45 atm. The activities of glyoxalase II and glutathione S-transferase were not affected by the treatment.     

In situ kinetic analysis of glyoxalase I and glyoxalase II in Saccharomyces cerevisiae.

The kinetics of glyoxalase I [(R)-S-lactoylglutathione methylglyoxal-lyase; EC 4.4.1.5] and glyoxalase II (S-2-hydroxyacylglutathione hydrolase; EC 3.1.2.6) from Saccharomyces cerevisiae was studied in situ, in digitonin permeabilized cells, using two different approaches: initial rate analysis and progress curves analysis. Initial rate analysis was performed by hyperbolic regression of initial rates using the program HYPERFIT. Glyoxalase I exhibited saturation kinetics on 0.05-2.5 mM hemithioacetal concentration range, with kinetic parameters Km 0.53 +/- 0.07 mM and V (3.18 +/- 0.16) x 10(-2) mM.min(-1). Glyoxalase II also showed saturation kinetics in the SD-lactoylglutathione concentration range of 0.15-3 mM and Km 0.32 +/- 0.13 mM and V (1.03 +/- 0.10) x 10(-3) mM.min(-1) were obtained. The kinetic parameters of both enzymes were also estimated by nonlinear regression of progress curves using the raw absorbance data and integrated differential rate equations with the program GEPASI. Several optimization methods were used to minimize the sum of squares of residuals. The best parameter fit for the glyoxalase I reaction was obtained with a single curve analysis, using the irreversible Michaelis-Menten model. The kinetic parameters obtained, Km 0.62 +/- 0.18 mM and V (2.86 +/- 0.01) x 10(-2) mM.min(-1), were in agreement with those obtained by initial rate analysis. The results obtained for glyoxalase II, using either the irreversible Michaelis-Menten model or a phenomenological reversible hyperbolic model, showed a high correlation of residuals with time and/or high values of standard deviation associated with Km. The possible causes for the discrepancy between data obtained from initial rate analysis and progress curve analysis, for glyoxalase II, are discussed.     

Modification of the glyoxalase system during the functional activation of human neutrophils

The glyoxalase system catalyses the metabolism of methylglyoxal to D-lactic acid, via the intermediate S-D-lactoylglutathione. It is present in human neutrophils and undergoes a significant modification during functional activation--induction of chemotaxis, phagocytosis and degranulation. During the activation of neutrophils with serum-opsonised zymosan and the tumour-promoting phorbol diester 12-O-tetradecanoylphorbol 13-acetate, the activity of glyoxalase I increases and the activity of glyoxalase II decreases by 20-40% of their activities in resting cells, in the initial 10 min of the activation period. Determination of the Michaelis constant, Km, and the apparent maximum velocity, Vmax, for these enzymatic reactions indicates that the change in activity is due to a non-competitive activation and inhibition of glyoxalase I and glyoxalase II, respectively. This is consistent with a modification of the glyoxalase enzyme protein during the activation response. This modification occurs under aerobic and anaerobic incubation conditions. The concentration of S-D-lactoylglutathione increases approx. 100% of the resting cell concentration during the initial 10 min of the activation period. The presence of S-D-lactoylglutathione in neutrophils may be related to its ability to stimulate microtubule assembly.     

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%).     

Metabolism of lipid peroxidation products by the gastro-intestinal nematodes Necator americanus, Ancylostoma ceylanicum and Heligmosomoides polygyrus.

Somatic extracts of the three parasitic nematodes Necator americanus, Ancylostoma ceylanicum and Heligmosomoides polygyrus were able to detoxify a model hydroperoxide and a putative natural peroxide by glutathione-dependent peroxidase activity while cytotoxic carbonyls could be metabolized by NADPH-linked reduction activities. Unlike cestodes and digeneans, the nematodes in this study could not enzymatically conjugate carbonyls with glutathione. The results indicate that the three nematodes can protect themselves against possible host-immune initiated lipid peroxidation of their membranes at the level of the hydroperoxide and at the level of cytotoxic carbonyl, although other protective enzymatic mechanisms are also likely to exist (superoxide dismutase and catalase).     

Molecular cloning of the Pseudomonas putida glyoxalase I gene in Escherichia coli

The glyoxalase I gene of Pseudomonas putida was cloned onto a vector plasmid pBR 322 as a 7.5 kilobase Sau 3AI fragment of chromosomal DNA and the hybrid plasmid was designated pGI 318. The gene responsible for the glyoxalase I activity in pGI 318 was recloned in pBR 322 as a 2.2 kilobase Hin dIII fragment and was designated pGI 423. The P. putida glyoxalase I gene on pGI 318 and pGI 423 was highly expressed in E. coli cells and the glyoxalase I activity level was increased more than 150 fold in the pGI 423 bearing strain compared with that of E. coli cells without pGI 423. The E. coli transformants harboring pGI 318 or pGI 423 could grow normally in the presence of methylglyoxal, although the E. coli cells without plasmid were inhibited to grow and showed the extremely elongated cell shape.     

Isolation of glyoxalase II from bovine liver mitochondria

Bovine liver mitochondria contain about 10% of the total glyoxalase II activity in the homogenate. Electrophoresis and isoelectric focussing of either crude mitochondrial extract or the purified mitochondrial glyoxalase II resolved the enzyme activity into five forms (pl 6.3, 6.7, 7.1, 7.7, and 7.9). Since bovine liver cytosol contains a single form of glyoxalase II (pl 7.5), at least four forms are exclusively mitochondrial with no counterpart in the cytosol. The relative molecular mass of mitochondrial glyoxalase II is about 23-24 kDa, similar to the cytosolic form. The kinetic constants obtained using S-D-lactoyl, S-acetyl-, S-acetoacetyl-, and S-succinyl-glutathione as substrates are similar to those reported for glyoxalase II from rat liver mitochondria. S-D-Lactoyl- and S-acetoacetyl-glutathione are the best substrates. S-Acetylglutathione is the poorest substrate with respect to both Vmax and Km values.     

Paclobutrazol mitigates salt stress in <Emphasis Type="Italic">indica</Emphasis> rice seedlings by enhancing glutathione metabolism and glyoxalase system

Stress-induced methylglyoxal (MG) functions as a toxic molecule, inhibiting plant physiological processes such as photosynthesis and antioxidant defense systems. In the present study, an attempt was made to investigate the MG detoxification through glutathione metabolism in indica rice [Oryza sativa L. ssp. indica cv. Pathumthani 1] under salt stress by exogenous foliar application of paclobutrazol (PBZ). Fourteen-day-old rice seedlings were pretreated with 15 mg L^?1 PBZ foliar spray. After 7 days, rice seedlings were subsequently exposed to 0 (control) or 150 mM NaCl (salt stress) for 12 days. Prolonged salt stress enhanced the production of MG molecules and the oxidation of proteins, leading to decreased activity of glyoxalase enzymes, glyoxalase I (Gly I) and glyoxalase II (Gly II). Consequently, the decreased glyoxalase activities were also associated with a decline in reduced glutathione (GSH) content and glutathione reductase (GR) activity. PBZ pretreatment of rice seedlings under salt stress significantly lowered MG production and protein oxidation, and increased the activities of both Gly I and Gly II. PBZ also increased GSH content and GR activity along with the up-regulation of glyoxalase enzymes, under salt stress. In summary, salinity induced a high level of MG and the associated oxidative damage, while PBZ application reduced the MG toxicity by up-regulating glyoxalase and glutathione defense system in rice seedlings.     

Effect of antidiabetic compounds on glyoxalase I activity in experimental diabetic rat liver

The activity of glyoxalase I from the soluble fraction of diabetic rat liver was found to decrease as compared to the control. Sodium orthovanadate in drinking water and Trigonella foenum graecum seed powder when administered to these diabetic animals were found to reverse the activity of glyoxalase I to control values. A combination of the above two antidiabetic compounds showed a better reversal. Vanadate and Trigonella seed powder treatment separately to diabetic rats also normalized hyperglycemia together with glyoxalase I activity. A combination of vanadate and Trigonella seed powder also restored the other general parameters of the diabetic animals.     

Activation of glyoxalase I during the cell division cycle and its homology with auxin regulated genes

In several plant systems increase in glyoxalase I activity has been correlated with cell proliferation. Cell cycle studies of tobacco protoplasts indicate a rise in glyoxalase I activity prior to G₂/M phase. Further, synthetic auxin, NAA, induced glyoxalase I activity and cell division significantly. This induction was specific in response to auxin only. Cytokinins alone do not induce cell division or increase enzyme activity. Analysis of glyoxalase I cDNA sequence from soybean shows significant homology with auxin inducible genes particularly Nt107 and limited but strong similarity with identified plant mitotic cyclins, implicating glyoxalase I in possible relationship with certain cell division regulating factors.     

Enhancing salt tolerance in a crop plant by overexpression of glyoxalase II

Earlier we have shown the role of glyoxalase overexpression in conferring salinity tolerance in transgenic tobacco. We now demonstrate the feasibility of same in a crop like rice through overproduction of glyoxalase II. The rice glyoxalase II was cloned in pCAMBIA1304 and transformed into rice (Oryza sativa cv PB1) via Agrobacterium. The transgenic plants showed higher constitutive activity of glyoxalase II that increased further upon salt stress, reflecting the upregulation of endogenous glyoxalase II. The transgenic rice showed higher tolerance to toxic concentrations of methylglyoxal (MG) and NaCl. Compared with non-transgenics, transgenic plants at the T1 generation exhibited sustained growth and more favorable ion balance under salt stress conditions. Sneh L. Singla-Pareek and Sudesh Kumar Yadav have contributed equally to this work.