Reactivity, Selectivity, and Reaction Mechanisms of Aminoguanidine, Hydralazine, Pyridoxamine, and Carnosine as Sequestering Agents of Reactive Carbonyl Species: A Comparative Study.

Reactive carbonyl species (RCS) are endogenous or exogenous byproducts involved in the pathogenic mechanisms of different oxidative-based disorders. Detoxification of RCS by carbonyl quenchers is a promising therapeutic strategy. Among the most studied quenchers are aminoguanidine, hydralazine, pyridoxamine, and carnosine; their quenching activity towards four RCS (4-hydroxy-trans-2-nonenal, methylglyoxal, glyoxal, and malondialdehyde) was herein analyzed and compared. Their ability to prevent protein carbonylation was evaluated in vitro by using an innovative method based on high-resolution mass spectrometry (HRMS). The reactivity of the compounds was RCS dependent: carnosine efficiently quenched 4-hydroxy-trans-2-nonenal, pyridoxamine was particularly active towards malondialdehyde, aminoguanidine was active towards methylglyoxal and glyoxal, and hydralazine efficiently quenched all RCS. Reaction products were generated in vitro and were characterized by HRMS. Molecular modeling studies revealed that the reactivity was controlled by specific stereoelectronic parameters that could be used for the rational design of improved carbonyl quenchers.

Kinetics of glycoxidation of bovine serum albumin by methylglyoxal and glyoxal and its prevention by various compounds.

The aim of this study was to compare several methods for measurement of bovine serum albumin (BSA) modification by glycoxidation with reactive dicarbonyl compounds (methylglyoxal--MGO and glyoxal--GO), for studies of the kinetics of this process and to compare the effects of 19 selected compounds on BSA glycation by the aldehydes. The results confirm the higher reactivity of MGO with respect to GO and point to the usefulness of AGE, dityrosine and N'-formylkynurenine fluorescence for monitoring glycation and evaluation of protection against glycation. Different extent of protection against glycation induced by MGO and GO was found for many compounds, probably reflecting effects on various stages of the glycation process. Polyphenols (genistein, naringin and ellagic acid) were found to protect against aldehyde-induced glycation; 1-cyano-4-hydroxycinnamic acid was also an effective protector.

Glyoxal causes inflammatory injury in human vascular endothelial cells.

To explore mechanisms of diabetes-associated vascular endothelial cells (ECs) injury, human umbilical vein ECs were treated for 24h with high glucose (HG; 26mM), advanced glycation end-products (AGEs; 100mug/ml) or their intermediate, glyoxal (GO: 50-5000muM). HG and AGEs had no effects on ECs morphology and inflammatory states as measured by vascular cell adhesion molecule (VCAM)-1 and cyclooxygenase (COX)-2 expressions. GO (500muM, 24h) induced cytotoxic morphological changes and protein expression of COX-2 but not VCAM-1. GO (500muM, 24h) activated ERK but not JNK, p38 or NF-kappaB. However, ERK inhibitor PD98059 was ineffective to GO-induced COX-2. While EUK134, synthetic combined superoxide dismutase/catalase mimetic, had no effect on GO-mediated inflammation, sodium nitroprusside inhibited it. The present results indicate that glyoxal, a metabolite of glucose might be a more powerful inducer for vascular ECs inflammatory injury. Nitric oxide but not anti-oxidant is preventive against GO-mediated inflammatory injury.

Determination of the structure of tetrahedral transition state analogues bound at the active site of chymotrypsin using 18O and 2H isotope shifts in the 13C NMR spectra of glyoxal inhibitors.

The peptide-derived glyoxal inhibitor Z-Ala-Pro-Phe-glyoxal, where Z is benzyloxycarbonyl, is an extremely potent inhibitor of chymotrypsin. When it is bound to chymotrypsin both the glyoxal (RCOCHO) keto and aldehyde carbons are sp3 hybridized with chemical shifts of 100.7 and 91.4 ppm, respectively. However it is has not been shown whether these carbons are bound as hydrates or whether the active-site serine has reacted with them to form the corresponding hemiketal or hemiacetal. In this study we use 18O isotope shifts to determine whether one or two exchangeable oxygen atoms are attached to the glyoxal keto or aldehyde carbons when it is free in water or bound to alpha-chymotrypsin. Both the 18O isotope shifts at the free and enzyme-bound aldehyde carbons were approximately 0.04 ppm showing that it is hydrated in both the free and bound forms. The 18O isotope shift for the free hydrated keto carbon at 96.6 ppm was 0.046-0.049 ppm, but this was reduced to 0.026 ppm when the glyoxal inhibitor was bound to alpha-chymotrypsin showing that the nonexchangeable serine hydroxyl group has formed a hemiketal with glyoxal keto carbon. Deuterium isotope shifts on the 13C NMR signals from the glyoxal inhibitor when it free and hydrated, when it is bound to chymotrypsin, as well as when it forms a model hemiketal confirm that the serine hydroxyl group has formed a hemiketal with the glyoxal keto carbon. The reasons for the different reaction specificities of glyoxal inhibitors for the active-site nucleophiles of serine and cysteine proteases are discussed.

The cytotoxic mechanism of glyoxal involves oxidative stress.

Glyoxal is a reactive alpha-oxoaldehyde that is a physiological metabolite formed by lipid peroxidation, ascorbate autoxidation, oxidative degradation of glucose and degradation of glycated proteins. Glyoxal is capable of inducing cellular damage, like methylglyoxal (MG), but may also accelerate the rate of glycation leading to the formation of advanced glycation end-products (AGEs). However, the mechanism of glyoxal cytotoxicity has not been precisely defined. In this study we have focused on the cytotoxic effects of glyoxal and its ability to overcome cellular resistance to oxidative stress. Isolated rat hepatocytes were incubated with different concentrations of glyoxal. Glyoxal by itself was cytotoxic at 5mM, depleted GSH, formed reactive oxygen species (ROS) and collapsed the mitochondrial membrane potential. Glyoxal also induced lipid peroxidation and formaldehyde formation. Glycolytic substrates, e.g. fructose, sorbitol and xylitol inhibited glyoxal-induced cytotoxicity and prevented the decrease in mitochondrial membrane potential suggesting that mitochondrial toxicity contributed to the cytotoxic mechanism. Glyoxal cytotoxicity was prevented by the glyoxal traps d-penicillamine or aminoguanidine or ROS scavengers were also cytoprotective even when added some time after glyoxal suggesting that oxidative stress contributed to the glyoxal cytotoxic mechanism.

A 13C-NMR study of the inhibition of papain by a dipeptide-glyoxal inhibitor.

Z-Phe-Ala-glyoxal (where Z is benzyloxycarbonyl) has been synthesized and shown to be a competitive inhibitor of papain with a K(i)=3.30+/-0.25 nM. (13)C-NMR has been used to show that in aqueous media, Z-Phe-[2-(13)C]Ala-glyoxal gives signals at 207.7 p.p.m. and 96.3 p.p.m. showing that both the alpha-keto carbon and its hydrate are present. When this inhibitor is bound to papain a single signal at 209.7 p.p.m. is observed due to the (13)C-enriched carbon. This demonstrates that the glyoxal alpha-keto carbon is not hydrated when it is bound to papain and that it does not form a thiohemiketal with the thiol group of Cys-25. Z-Phe-[1-(13)C]Ala-glyoxal has also been synthesized and its aldehyde carbon is fully hydrated in aqueous solution giving signals at 88.7 p.p.m. and 90.2 p.p.m. when the alpha-keto carbon and its hydrate are present respectively. When this inhibitor is bound to papain a single signal at 71.04 p.p.m. was observed due to the (13)C-enriched carbon showing that the (13)C-enriched aldehyde carbon forms a thiohemiacetal with Cys-25.

Suppressive effect of irsogladine maleate on N-methyl-N-nitro-N-nitrosoguanidine (MNNG)-initiated and glyoxal-promoted gastric carcinogenesis in rats.

The modifying effect of irsogladine maleate (IRG) on N-methyl-N-nitro-N-nitrosoguanidine (MNNG)-initiated and glyoxal-promoted gastric carcinogenesis was examined in male Wistar rats. Six-week-old rats were divided into ten groups. Groups 1 through 6 were given MNNG (100 mg/l in drinking water) for 25 weeks from the start of the experiment, whereas groups 7 through 10 received distilled water in the initiation phase as the vehicle treatment. Groups 1 and 8 were kept on the basal diet and distilled water throughout the experiment (55 weeks). Groups 2-8 were given 0.5% glyoxal in the drinking water for 30 weeks from 26th week of the experiment. Group 3 was fed the diet mixed with 100 ppm IRG for 25 weeks from the start of experiment. Groups 4 and 8 were fed the diet mixed with 100 ppm IRG for 30 weeks from 26th week of experiment. Groups 5 and 9 or 6 were given 100 or 25 ppm IRG containing diet, respectively throughout the experiment. Group 10 was given the basal diet and distilled water as the vehicle treated control. Tumors of upper digestive tracts (stomach and duodenum) were developed in groups: 1 (12/17 rats, 71%), 2 (11/12 rats, 92%), 3 (9/16 rats, 56%), 4 (5/12 rats, 42%), 5 (6/15 rats, 40%) and 6 (7/12 rats, 58%). High dose of IRG in initiation and/or promotion phase significantly reduced the incidence of tumors of the upper digestive tracts. The average numbers of the digestive tracts neoplasms in groups 3,5 and 6 given glyoxal and IRG were less than those in group 2 which received only glyoxal. These results suggest that IRG could be a preventive agent against the occurrence of neoplasms of the upper digestive tract.