Klaus M. Biemel

Effect of pyridoxamine on chemical modification of proteins by carbonyls in diabetic rats: Characterization of a major product from the reaction of pyridoxamine and methylglyoxal

Advanced glycation end products (AGEs) from the Maillard reaction contribute to protein aging and the pathogenesis of age- and diabetes-associated complications. The alpha-dicarbonyl compound methylglyoxal (MG) is an important intermediate in AGE synthesis. Recent studies suggest that pyridoxamine inhibits formation of advanced glycation and lipoxidation products. We wanted to determine if pyridoxamine could inhibit MG-mediated Maillard reactions and thereby prevent AGE formation. When lens proteins were incubated with MG at 37 degrees C, pH 7.4, we found that pyridoxamine inhibits formation of methylglyoxal-derived AGEs concentration dependently. Pyridoxamine reduces MG levels in red blood cells and plasma and blocks formation of methylglyoxal-lysine dimer in plasma proteins from diabetic rats and it prevents pentosidine (an AGE derived from sugars) from forming in plasma proteins. Pyridoxamine also decreases formation of protein carbonyls and thiobarbituric-acid-reactive substances in plasma proteins from diabetic rats. Pyridoxamine treatment did not restore erythrocyte glutathione (which was reduced by almost half) in diabetic animals, but it enhanced erythrocyte glyoxalase I activity. We isolated a major product of the reaction between MG and pyridoxamine and identified it as methylglyoxal-pyridoxamine dimer. Our studies show that pyridoxamine reduces oxidative stress and AGE formation. We suspect that a direct interaction of pyridoxamine with MG partly accounts for AGE inhibition.

Formation Pathways for Lysine-Arginine Cross-links Derived from Hexoses and Pentoses by Maillard Processes UNRAVELING THE STRUCTURE OF A PENTOSIDINE PRECURSOR

Covalently cross-linked proteins are among the major modifications caused by the advanced Maillard reaction. So far, the chemical nature of these aggregates and their formation pathways are largely unknown. Synthesis and unequivocal structural characterization are reported for the lysine-arginine cross-linksN 6-{2-{[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino}-5-[(2S,3R)-2,3,4- trihydroxybutyl]-3,5-dihydro-4H-imidazol-4-ylidene}-l-lysinate (DOGDIC 12),N 6-{2-{[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino}-5-[(2S)-2,3-dihydroxypropyl]-3,5-dihydro-4H-imidazol-4-ylidene}-l-lysinate (DOPDIC 13), and 6-((6S)-2-{[(4S)-4-ammonio-5-oxido-5-oxopentyl] amino}-6-hydroxy-5,6,7,7a-tetrahydro-4H-imidazo[4,5-b] pyridin-4-yl)-l-norleucinate (pentosinane 10). For these compounds, as well as for glucosepane 9 and pentosidine 11, the formation pathways could be established by starting from native carbohydrates, Amadori products, and 3-deoxyosones, respectively. Pentosinane 10 was unequivocally proven to be an important precursor of pentosidine 11, which is a well established fluorescent indicator for advanced glycation processesin vivo. The Amadori products are shown to be the pivots in the formation of the various cross-links 9–13. The bicyclic structures 9–11 are directly derived from aminoketoses, whereas 12 and 13 stem from reaction with the 3-deoxyosones. All products 9–13 were identified and quantified from incubations of bovine serum albumin with the respective 3-deoxyosone or carbohydrate. From these results it seems fully justified to expect both glucosepane 9 and DOGDIC 12 to constitute important in vivo cross-links.

Identification and quantitative evaluation of the lysine-arginine crosslinks GODIC, MODIC, DODIC, and glucosepan in foods

The presence of the various protein crosslinks GOLD 2, MOLD 3, GODIC 4, MODIC 5, DODIC 6, and glucosepan 7 in foods has been established for the first time by liquid chromatography-mass spectrometry (LC-MS) with electrospray ionization (ESI). In compounds 2 and 3 two lysine moieties, in 4-7 a lysine and an arginine side chain are joined by the crosslink. Unequivocal identification of 2-7 was achieved with independently synthesized reference material. The quantitative results for the investigated foodstuffs show MODIC 5 to be the most important Maillard crosslink. The concentrations of 5 and GODIC 4 are 5-10 fold higher than those of the corresponding imidazolium compounds 3 and 2, establishing 5 and 4 as the major food protein crosslinks derived from methylglyoxal and glyoxal, respectively. The maximum value of 151 mg MODIC 5/kg protein (equivalent to 0.42 mmol/kg protein) was found in a butter biscuit sample which also shows the highest overall Maillard crosslink content with 0.71 mmol 47/kg protein. These first quantitative results suggest that compounds 4-7 can be jointly responsible for protein polymerization in the course of food processing.

Formation pathways for lysine–arginine cross-links derived from hexoses and pentoses by Maillard processes

Abstract α-Dicarbonyl compounds are crucial intermediates in the cross-linking of proteins by reducing sugars in the course of the Maillard reaction. The novel dideoxyosones N6-(2,3-dihydroxy-5,6-dioxohexyl)lysine (9a,b) and N6-(2-hydroxy-4,5-dioxopentyl)lysine (12) were unequivocally identified via their triazine derivatives and these α-diketo compounds established as precursors of the major in vivo cross-links glucosepane 11 and pentosidine 16, respectively. This new dideoxyosone class is formed in high yield in the model incubations and the underlying reaction sequence will improve our understanding of protein cross-linking and of Maillard chemistry in general.

Spiro cross-links: Representatives of a new class of glycoxidation products

Covalently cross-linked proteins are among the major modifications caused by the advanced Maillard reaction. So far, the chemical nature of these aggregates is largely unknown. Investigations are reported on the isolation of 6-[2-[[(4S)-4-amino-4-carboxybutyl]amino]-6,7-dihydroxy-6,7-dihydroimidazo[4,5-b]azepin-4(5H)-yl]-L-norleucine (10) and N-acetyl-6-[(6R,7R)-2-[[4-(acetylamino)-4-carboxybutyl]amino]-6,7,8a-trihydroxy-6,7,8,8a-tetrahydroimidazo[4,5-b]azepin-4(5H)-yl]-L-norleucine (12) formed by oxidation of the major Maillard cross-link glucosepane 1. Independent synthesis and unequivocal structural characterization are given for 10 and 12. Spiro cross-links, representing a new class of glycoxidation products, were obtained by dehydrogenation of the amino imidazolinimine compounds N6-[2-[[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino]-5-[(2S,3R)-2,3,4-trihydroxybutyl]-3,5-dihydro-4H-imidazol-4-ylidene]-L-lysinate (DOGDIC 2) and N6-[2-[[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino]-5-[(2S)-2,3-dihydroxypropyl]-3,5-dihydro-4H-imidazol-4-ylidene]-L-lysinate (DOPDIC 3). These new oxidation products were synthesized, and their unambiguous structural elucidation proved the formation of the spiro imidazolimine structures N6-[(7R,8S)-2-[[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino]-8-hydroxy-7-(hydroxymethyl)-6-oxa-1,3-diazaspiro[4.4]non-1-en-4-ylidene]-L-lysinate (16), N6-(8R,9S)-2-[(4S)-4-ammonio-5-oxido-5-oxopentyl]amino]-8,9-dihydroxy-6-oxa-1,3-diazaspiro[4.5]dec-1-en-4-ylidene)-L-lysinate (19), and N6-[(8S)-2-[(4-amino-4-carboxybutyl)amino]-8-hydroxy-6-oxa-1,3-diazaspiro[4.4]non-1-en-4-ylidene]-L-lysinate (18), respectively. It was shown that reaction of the imidazolinone 15 led to the formation of spiro imidazolones, structurally analogous to 16 and 19.