Collagen in its fibrillar state is protected from glycation

To assess the impact collagen structures may have on glycation, the effects of glucose upon bovine serum albumin, guinea pig skin collagen, rat tail tendon and monomeric collagen were compared under near physiological conditions. Proteins were incubated with or without 50 mM glucose for 64 d in pH 7.4 50 mM phosphate buffer, followed by reduction, acid/alkaline hydrolysis, and analysis. Yields of non-reducible fructose-lysine, in the form of the acid-degradation products furosine and pyridosine, were significantly higher from skin collagen when compared to albumin. Yields of reducible fructose-lysine, in the form of glucitol- and mannitol-lysine, were conversely much greater for albumin, while tail tendon reported intermediate values. Fructose-lysine and unmodified lysine within collagen fibres prior to incubation was therefore protected by the tight packing of the collagen helices, where milling of tail tendon to increase the surface area exposed much of it to reduction protocols. Together with an analysis of pentosidine formation and other products, these results have shown that the interior of the tightly packed skin collagen fibres is protected from both glycation and reduction, and that glycation products differ depending on the protein incubated. Amino acid analysis then showed that our glycated skin collagen was similar to human diabetic skin collagen. Significant quantities of glucose-independent unknowns form in control incubations; their composition again being protein-dependent. The four compound Ks as previously reported were found to be unique to glycated rat tail tendon and soluble collagen, while another glycation product detected in collagen but not albumin may be attributable to carboxymethyl-arginine.     

Identification of N(omega)-carboxymethylarginine, a new advanced glycation endproduct in serum proteins of diabetic patients: possibility of a new marker of aging and diabetes

A new advanced glycation end product (AGE), N(omega)-carboxymethyl-arginine (CMA), was found in acid-soluble skin collagen of a newborn bovine prepared by in vitro glycation with 1 M glucose incubation at 37 degrees C for about 30 days [ 1 ]. CMA production was increased with incubation time in parallel, and after 30 days incubation the yield was 100 times higher than that of pentosidine [ 1 ]. This result suggested the importance of CMA as a major AGE in collagen. We have detected and measured the CMA level in human serum proteins by electrospray ionization/liquid chromatography/mass spectrometry (ESI/LC/MS), using CMA standard concentration curve. In this report, we first show the existence of CMA in vivo, and its serum level is significantly elevated in diabetic serum proteins, compared to age-matched control serum proteins. These results provide strong evidence that CMA is a new diagnostic marker of glycation in diabetes.     

Inhibition of advanced glycation end product formation on collagen by rutin and its metabolites

Several lines of evidence suggest that rutin, flavonoid in fruits and vegetables, or one of its metabolites may effectively modulate advanced glycation end product (AGE) formation. Following ingestion, rutin forms metabolites that include 3,4-dihydroxyphenylacetic acid (3,4-DHPAA), 3,4-dihydroxytoluene (3,4-DHT), m-hydroxyphenylacetic acid (m-HPAA), 3-methoxy-4-hydroxyphenylacetic acid (homovanillic acid, HVA) and 3,5,7,3',5'-pentahydroxyflavonol (quercetin). We studied the effects of rutin and its metabolites on the formation of AGE biomarkers such as pentosidine, collagen-linked fluorescence, N(epsilon)-carboxymethyllysine (CML) adducts, glucose autoxidation and collagen glycation, using an in vitro model where collagen I was incubated with glucose. Rutin metabolites containing vicinyl dihydroxyl groups, i.e., 3,4-DHT, 3,4-DHPAA and quercetin, inhibited the formation of pentosidine and fluorescent adducts, glucose autoxidation and glycation of collagen I in a dose-dependent manner, whereas non-vicinyl dihydroxyl group-containing metabolites, i.e., HVA and m-HPAA, were much less effective. All five metabolites of rutin effectively inhibited CML formation. In contrast, during the initial stages of glycation and fluorescent AGE product accumulation, only vicinyl hydroxyl group-containing rutin metabolites were effective. These studies demonstrate that rutin and circulating metabolites of rutin can inhibit early glycation product formation, including both fluorescent and nonfluorescent AGEs induced by glucose glycation of collagen I in vitro. These effects likely contribute to the beneficial health effects associated with rutin consumption.     

Early glycation products produce pentosidine cross-links on native proteins. novel mechanism of pentosidine formation and propagation of glycation

Bovine lens alpha-crystallin was immobilized on EAH-Sepharose gel and glycated using d-ribose. Incubation with 500 and 100 mm d-ribose for 2 and 15 days produced short-term glycated (STGP gel) and long-term glycated proteins (LTGP gel). Both STGP and LTGP gels produced oxygen free radicals. Hydroxyl radical production was twice that in STGP gel compared with the LTGP gel. Incubation with the glycated gels produced pentosidine in a mixture of N-alpha-acetylarginine + N-alpha-acetyllysine, bovine lens proteins (BLP), and lysozyme; the amounts measured with STGP gel were higher than those with LTGP gel. Reactive oxygen species scavengers decreased the formation of pentosidine. Pentosidine was also formed in BLP when incubated with water-insoluble proteins extracted from aged or brunescent human lenses. Early glycated proteins from aged or diabetic lenses were bound to a boronate affinity column, the protein-containing gel was incubated with BLP, and pentosidine was measured in the incubation mixtures. With this method we found that diabetic lens proteins produced more pentosidine on BLP than did aged lens proteins. Further investigation indicates that two and three carbon carbohydrates possibly formed from oxidative cleavage of early glycation products are involved in pentosidine formation. Based on our findings, we propose a novel pathway for pentosidine formation on native proteins from glycated proteins.     

The pentosidine concentration in human blood specimens is affected by heating

Pentosidine is an advanced glycation end product, formed by oxidation and glycation that accumulates markedly during end-stage renal failure. Measurement of the pentosidine level in physiological samples is applied as a sensitive marker for the early diagnosis of renal failure. In the quantitative measurements of pentosidine reported to date, a rapid enzyme-linked immunosorbent assay (ELISA) has been widely used to estimate the plasma/serum pentosidine levels in a number of clinical samples, because high performance liquid chromatography (HPLC) methods require multiple preparation steps before the analysis. However, the currently used clinical analysis of the plasma/serum pentosidine level by ELISA requires incubation of the plasma/serum at 100°C for 15 min to inactivate the protease, which is required before the anti-pentosidine antibody can bind to the pentosidine. In the present study, we examined whether pentosidine could be generated artificially through the heating of serum. The pentosidine content, measured by HPLC, in the serum increased by heating in a temperature- and time-dependent manner. The pentosidine content was increased 1.1- to 4.2-fold by the heating process compared to unheated samples, and the increased rate was not identical for each sample. After removing low-molecular weight (<10,000) serum components, the heat-induced pentosidine formation was decreased. Furthermore, the increase in pentosidine formation was significantly inhibited by acidic conditions more than by the addition of diethylene triamine pentaacetic acid, a metal chelator. This indicates that the level of serum pentosidine will be measured more accurately by ELISA if hydrochloric acid is added during the heating process.     

Modification of albumin with different degrees of the oxidation of SH-groups in the reaction with glucose

A molecule of the major blood protein albumin contains 34 cysteine residues involved in disulfide bonds and one unpaired SH-group of residue Cys34. Normally, 20–30% of these SH-groups are oxidized and form disulfide bonds or the derivatives of sulfenic, sulfinic, and sulfonic acids. The goal of the present work was to study the influence of the degree of oxidation of sulfhydryl groups on the capacity of albumin for glycation. Commercially available human albumin containing 0.4 moles of sulfhydryl groups per 1 mole of the protein (nonmercaptalbumin) was used. Disulfide bonds in this preparation were reduced with dithiothreitol to 0.7 mole/mole to give mercaptalbumin. The preparations were incubated for three weeks with glucose at a concentration of 5 and 50 mM. The content of ketoamine, a glycation product, was determined by the colorimetric method, the content of pentosidine (glycation end product) was analyzed by fluorescence, and the content of SH-groups was determined using the Ellman’s reagent. Changes in the structure and properties of the protein during glycation were studied by fluorescence and HPLC. During the incubation of both albumin preparations with 5 mM glucose, no significant increase in the ketoamine content was observed, whereas the incubation with 50 mM glucose was accompanied by a considerable accumulation of ketoamine. It was found that the greatest amount of ketoamine under these conditions forms in nonmercaptalbumin; in this case, the intensity of tryptophan fluorescence decreases. The intensity of pentosidine fluorescence increases with increasing content of ketoamine. The results obtained enable the conclusion that the oxidation of free SH-groups of the protein changes its conformation; as a result, the glycation of earlier hidden sites becomes possible, and the degree of protein glycation increases.     

Longitudinal determination of skin collagen glycation and glycoxidation rates predicts early death in C57BL/6NNIA mice.

In 1988, the National Institute on Aging launched a 10-year program aimed at identification of biomarkers of aging. Previous results from our laboratory showed that pentosidine, an advanced glycation product, formed in skin collagen at a rate inversely related to maximum life span across several mammalian species. As part of the Biomarkers Program, we investigated the hypothesis that longitudinal determination of glycation and glycoxidation rates in skin collagen could predict longevities in ad libitum-fed (AL) and caloric restricted (CR) mice. C57BL/6NNia male mice were biopsied at age 20 months and at natural death. Glycation (furosine method) was assessed by gas chromatography/mass spectrometry (GC/MS) and the glycoxidation products carboxymethyllysine (CML) and pentosidine were determined by GC/MS and HPLC, respectively. CR vs. AL significantly (P<0.0001) increased both mean (34 vs. 27 months) and maximum (47 vs. 31 months) life spans. Skin collagen levels of furosine (pmol/micromol lysine) were approximately 2.5-fold greater than CML levels and 100-fold greater than pentosidine. Individual accumulation rates modeled as linear equations were significantly (P<0.001) inhibited by CR vs. AL for all parameters and in all cases varied inversely with longevity (P<0.1 to <0.0001). The incidence of three tissue pathologies (lymphoma, dermatitis, and seminal vesiculitis) was found to be attenuated by CR and the latter pathology correlated significantly with longevities (r=0.54, P=0. 002). The finding that markers of skin collagen glycation and glycoxidation rates can predict early deaths in AL and CR C57BL/6NNia mice strongly suggests that an age-related deterioration in glucose tolerance is a life span-determining process.     

Glycation-induced matrix stability in the rabbit achilles tendon

Connective tissue susceptibility to nonenzymatic glycation was examined following 0, 2, 4, 6, 8, and 10 weeks of incubating the rabbit Achilles tendon in phosphate-buffered saline containing ribose (glycated). The biomechanical integrity of the glycated tendons was then compared to control tendons incubated in phosphate-buffered saline (non-glycated) at each time interval, while the biochemical stability of both groups of tendons was determined by examining collagen extractability and the formation of pentosidine at 8 weeks. Whereas there were no significant biomechanical differences between control and glycated tendons at 0- and 2-week intervals (P > 0.05), moderately significant increases in maximum load, energy to yield, and toughness of glycated tendons were observed at 4 weeks. Beyond 4 weeks of incubation, the differences between glycated and non-glycated tendons became highly significant, as glycated tendons withstood more load and tensile stress (P < 0.01 for each variable), attained significantly higher modulus of elasticity (P < 0.01), absorbed more energy (P < 0.01), and became tougher (P < 0.01) than controls. These differences in the biomechanical indices of the effects of glycation were stable between the 6th and 10th week of glycation. The maximum increases in the biomechanical measurements as a result of glycation were 29% for maximum load, 125% for stress, 19% for strain, 106% for Young's modulus of elasticity, 14% for energy to yield, and 57% for toughness. Biochemical analysis showed a 61% reduction in the extractability of neutral salt-soluble collagen, a 48% decrease in acid-soluble collagen, and a 29% decline in pepsin-soluble collagen in glycated tendons (P < 0.01). In contrast, there was a 28% increase in the amount of insoluble collagen and significantly higher amounts of pentosidine (P < 0.01) in glycated tendons. Collectively, these biomechanical and biochemical results suggest that nonenzymatic glycation may explain the altered stability of connective tissue matrix induced by the processes of diabetes and aging.     

Nonenzymatic glycation of cartilage proteoglycans: an in vivo and in vitro study

In this study we have investigated whether proteoglycans (aggrecan) are modified by nonenzymatic glycation as in collagen. Purified human aggrecan from osteoarthritic and normal human knee articular cartilage was assayed for pentosidine, a cross-link formed by nonenzymatic glycation, using reverse-phase HPLC. In addition, an in vitro study was done by incubation of purified bovine nasal cartilage aggrecan with ribose. Pentosidine was found in all the purified human aggrecan samples. 2-3% of the total articular cartilage pentosidine was found in aggrecan. Purified link protein also contained penosidine. The in vitro study led to pentosidine formation, but did not appear to increase the molecular size of the aggrecan suggesting that pentosidine was creating intramolecular cross-links. Similar amounts of glycation were found in osteoarthritic and normal cartilage. Like collagen, aggrecan and link proteins are crosslinked by nonenzymatic glycation in normal and osteoarthritic cartilage. Crosslinking could be reproduced, in vitro, by incubating aggrecan with ribose. This revised version was published online in August 2006 with corrections to the Cover Date.     

Characterization of the glycated human cerebrospinal fluid proteome

Protein glycation is a nonenzymatic modification that involves pathological functions in neurological diseases. Despite the high number of studies showing accumulation of advanced end glycation products (AGEs) at clinical stage, there is a lack of knowledge about which proteins are modified, where those modifications occur, and to what extent. The goal of this study was to achieve a comprehensive characterization of proteins modified by early glycation in human cerebrospinal fluid (CSF). Approaches based on glucose diferential labeling and mass spectrometry have been applied to evaluate the glycated CSF proteome at two physiological conditions: native glucose level and in vitro high glucose content. For both purposes, detection of glycated proteins was carried out by HCD-MS2 and CID-MS3 modes after endoproteinase Glu-C digestion and boronate affinity chromatography. The abundance of glycation was assessed by protein labeling with (13)C(6)-glucose incubation. The analysis of native glycated CSF identified 111 glycation sites corresponding to 48 glycated proteins. Additionally, the in vitro high glucose level approach detected 265 glycation sites and 101 glycated proteins. The comparison of glycation levels under native and 15 mM glucose conditions showed relative concentration increases up to ten folds for some glycated proteins. This report revealed for the first time a number of key glycated CSF proteins known to be involved in neuroinflammation and neurodegenerative disorders. Altogether, the present study contains valuable and unique information, which should further help to clarify the pathological role of glycation in central nervous system pathologies. This article is part of a Special Issue entitled: Translational Proteomics.     

Acetoacetate promotes the formation of fluorescent advanced glycation end products (AGEs)

Acetoacetate (AA) is an important ketone body, which produces reactive oxygen species (ROS). Advanced glycation end products (AGEs) are defined as final products of glycation process whose production is influenced by the levels of ROS. The accumulation of AGEs in the body contributes to pathogenesis of many diseases including complications of diabetes, and Alzheimer’s and Parkinson’s disease. Here, we evaluated the impact of AA on production of AGEs upon incubation of human serum albumin (HSA) with glucose. The effect of AA on the AGEs formation of HSA was studied under physiological conditions after incubation with glucose for 35 days. The physical techniques including circular dichroism (CD) and fluorescence spectroscopy were used to assess the impact of AA on formation and structural changes of glycated HSA (GHSA). Our results indicated that the secondary and tertiary structural changes of GHSA were increased in the presence of AA. The fluorescence intensity measurements of AGEs also showed an increase in AGEs formation. Acetoacetate has an activator effect in formation of AGEs through ROS production. The presence of AA may result in enhanced glycation in the presence of glucose and severity of complications associated with accumulation of AGEs.     

Early and advanced glycation end-products are increased in dietary copper deficiency

The hypothesis that nonenzymatic glycosylation of proteins (glycation) contributes to damage associated with dietary copper deficiency has depended largely on indirect evidence. Thus far, the observation of an elevated percentage of glycated hemoglobin in copper-deficient rats has provided the only direct evidence of an increase in glycation. We sought further direct evidence of increased glycation in copper deficiency. Male weanling rats were fed a copper-adequate (CuA, 6.4 mg Cu/kg diet) or copper-deficient diet (CuD, 0.4 mg Cu/kg diet) for 5 weeks. Rats fed the CuD diet were copper deficient as judged by depressed organ copper concentrations and a variety of indirect indices. Measurements of hemoglobin A(1) and serum fructosamine (both early glycation end-products) as well as serum pentosidine (an advanced glycation end-product) indicated that all three compounds were elevated in CuD rats relative to CuA rats. This finding further supports the view that glycation is enhanced and thus may contribute to defects associated with dietary copper deficiency.     

Papaverine increases human serum albumin glycation

Glycation is a non-enzymatic reaction that is initiated by the primary addition of sugars to amino groups of proteins. In the early phase of glycation, the synthesis of intermediates leads to formation of Amadori compounds. In the last phase, advanced glycation end products (AGE) are irreversibly formed following a complex cascade of reactions. It has recently been shown that glycation also affects diabetes-related complications and Alzheimer’s disease. In this study, human serum albumin at a concentration of 10 mg/ml was incubated in PBS with 40 mM of glucose and in different concentrations of papaverine (25, 100, 250, 500 μM) for 42 days at 37 °C. HSA with no additives as well as with glucose 40 mM were incubated as a control and as a glycated sample, respectively. Following the incubation, the samples were prepared for circular dichroism, fluorescence and absorbance techniques. The results showed that in presence of papaverine and glucose, the glycation of HSA increased notably compared with the glycated sample. In conclusion, in this work, we showed that papaverine affects HSA and increases its glycation level.     

An in vitro study on the role of metal catalyzed oxidation in glyeation and crosslinking of collagen

The present investigation was carried out to understand the effect of metal catalyzed oxidation on glycation and crosslinking of collagen. Tail tendons obtained from rats weighing 200-225 g were incubated with glucose (250 mM) and increasing concentrations of copper ions (5, 25, 50 and 100 M) under physiological conditions of temperature and pH. Early glycation, crosslinking and late glycation (fluorescence) of collagen samples were analyzed periodically. Early glycation was estimated by phenol sulfuric acid method, and the crosslinking was assessed by pepsin and cyanogen bromide digestion. A concentrationdependent effect of metal ions on the rate of glycation and crosslinking of collagen was observed. Tendon collagen incubated with glucose and 100 M copper ions showed 80% reduction in pepsin digestion within seven days, indicating extensive crosslinking, whereas collagen incubated with glucose alone for the same period showed only 7% reduction. The presence of metal ions in the incubation medium accelerated the development of Maillard reaction fluorescence on collagen, and the increase was dependent on the concentration of metal ions used. The metal chelator Diethylene triamine penta-acetate significantly prevented the increase in collagen crosslinking by glucose and copper ions. Free radical scavengers benzoate and mannitol effectively prevented the increased crosslinking and browning of collagen by glucose. The results indicate that the metal catalyzed oxidation reactions play a major role in the crosslinking of collagen by glucose. It is also suggested that the prevention of increased oxidative stress in diabetes may prevent the accelerated advanced glycation and crosslinking of collagen.     

Decreased interaction of fibronectin, type IV collagen, and heparin due to nonenzymatic glycation. Implications for diabetes mellitus

The nonenzymatic glycation of basement membrane proteins, such as fibronectin and type IV collagen, occurs in diabetes mellitus. These proteins are nonenzymatically glycated in vivo and can also be nonenzymatically glycated in vitro. After 12 days of incubation at 37 degrees C with 500 mM glucose, purified samples of human plasma fibronectin and native type IV collagen showed a 13.0- and 4.2-fold increase, respectively, in glycated amino acid levels in comparison to control samples incubated in the absence of glucose. Gelatin (denatured calfskin collagen) was glycated 22.3-fold under the same conditions. Scatchard analyses were performed on the binding of radiolabeled fibronectin to gelatin or type IV collagen. It was found that there is a 3-fold reduction in the affinity of fibronectin to type IV collagen due to the nonenzymatic glycation of fibronectin. The dissociation constant (KD) for the binding of control fibronectin to type IV collagen was 9.6 X 10(-7) M while the KD for glycated fibronectin and type IV collagen was 2.9 X 10(-6) M. This was similar to the 2.7-fold reduction in the affinity of fibronectin for gelatin found as a result of the nonenzymatic glycation of fibronectin (KD of 4.5 X 10(-7) M for the interaction of control fibronectin with gelatin vs. KD of 1.2 X 10(-6) M for the interaction of nonenzymatically glycated fibronectin with gelatin). The molecular association of control fibronectin or its glycated counterpart with [3H]heparin was also determined. Scatchard analyses of this interaction showed no difference between control fibronectin and glycated fibronectin in [3H]heparin binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formation of pentosidine during nonenzymatic browning of proteins by glucose. Identification of glucose and other carbohydrates as possible precursors of pentosidine in vivo

A fluorescent compound has been detected in proteins browned during Maillard reactions with glucose in vitro and shown to be identical to pentosidine, a pentose-derived fluorescent cross-link formed between arginine and lysine residues in collagen (Sell, D. R., and Monnier, V. M. (1989) J. Biol. Chem. 264, 21597-21602). Pentosidine was the major fluorophore formed during nonenzymatic browning of ribonuclease and lysozyme by glucose, but accounted for less than 1% of non-disulfide cross-links in protein dimers formed during the reaction. Pentosidine was formed in greatest yields in reactions of pentoses with lysine and arginine in model systems but was also formed from glucose, fructose, ascorbate, Amadori compounds, 3-deoxyglucosone, and other sugars. Pentosidine was not formed from peroxidized polyunsaturated fatty acids or malondialdehyde. Its formation from carbohydrates was inhibited under nitrogen or anaerobic conditions and by aminoguanidine, an inhibitor of advanced glycation and browning reactions. Pentosidine was detected in human lens proteins, where its concentration increased gradually with age, but it did not exceed trace concentrations (less than or equal to 5 mumol/mol lysine), even in the 80-year-old lens. Although its precise carbohydrate source in vivo is uncertain and it is present in only trace concentrations in tissue proteins, pentosidine appears to be a useful biomarker for assessing cumulative damage to proteins by nonenzymatic browning reactions with carbohydrates.     

In vitro glycoxidation of insoluble fibrous type I collagen: solubilization and advanced glycation end products

The deleterious effects of glycoxidation are dependent on the half-life of proteins. Collagen, the main component of extracellular matrices, is a long live protein and thus may be sensitive to the glycoxidation process. We incubated calf skin fibrous type I collagen in PBS at 37 degrees C with glucose. The fibrous type I collagen was solubilized and an increase in the amount of advanced glycation end products of the solubilized fraction was observed. As there was no bacterial contamination and no proteolytic activities in the incubation medium, the solubilization of fibrous type I collagen is probably due to the speculative production of the free radicals in our experimental conditions. To test this hypothesis, fibrous type I collagen was incubated in PBS with AAPH (2,2'azo-bis 2-aminodinopropane) a free radicals generator. AAPH induced a dramatic and dose dependent solubilization of fibrous type I collagen.     

Age-related accumulation of the advanced glycation endproduct pentosidine in human articular cartilage aggrecan: the use of pentosidine levels as a quantitative measure of protein turnover.

During aging, non-enzymatic glycation results in the formation and accumulation of the advanced glycation endproduct pentosidine in long-lived proteins, such as articular cartilage collagen. In the present study, we investigated whether pentosidine accumulation also occurs in cartilage aggrecan. Furthermore, pentosidine levels in aggrecan subfractions of different residence time were used to explore pentosidine levels as a quantitative measure of aggrecan turnover. In order to compare protein turnover rates, protein residence time was measured as racemization of aspartic acid. As has previously been shown for collagen, pentosidine levels increase with age in cartilage aggrecan. Consistent with the faster turnover of aggrecan compared to collagen, the rate of pentosidine accumulation was threefold lower in aggrecan than in collagen. In the subfractions of aggrecan, pentosidine levels increased with protein residence time. These pentosidine levels were used to estimate the half-life of the globular hyaluronan-binding domain of aggrecan to be 19.5 years. This value is in good agreement with the half-life of 23.5 years that was estimated based on aspartic acid racemization. In aggrecan from osteoarthritic (OA) cartilage, decreased pentosidine levels were found compared with normal cartilage, which reflects increased aggrecan turnover during the OA disease process. In conclusion, we showed that pentosidine accumulates with age in aggrecan and that pentosidine levels can be used as a measure of turnover of long-lived proteins, both during normal aging and during disease.     

Controversial behavior of aminoguanidine in the presence of either reducing sugars or soluble glycated bovine serum albumin

The elucidation of the controversial inhibitory effect of aminoguanidine (AG) on the cross-linking and fluorescent advanced glycation end products (AGEs) formation during long-term in vitro glycation of type I collagen with 250 mM reducing sugars or 0.5 mg/ml soluble glycated bovine serum albumin (AGE-BSA) was researched.Chromatographic and SDS–PAGE analyses revealed the formation of aggregates during collagen glycation. AG at all concentrations (5–80 mM) prevented the cross-linking of collagen peptides with monosaccharides but an increase in fluorescence with a maximum value at 10 mM AG was noticed. In the presence of AGE-BSA, AG prevented the cross-linking process and decreased the fluorescence levels in a concentration-dependent manner.Our results suggest that AG is an efficient inhibitor of collagen cross-linking and the highest increase in fluorescence due to reducing sugars and AG can be explained by the competition between guanidine group of AG and arginine residues of some protein-bound dideoxyosones, which could form fluorescent compounds.     

Determination of dideoxyosone precursors of AGEs in human lens proteins

Dideoxyosones (DDOs) are intermediates in the synthesis of advanced glycation endproducts (AGEs), such as pentosidine and glucosepane. Although the formation of pentosidine and glucosepane in the human lens has been firmly established, the formation of DDOs has not been demonstrated. The aim of this study was to develop a reliable method to detect DDOs in lens proteins. A specific DDO trapping agent, biotinyl-diaminobenzene (3,4-diamino-N-(3-[5-(2-oxohexahydro-1H-thieno[3,4-d]imidazol-4-yl)pentanoyl]aminopropyl)benzamide) (BDAB) was added during in vitro protein glycation or during protein extraction from human lenses. In vitro glycated human lens protein showed strong reaction in monomeric and polymeric crosslinked proteins by Western blot and ELISA. Glycation of BSA in the presence of BDAB resulted in covalent binding of BDAB to the protein and inhibited pentosidine formation. Mass spectrometric analysis of lysozyme glycated in the presence of BDAB showed the presence of quinoxalines at lysine residues at positions K1, K33, K96, and K116. The ELISA results indicated that cataractous lens proteins contain significantly higher levels of DDO than non-cataractous lenses (101.9±67.8 vs. 31.7±19.5AU/mg protein, p<0.0001). This study provides first direct evidence of DDO presence in human tissue proteins and establishes that AGE crosslink synthesis in the human lens occurs via DDO intermediates.