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Inhibition of advanced glycation end-product formation on eye lens protein by rutin

Published online by Cambridge University Press:  25 August 2011

P. Muthenna
Affiliation:
Biochemistry Division, National Institute of Nutrition, Jamai-Osmania, Tarnaka, Hyderabad500 604, India
C. Akileshwari
Affiliation:
Biochemistry Division, National Institute of Nutrition, Jamai-Osmania, Tarnaka, Hyderabad500 604, India
Megha Saraswat
Affiliation:
Biochemistry Division, National Institute of Nutrition, Jamai-Osmania, Tarnaka, Hyderabad500 604, India
G. Bhanuprakash Reddy*
Affiliation:
Biochemistry Division, National Institute of Nutrition, Jamai-Osmania, Tarnaka, Hyderabad500 604, India
*
*Corresponding author: Dr G. B. Reddy, fax +91 40 27019074, email [email protected]
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Abstract

Formation of advanced glycation end products (AGE) plays a key role in the several pathophysiologies associated with ageing and diabetes, such as arthritis, atherosclerosis, chronic renal insufficiency, Alzheimer's disease, nephropathy, neuropathy and cataract. This raises the possibility of inhibition of AGE formation as one of the approaches to prevent or arrest the progression of diabetic complications. Previously, we have reported that some common dietary sources such as fruits, vegetables, herbs and spices have the potential to inhibit AGE formation. Flavonoids are abundantly found in fruits, vegetables, herbs and spices, and rutin is one of the commonly found dietary flavonols. In the present study, we have demonstrated the antiglycating potential and mechanism of action of rutin using goat eye lens proteins as model proteins. Under in vitro conditions, rutin inhibited glycation as assessed by SDS-PAGE, AGE-fluorescence, boronate affinity chromatography and immunodetection of specific AGE. Further, we provided insight into the mechanism of inhibition of protein glycation that rutin not only scavenges free-radicals directly but also chelates the metal ions by forming complexes with them and thereby partly inhibiting post-Amadori formation. These findings indicate the potential of rutin to prevent and/or inhibit protein glycation and the prospects for controlling AGE-mediated diabetic pathological conditions in vivo.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Non-enzymatic glycation is a complex cascade of reactions, initiated by the condensation of reducing sugars with free amino groups of protein to form reversible Schiff's base, which undergoes rearrangement to form a relatively stable Amadori product. Amadori products, over a period of time, undergo a series of reactions involving multiple dehydration, fragmentation and oxidative modifications through highly reactive dicarbonyl intermediates to form stable, heterogeneous adducts called advanced glycation end products (AGE)(Reference Sing, Barden and Mori1Reference Monnier3). A wide variety of chemical structures of AGE such as carboxymethyllysine (CML), pentosidine, glyoxal-lysine dimer and methylglyoxal (MGO)-lysine dimer are reported(Reference Sing, Barden and Mori1Reference Monnier3). Though, inside the cell, the impact of glycation is countered by high turnover and short half-life of many cellular proteins, the major consequence of glycation is the age-dependent chemical modifications of long-lived proteins, like eye lens proteins, skin collagen and basement membrane proteins(Reference Vlassara4Reference Brownlee6).

Although AGE formation takes place during the normal ageing process, it is accelerated in hyperglycaemic conditions. An overwhelming body of evidence indicates that non-enzymatic glycation of proteins is implicated in a number of biochemical abnormalities associated with ageing and diabetes(Reference Vlassara4Reference Brownlee6). It has been shown that the formation of AGE in vivo contributes to several pathophysiologies associated with ageing and diabetes mellitus, such as arthritis, atherosclerosis, chronic renal insufficiency, Alzheimer's disease, nephropathy, neuropathy and cataract(Reference Vlassara4Reference Kumar, Reddy and Kumar9). Glycation of eye lens protein has been considered to be one of the mechanisms responsible for both age-related and diabetic cataract, which is the leading cause of blindness(Reference Lyons, Silvestri and Dunn5, Reference Luthra and Balasubramanian8, Reference Kumar, Reddy and Kumar9). It has been shown that the formation of AGE in vivo contributes to the cataract, by altering the surface charge of the protein, leading to conformational change that in turn may affect protein–protein and protein–water interactions and ultimately lead to decreased transparency of the eye lens(Reference Luthra and Balasubramanian8Reference Beswick and Harding10). The rate of AGE accumulation is related to the severity of diabetic cataract. Since considerable evidences have shown the contribution of AGE in the development of diabetic complications, inhibition of AGE is considered to be one promising approach for the prevention and treatment of diabetic complications. A wide variety of agents like pyridoxamine, carnosine, OPB-9195 (2-isopropylidenehydrazono-4-oxo-thiazolidin-5-ylacetanilide), phenyl thiazolium bromides, aspirin and lipoic acid have been investigated in several in vitro and in vivo studies for their potential against various pathologies including cataract(Reference Sing, Barden and Mori1, Reference Stitt, Gardiner and Alderson11Reference Edelstein and Brownlee14). However, except pyridoxamine, none have passed all the stages of clinical trials. While the extensively investigated hydrazine compound, aminoguanidine, has shown promising results in vitro and in animal models in terms of inhibition of AGE-formation and entered into phase 3 clinical trials(Reference Edelstein and Brownlee14Reference Taguchi, Sugiura and Hamada16), the trial was terminated due to various safety concerns(Reference Freedman, Wuerth and Cartwright15). It is known that glycation and AGE-induced toxicity are associated with increased free-radical activity. Recent studies have demonstrated the benefits of using compounds with combined antiglycation and antioxidant properties(Reference Ahmad and Ahmed17, Reference Grover, Yadav and Vats18). Such compounds not only prevent AGE formation, but also reduce free-radical-mediated toxicity. Hence, efforts are being made in identifying the natural sources of antiglycating agents that can be tested for their therapeutic value against AGE-mediated pathologies.

In the course of identifying and testing new antiglycating agents, we have evaluated a number of traditional and very common dietary sources and found that some spice principles, fruits and vegetables have the potential to inhibit AGE formation under in vitro conditions(Reference Saraswat, Reddy and Muthenna19, Reference Mrudula, Suryanarayana and Srinivas20) and in animal models(Reference Kumar, Reddy and Srinivas21, Reference Saraswat, Suryanarayana and Reddy22, Reference Kusirisin, Srichairatanakool and Lerttrakarnnon23). Flavonoids are abundantly found in fruits, vegetables, herbs and spices, and some of the flavonoids have been tested for their antiglycating activity(Reference Ahmad and Ahmed17, Reference Saraswat, Suryanarayana and Reddy22Reference Nakagawa, Yokozawa and Terasawa24). Rutin is one of the commonly found dietary flavonols. Although the antiglycating activity of rutin and its metabolites has been reported(Reference Nagasawa, Tabata and Ito25, Reference Pashikanti, de Alba and Boissonneault26), its potential against non-enzymatic glycation of eye lens protein has not been tested. Therefore, in the present study, we investigated the effect of rutin against glycation-induced alterations of the lens protein. We employed a set of complementary methods; spectroscopic, electrophoretic, chromatographic and immunochemical, to evaluate the antiglycating potential of rutin as well as its mechanism of action.

Materials and methods

Materials

Fructose, bovine serum albumin (BSA), Chelex-100, sorbitol, rutin, ascorbic acid, d-ribose, keyhole limpet haemocyanin (KLH), ribonuclease (RNase), MGO, Freund's complete and incomplete adjuvant, m-aminophenylboronic acid and horseradish peroxidase-conjugated goat anti-rabbit antibody were obtained from Sigma-Aldrich (St Louis, MO, USA). Glyoxylic acid and sodium cyanoborohydride were purchased from ICN Biochemicals (Aurora, OH, USA). All other chemicals and solvents used were of analytical grade.

Preparation of advanced glycation end products antigens

AGE-RNase was prepared as described previously(Reference Beswick and Harding10, Reference Saraswat, Reddy and Muthenna19, Reference Kumar, Reddy and Srinivas21). Briefly, RNase (25 mg/ml) was incubated with 1 m-glucose in 0·2 m-phosphate buffer (pH 7·4) containing 0·05 % sodium azide at 37°C for 90 d. KLH (50 mg/ml) was incubated with 0·045 m-glyoxylic acid and 0·15 m-sodium cyanoborohydride in 0·2 m-sodium phosphate buffer (pH 7·8) for 24 h at 37°C for the preparation of CML-KLH. For MGO-BSA, BSA (50 mg/ml) was incubated with 0·5 m-MGO in 100 mm-sodium phosphate buffer (pH 7·5) at 37°C in the dark for 3 d. Low molecular weight reactants and unbound sugars were removed by extensive dialysis.

Production of polyclonal anti-advanced glycation end products antibodies

Antibodies were produced against AGE-RNase, CML-KLH and MGO-BSA by immunising 3-month-old female New Zealand white rabbits as described previously(Reference Beswick and Harding10, Reference Mrudula, Suryanarayana and Srinivas20, Reference Kumar, Reddy and Srinivas21). Rabbits were immunised by subcutaneous administration of a 1 ml solution containing 1 mg/ml AGE-protein antigen in Freund's complete adjuvant at multiple sites on the back of the rabbits and subsequently three boosters were given at 3-week intervals in Freund's incomplete adjuvant. For testing the titres, the rabbits were bled intermittently from the ear vein and the titre was checked by dot-blot analysis. The rabbits were bled after the last booster, and the serum was collected by centrifugation. Antiserum was partially purified by ammonium sulphate fractionation followed by diethylaminoethyl-sepharose anion exchange chromatography to obtain an IgG-rich fraction.

Animal care

Institutional and national guidelines for the care and use of animals were followed and all experimental procedures involving animals were approved by the Institutional Animal Ethical Committee of National Institute of Nutrition. We adhered to the Association for Research in Vision and Ophthalmology Statement for the Use of Animals in Ophthalmic and Vision Research.

In vitro glycation of proteins

Eye lens soluble proteins were obtained from 6-month-old goat lenses as described previously(Reference Kumar, Kumar and Reddy27). A 10 % homogenate of goat lenses was prepared in phosphate buffer saline, pH 7·4 and centrifuged at 10 000 g for 30 min at 4°C. The supernatant (total lens soluble protein referred to as total soluble protein (TSP), henceforth) was used for in vitro glycation. Each 1 ml reaction mixture contained 10 mg of TSP, 0·2 m-phosphate buffer, pH 7·4, 0·1 m-fructose, 50 μg of penicillin and streptomycin and 0·01 % sodium azide. Reaction tubes were incubated in the dark at 37°C for 3 weeks. At the end of the incubation, unbound sugars were removed by dialysis against the same buffer. Protein concentration was determined by the Lowry method using BSA as standard. Stock solutions of all the reaction contents were filtered through 0·20 μm syringe filters. The rationale behind using the lens proteins as a model protein was their longevity and their susceptibility to extensive accumulation of AGE, which is accelerated in diabetes-associated pathologies(Reference Beswick and Harding10, Reference Kumar, Reddy and Srinivas21, Reference Kumar, Kumar and Reddy27).

Inhibition studies with rutin and aminoguanidine

For inhibition studies, concentrated stocks of rutin were prepared in dimethyl sulphoxide. Various concentrations of rutin (10–1000 μm) and aminoguanidine (10 and 100 mm) were added to in vitro protein glycation assay mixture and incubated in the dark at 37°C for 3 weeks as described earlier. At the end of the incubation, unbound reactants were removed by dialysis and protein concentration was determined as described previously. The extent of protein glycation in the absence and presence of rutin and aminoguanidine was evaluated by monitoring protein cross-linking on SDS-PAGE, AGE-related non-tryptophan fluorescence, protein carbonyl content, phenyl boronate affinity chromatography and immunodetection methods as described next. The percentage of inhibition with rutin and aminoguanidine was calculated considering the extent of glycation in their absence as 100 %.

Fluorescence measurements

Non-tryptophan AGE fluorescence was monitored using 0·15 mg/ml protein in 20 mm-sodium phosphate buffer, pH 7·4, by exciting at 370 nm and recording the emission between 400 and 500 nm using a spectrofluorometer (Jasco FP-6500; JASCO Analytical Instruments, Tokyo, Japan).

SDS-PAGE

Formation of high molecular weight (HMW) aggregates and protein cross-links in TSP as a result of protein glycation was monitored by SDS-PAGE under reducing conditions using 12 % gels.

Glyco-oxidative damage

The effect of rutin and aminoguanidine on non-enzymatic glycation-mediated glyco-oxidative damage of TSP was monitored by estimating total protein carbonyls according to the method of Uchida et al. (Reference Uchida, Kanematsu and Sakai28).

Immunodetection of advanced glycation end products

Formation of specific AGE was detected by immunoblotting using anti-MGO-BSA, anti-CML-KLH and anti-AGE-RNase antibodies. Glycated proteins were resolved on a 12 % SDS-PAGE and transferred onto nitrocellulose membrane. The membrane was incubated for 2 h in blocking buffer containing 5 % skimmed milk powder. Subsequently, it was incubated with the respective primary antibodies (CML-KLH, 1:2000, MGO-BSA, 1:2000 and AGE-RNase, 1:1000) separately. The membrane was then incubated with horseradish peroxidase-conjugated goat anti-rabbit antibody (1:5000) and detection was performed using the substrate buffer containing diaminobenzidine and H2O2.

Affinity chromatography

The extent of glycation of TSP in the absence and presence of rutin was performed using phenyl boronate affinity chromatography(Reference Kumar, Reddy and Srinivas21, Reference Kumar, Kumar and Reddy27). In the present study, 10 mg of glycated TSP was passed through phenyl boronate affinity column (8 × 1 cm) equilibrated with 0·25 m-ammonium acetate buffer, pH 8·5, containing 0·05 m-MgCl2. The unbound fraction containing non-glycated protein was washed with the earlier-mentioned buffer, while the bound glycated protein was eluted using 0·1 m-Tris-Cl, pH 7·5, and containing 0·2 m-sorbitol.

Metal chelation

Metal-chelating activity was assessed by determining the metal-induced oxidation of ascorbic acid to dihydroascorbic acid using the HPLC method as described previously(Reference Price, Rhett and Thorpe29). Copper chloride (1 μm) was preincubated with and without rutin in Chelex-100 treated Milli-Q element free water for 5 min, and then the ascorbate (0·01 mg/ml) was added to the reaction mixture and transferred to auto-injector vials to initiate the metal-catalysed oxidation reaction. Metal-catalysed oxidation of ascorbic acid was analysed using an RP-C18 column (3·9 × 300 mm) on a Shimadzu HPLC-(10AT VP) equipped with an SIL-10AD VP auto-injector and an SPD-10AV VP UV/Vis detector. The mobile phase was 70 % methanol and detection was at 265 nm. The peak area was integrated to estimate the percentage of ascorbic acid unoxidised with time in the absence and presence of rutin.

Spectral absorbance shift

The shift in the absorbance spectrum of rutin due to complex formation with CuCl2 was recorded(Reference Brown, Khodr and Hider30). The absorbance of rutin in the absence and presence of 100 μm-CuCl2 in Chelex-100 treated 50 mm-sodium phosphate buffer (pH 7·4), was scanned from 200 to 700 nm in spectrophotometer (Spectramax-384; Molecular Devices, Sunnyvale, CA, USA).

Post-Amadori inhibition

BSA (10 mg/ml) was incubated with ribose (0·4 m) at 37°C in 0·4 m phosphate buffer, pH 7·4, for 24 h. Glycation was then interrupted to remove excess ribose and also the reversible Schiff base by extensive dialysis against 20 mm-sodium phosphate buffer at 4°C. The glycated BSA intermediate containing maximal amount of Amadori product was then incubated at 37°C in the absence or presence of rutin, aminoguanidine and a combination of both for 5 d. This initiated conversion of Amadori intermediates to AGE products and the extent of conversion of Amadori to AGE(Reference Booth, Khalifah and Todd31) were measured by non-tryptophan AGE fluorescence as described previously.

Statistical analysis

Results were expressed as means with their standard errors. Data were analysed using SPSS version 15.0 software (SPSS Inc., Chicago, IL, USA). Mean values were compared by one-way ANOVA with post hoc tests of least significant difference method. Heterogeneity of variance was tested by non-parametric Mann–Whitney test. Differences between comparisons of groups were considered to be significant at P < 0·05.

Results

The antiglycation effect of rutin was evaluated by incubating it with TSP of goat lens and fructose for 21 d. AGE-related non-tryptophan fluorescence, which represents cumulative AGE fluorescence in a non-specific manner, was monitored to assess the effect of rutin (Fig. 1). Rutin inhibited AGE-related fluorescence in a dose-dependent manner with 90 % of reduction in AGE-fluorescence at 200 μm as opposed to aminoguanidine, which reduced 60 % AGE-fluorescence at 100 mm concentration (Fig. 1). Despite their heterogeneity, the propensity to form covalent cross-links is the common consequence of AGE which leads to the formation of HMW aggregates on proteins and ultimately lens opacification. Hence, the effect of rutin on the formation of AGE-mediated protein cross-links and HMW aggregates was investigated. Incubation of lens protein with fructose led to the appearance of non-disulphide dimers with a molecular weight of approximately 45 kDa and a large amount of HMW aggregates above 200 kDa that did not enter the stacking gel was observed on the SDS-PAGE (Fig. 2), similar to the modifications observed in the soluble portion of the lens protein from streptozotocin-induced diabetic cataract(Reference Suryanarayana, Saraswat and Mrudula32). While rutin at 100 μm was found to reduce the formation of both cross-link and HMW aggregates (Fig. 2), 100 mm-aminoguanidine was required for comparable results (data not shown).

Fig. 1 Inhibition of advanced glycation end products (AGE) formation by rutin. (a) Representative non-tryptophan AGE-related fluorescence of total soluble protein upon in vitro glycation in the absence and presence of rutin. Trace 1, protein alone (P); trace 2, P+100 mm fructose (F); trace 3, P+F+10 μm-rutin; trace 4, P+F+50 μm-rutin; trace 5, P+F+100 μm-rutin; trace 6, P+F+200 μm-rutin; trace 7, P+200 μm-rutin. (b) Fold change in non-tryptophan AGE fluorescence was calculated considering the emission intensity (at 440 nm) of P as one fold. Bars 1–7 of (b) correspond to traces 1–7 of (a) and bars 8 and 9 correspond to P+F+10 mm and 100 mm aminoguanidine, respectively. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Fig. 2 Inhibition of advanced glycation end products-mediated protein cross-links by rutin. (a) Representative SDS-PAGE profile of total soluble protein upon in vitro glycation in the absence and presence of rutin. Lane 1, molecular weight markers; lane 2, protein alone (P); lane 3, P+100 mm-fructose (F); lane 4, P+F+10 μm-rutin; lane 5, P+F+50 μm-rutin; lane 6, P+F+100 μm-rutin. (b) Densitometry analysis of cross-linked and aggregated proteins. Intensity of protein bands above 31 kDa was quantified considering the intensity of lane 2 (a) as 100 %. Bars 1–5 of (b) correspond to lanes 2–6 of (a). Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

A wide variety of structurally diverse sugar-derived AGE have been demonstrated, such as pentosidine, argypyrimidine, carboxyethyllysine and CML(Reference Padayatti, Ng and Uchida33Reference Ahmed, Brinkmann-Frye and Degenhardt36). Having shown the effective reduction of fructose-induced modification over the lens protein by rutin, next we evaluated the immunoreactivity of MGO-, CML- and glucose-derived AGE using antibodies raised against MGO-BSA, CML-KLH and AGE-RNase. Immunodetection with anti-AGE antibodies demonstrated the presence of diverse antigenic determinants over the protein (Fig. 3(a)). Anti-MGO-BSA detected cross-linked species of 45 and 26 kDa along with HMW aggregates >118 kDa. Anti-CML-KLH detected the HMW aggregates >118 kDa along with intermediate species of 45 and 26 kDa and anti-AGE-RNase detected the intermediate cross-linked species of 85 kDa. Densitometry analysis (Fig. 3(b)) indicates that CML- and MGO-derived AGE were prominent than glucose-derived AGE. Rutin showed a dose–response inhibition against all AGE. Densitometry analysis showed that rutin at 50 μm could reduce CML-derived AGE by approximately 90 %, glucose-derived AGE by 60 and 90 % reduction for the MGO-derived modification, respectively. Furthermore, boronate affinity chromatography shows that rutin could reduce the fraction of glycated protein in a dose-dependent manner (Fig. 4). Since boronate affinity allows the direct separation of glycated protein from the nonglycated one, these results corroborate the antiglycating potential of the rutin.

Fig. 3 Immunodetection of advanced glycation end products (AGE) in soluble lens protein. (a) Representative Western blot profile of total soluble protein upon in vitro glycation in the absence and presence of rutin. Blots were probed with anti-methylglyoxal-bovine serum albumin (top), anti-carboxy methyl lysine-keyhole limpet haemocyanin (middle) and anti-AGE-ribonuclease antibodies (bottom). Lane 1, molecular weight markers; lane 2, protein alone (P); lane 3, P+100 mm-fructose (F); lane 4, P+F+10 μm-rutin; lane 5, P+F+50 μm-rutin and lane 6, P+F+100 μm-rutin. (b) Densitometry analysis of AGE. Intensity of AGE signals was quantified considering the intensity of lane 2 (a) as 100 %. Bars 1–5 in (b) correspond to lanes 2–6 of (a). Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Fig. 4 The effect of rutin on the amount of glycated protein in total soluble protein upon in vitro glycation as analysed by phenyl boronate affinity chromatography. Trace 1, protein alone (P); trace 2, P+100 mm-fructose (F); trace 3, P+F+10 μm-rutin; trace 4, P+F+50 μm-rutin; trace 5, P+F+100 μm-rutin. OD, optical density.

The reactive intermediates of the Maillard reaction, MGO and glyoxal, which can originate from all the stages of glycation (degradation of Schiff's base, auto-oxidation of sugar and from Amadori product), are a major source for AGE formation(Reference Nagaraj, Shipanova and Faust35Reference Glomb and Monnier37). Trapping the reactive carbonyl compounds may be a valuable strategy for inhibiting or delaying the progressive glycation reactions. Hence, total protein carbonyls were estimated in the absence and presence of rutin. Increased carbonyl content (four-fold) of lens proteins upon fructose modification is an indication of glyco-oxidative damage (Fig. 5). While rutin was effective in lowering the carbonyl content in a dose-dependent manner, aminoguanidine – a known carbonyl scavenger – could not reduce glycation-induced carbonyl content in lens proteins on par with rutin even at 100 mm (Fig. 5). Metal-catalysed auto-oxidation of sugars or ascorbate is known to contribute to AGE formation(Reference Saxena, Saxena and Cui38, Reference Sajithlal, Chithra and Chandrakasan39). Therefore, potent chelating activity of the compounds might increase the antiglycating action of AGE inhibition. For example, nucleophilic compounds, which are designed to trap reactive carbonyl or dicarbonyl intermediates as AGE inhibitors, have also been shown to have chelating activity(Reference Price, Rhett and Thorpe29, Reference Brown, Khodr and Hider30). We have also demonstrated the metal chelating activity of rutin by quantifying CuCl2-catalysed ascorbic acid oxidation. Reduction of CuCl2-catalysed oxidation of ascorbic acid by rutin in a dose-dependent manner (Fig. 6) indicates that inhibition of AGE by rutin could be due to its metal chelation ability. Further, a shift in the absorbance spectrum of rutin in the presence of CuCl2 confirms the formation of rutin–metal complex (Fig. 7) and supports the finding that rutin may have metal chelation property. Finally, we have also assessed the potential of rutin to inhibit post-Amadori reaction as Amadori product after several rearrangement leads to the formation of stable and heterogeneous AGE. Rutin partly (30 %) inhibited the post-Amadori compound formation at 100 μM concentration, which is comparable to that of aminoguanidine at 10 mm (Fig. 8(a)). However, the effect of a combination of both rutin (100 and 200 μM) and aminoguanidine (10 mm) was not significantly different when compared with their individual potential alone (Fig. 8(b)).

Fig. 5 Protein carbonyl content of total soluble protein upon in vitro glycation in the absence and presence of rutin. Bar 1, protein alone (P); bar 2, P+100 mm-fructose (F); bar 3, P+F+10 μm-rutin; bar 4, P+F+50 μm-rutin; bar 5, P+F+100 μm-rutin; bar 6, P+F+10 mm-aminoguanidine; bar 7, P+F+100 mm-aminoguanidine. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Fig. 6 Chelation of metals by rutin. Percentage ascorbic acid unoxidised due to metal catalysed reaction in the absence and presence of rutin. Bar 1, ascorbic acid (AA)+CuCl2; bar 2, AA+CuCl2+50 μm-rutin; bar 3, AA+CuCl2+100 μm-rutin; bar 4, AA+CuCl2+500 μm-rutin; bar 5, AA+CuCl2+1000 μm-rutin. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 1 (P < 0·05).

Fig. 7 Spectral shift of rutin in the presence of CuCl2. Absorption spectrum of 50 μm-rutin in the absence (trace 2) and presence of 1 μm-CuCl2 (trace 3), absorption spectrum of 100 μm-rutin in the absence (trace 4) and presence of 1 μm-CuCl2 (trace 5). Absorption spectrum of 1 μm-CuCl2 alone is also recorded (trace 1).

Fig. 8 Inhibition of post-Amadori product formation by rutin and aminoguanidine. Non-tryptophan advanced glycation end products fluorescence of bovine serum albumin (BSA) upon incubation with 0·4 m-ribose (R) in the absence and presence of rutin or aminoguanidine or both was recorded at 440 nm upon excitation at 370 nm. (a) Bars 1–5 correspond to BSA alone, BSA+R, BSA+R+50 μm-rutin, BSA+R+100 μm-rutin and BSA+R+200 μm-rutin, respectively. (b) Bars 1–6 correspond to BSA alone, BSA+R, BSA+R+100 μm-rutin, BSA+R+100 mm-aminoguanidine, BSA+R+100 μm-rutin+10 mm-aminoguanidine and BSA+R+100 μm-rutin+100 mm-aminoguanidine, respectively. Values are means, with their standard errors represented by vertical bars, n 3. * Mean values were significantly different from bar 2 (P < 0·05).

Discussion

Numerous studies indicate that the world, in particular South-East Asia, is facing a growing diabetes epidemic, making it a major threat to public health(Reference Mohan, Sandeep and Deepa40, Reference Wild, Roglic and Green41). Prolonged diabetes can lead to various short-term and long-term secondary complications, which represent the main cause of morbidity and mortality in diabetic patients. Hence, the long-term complications of diabetes, such as blindness due to cataract and retinopathy, remain serious problems to be dealt with. Hence, agents which can prevent diabetic complications have been studied for the management of secondary complications. Previously, we have identified some natural sources that include fruits, vegetables and spices for their potential to inhibit protein glycation and AGE formation, with the ultimate goal to prevent or treat diabetic complications(Reference Saraswat, Reddy and Muthenna19Reference Saraswat, Suryanarayana and Reddy22). Rutin is one of the commonly found flavonoids in these dietary sources. In the present study, we demonstrated the antiglycating effect of rutin and its mechanism of action using total soluble eye lens protein complement as a model protein system so as to translate these in vitro effects to an in vivo system in experimental models of diabetic complications.

A study examined the antioxidant activity of rutin and related it to its efficacy to inhibit glycation in some tissue protein extracts; and suggested that rutin and the rutin analogues exhibited significant antioxidant activity which corresponds to the ability to suppress the formation of the Maillard reaction intermediates in tissue protein sources(Reference Nakagawa, Yokozawa and Terasawa24). Previously, it was also shown that dietary G-rutin suppresses the accumulation of glycation products in serum and kidney proteins as well as the oxidative modification of lipids and proteins in streptozotocin-induced diabetic rats(Reference Nagasawa, Tabata and Ito42). However, the duration of diabetes (1  month) was too short for both – to study the extent of glycation and to evaluate the effect of rutin. Using a non-oxidative model of protein glycation, with histone H1, and glyoxal, MGO or ADP-ribose as the reducing sugar, a previous study tested the rutin metabolites as AGE inhibitors under non-oxidative conditions(Reference Pashikanti, de Alba and Boissonneault26). In the present study, we used glucose (fructose)-based protein glycation system because glucose-mediated protein glycation may occur under oxidative and non-oxidative conditions to form AGE protein adducts; and our results suggest that rutin could be effective under both oxidative and non-oxidative conditions. Rutin is metabolised by the gut microflora to a range of phenolic compounds such as quercetin and phenol derivatives such as 3,4-dihydroxyphenylacetic acid, 3,4-dihydroxytoluene, 3-hydroxyphenylacetic acid and 4-hydroxy-3-methoxyphenylacetic acid (homovanillicacid)(Reference Pashikanti, de Alba and Boissonneault26, Reference Cervantes-Laurean, Schramm and Jacobson43, Reference Griffiths and Barrow44). While a study showed that rutin and its circulating metabolites inhibit early glycation product formation induced by glucose glycation of collagen in vitro (Reference Cervantes-Laurean, Schramm and Jacobson43), the results of the present study indicate that rutin can inhibit both early and late glycation product formation.

Unlike the previous studies which focused on a specific aspect of AGE inhibition, in the present study we used a battery of methods to describe the antiglycating and AGE inhibitory potential of rutin. Particularly, the use of affinity chromatography (to quantify glycated proteins), immunodetection of specific but predominant AGE-antigens and post-Amadori inhibition systems helped us to provide information on the antiglycating property of rutin. However, it would be interesting to study the effect of rutin on late glycation product formation using glucose-mediated protein glycation; and efforts in this connection are already underway.

Rutin is a flavonol glycoside composed of quercetin and the disaccharide rutinose, i.e. quercetin-3-rutinoside. Structure–activity relationship study suggests the importance of vicinyl dihydroxyl groups in the B-ring of flavonoid for showing the property of AGE inhibition which correlates with the free-radical scavenging activity of flavonoids(Reference Matsuda, Wang and Managi45). Probably, the presence of vicinyl dihydroxyl group in rutin contributes to its antiglycating activity. Being a free-radical scavenger, it may prevent the formation of dicarbonyls, the major source for AGE. In addition, the accumulation of intracellular sorbitol due to increased aldose reductase (ALR2 or AKR1B1) activity has been implicated in the development of various secondary complications of diabetes. Therefore, the inhibition of ALR2 is also one of the approaches to prevent or arrest the progression of diabetic complications. We have found that rutin also has the potential to inhibit ALR2 and suppress the formation of sorbitol, which has been shown as reported (G. B. R., unpublished results). Thus, these multiple properties of rutin support its utility for controlling AGE- and ALR2-mediated diabetic pathological conditions in vivo.

Although the beneficial impact of strict glycaemic control on the prevention of diabetic complications has been well established, most individuals with diabetes rarely achieve consistent euglycaemia. Hence, agents that can substantially delay or prevent the onset and development of diabetic complications, irrespective of glycaemic control, would offer many advantages. In principle, antiglycating agents and ALR2 inhibitors can be included in this category. Thus, intensive research continues to identify and test both synthetic as well as natural products for their therapeutic value to prevent the onset and/or delay the progression of diabetic complications. Studies are underway to investigate the potential of rutin against streptozotocin-induced diabetic cataract and other diabetic complications.

Acknowledgements

The authors thank Dr. N. Balakrishna (National Institute of Nutrition) for his help in statistical analysis of the data. P. M., C. A. and M. S. were involved in data collection, data analysis, data interpretation, literature search and manuscript preparation. G. B. R. was involved in the study design, data analysis, data interpretation, literature search, manuscript preparation and review of the manuscript. P. M. received a research fellowship from University Grants Commission, Government of India; M. S. received a research fellowship from Indian Council of Medical Research, Government of India; G. B. R. received grants from the Department of Biotechnology under 7th FP of Indo-EU collaborative grant on functional foods (Grant agreement no. 245030) and Life Sciences Research Board of Defence Research and Development Organization, Government of India. The authors declare that they have no conflicts of interest.

References

1 Sing, R, Barden, A, Mori, T, et al. (2001) Advanced glycation end products: a review. Diabetologia 44, 129146.Google Scholar
2 Baynes, JW, Watkins, NG, Fisher, CI, et al. (1989) The Amadori product on protein: structure and reactions. Prog Clin Biol Res 304, 4367.Google Scholar
3 Monnier, VM (1989) Structure elucidation of a senescence cross-link from human extracellular matrix. Implication of pentoses in the aging process. J Biol Chem 264, 2159721602.Google Scholar
4 Vlassara, H (1996) Advanced glycation end products and atherosclerosis. Ann Med 28, 419426.Google Scholar
5 Lyons, TJ, Silvestri, G, Dunn, JA, et al. (1991) Role of glycation in modification of lens crystallins in diabetic and nondiabetic senile cataracts. Diabetes 40, 10101015.Google Scholar
6 Brownlee, M (1995) Advanced protein glycosylation in diabetes and aging. Annu Rev Med 46, 223234.Google Scholar
7 Shuvaev, VV, Laffont, I, Serot, JM, et al. (2001) Increased protein glycation in cerebrospinal fluid of Alzheimer's disease. Neurobiol Aging 22, 397402.Google Scholar
8 Luthra, M & Balasubramanian, D (1993) Nonenzymatic glycation alters protein structure and stability. A study of two eye lens crystallins. J Biol Chem 268, 1811918227.Google Scholar
9 Kumar, MS, Reddy, PY, Kumar, PA, et al. (2004) Effect of dicarbonyl-induced browning on α-crystallin chaperone-like activity: physiological significance and caveats of in vitro aggregation assays. Biochem J 379, 273282.Google Scholar
10 Beswick, HT & Harding, JJ (1987) Conformational changes induced in lens α- and γ-crystallins by modification with glucose 6-phosphate. Implications for cataract. Biochem J 246, 761769.Google Scholar
11 Stitt, A, Gardiner, TA, Alderson, NL, et al. (2002) The AGE inhibitor pyridoxamine inhibits development of retinopathy in experimental diabetes. Diabetes 51, 28262832.Google Scholar
12 Wada, R, Nishizawa, Y, Yagihashi, N, et al. (2001) Effects of OPB-9195, anti-glycation agent, on experimental diabetic neuropathy. Eur J Clin Invest 31, 513520.Google Scholar
13 Vasan, S, Zhang, X, Zhang, X, et al. (1996) An agent cleaving glucose-derived protein crosslinks in vitro and in vivo. Nature 382, 275278.Google Scholar
14 Edelstein, D & Brownlee, M (1992) Mechanistic studies of advanced glycosylation end product inhibition by aminoguanidine. Diabetes 41, 2629.Google Scholar
15 Freedman, BI, Wuerth, JP, Cartwright, K, et al. (1999) Design and baseline characteristics for the aminoguanidine Clinical Trial in Overt Type 2 Diabetic Nephropathy (ACTION II). Control Clin Trials 20, 493510.Google Scholar
16 Taguchi, T, Sugiura, M, Hamada, Y, et al. (1998) In vivo formation of a Schiff base of aminoguanidine with pyridoxal phosphate. Biochem Pharmacol 55, 16671671.CrossRefGoogle ScholarPubMed
17 Ahmad, MS & Ahmed, N (2006) Antiglycation properties of aged garlic extract: possible role in prevention of diabetic complications. J Nutr 136, 796S799S.Google Scholar
18 Grover, JK, Yadav, S & Vats, V (2002) Medicinal plants of India with antidiabetic potentials. J Ethnopharmacol 81, 81100.CrossRefGoogle Scholar
19 Saraswat, M, Reddy, PY, Muthenna, P, et al. (2009) Prevention of non-enzymic glycation of proteins by dietary agents: prospects for alleviating diabetic complications. Br J Nutr 101, 17141721.Google Scholar
20 Mrudula, T, Suryanarayana, P, Srinivas, PN, et al. (2007) Effect of curcumin on hyperglycemia-induced vascular endothelial growth factor expression in streptozotocin-induced diabetic rat retina. Biochem Biophys Res Commun 361, 528532.Google Scholar
21 Kumar, PA, Reddy, PY, Srinivas, PN, et al. (2009) Delay of diabetic cataract in rats by the antiglycating potential of cumin through modulation of α-crystallin chaperone activity. J Nutr Biochem 20, 553562.CrossRefGoogle ScholarPubMed
22 Saraswat, M, Suryanarayana, P, Reddy, PY, et al. (2010) Antiglycating potential of Zingiber officinalis and delay of diabetic cataract in rats. Mol Vis 16, 15251537.Google Scholar
23 Kusirisin, W, Srichairatanakool, S, Lerttrakarnnon, P, et al. (2009) Antioxidative activity, polyphenolic content and anti-glycation effect of some Thai medicinal plants traditionally used in diabetic patients. Med Chem 5, 139147.Google Scholar
24 Nakagawa, T, Yokozawa, T, Terasawa, K, et al. (2002) Protective activity of green tea against free radical- and glucose-mediated protein damage. J Agric Food Chem 50, 24182422.Google Scholar
25 Nagasawa, T, Tabata, N, Ito, Y, et al. (2003) Dietary G rutin suppresses glycation in tissue proteins of streptozotocin induced diabetic rats. Mol Cell Biochem 252, 141147.Google Scholar
26 Pashikanti, S, de Alba, DR, Boissonneault, GA, et al. (2010) Rutin metabolites: novel inhibitors of nonoxidative advanced glycation end products. Free Radic Biol Med 48, 656663.Google Scholar
27 Kumar, PA, Kumar, MS, Reddy, GB, et al. (2007) Effect of glycation on alpha-crystallin structure and chaperone-like function. Biochem J 408, 251258.Google Scholar
28 Uchida, K, Kanematsu, M, Sakai, K, et al. (1998) Protein-bound acrolein: potential markers for oxidative stress. Proc Natl Acad Sci U S A 95, 48824887.Google Scholar
29 Price, DL, Rhett, PM, Thorpe, SR, et al. (2001) Chelating activity of advanced glycation end-product inhibitors. J Biol Chem 276, 4896748972.Google Scholar
30 Brown, JE, Khodr, H, Hider, RC, et al. (1998) Structural dependence of flavonoid interactions with Cu2+ ions: implications for their antioxidant properties. Biochem J 330, 11731178.Google Scholar
31 Booth, AA, Khalifah, RG, Todd, P, et al. (1997) In vitro kinetic studies of formation of antigenic advanced glycation end products (AGEs): novel inhibition of post-Amadori glycation pathways. J Biol Chem 28, 54305437.Google Scholar
32 Suryanarayana, P, Saraswat, M, Mrudula, T, et al. (2005) Curcumin and turmeric delay streptozotocin-induced diabetic cataract in rats. Invest Ophthalmol Vis Sci 46, 20922099.CrossRefGoogle ScholarPubMed
33 Padayatti, PS, Ng, AS, Uchida, K, et al. (2001) Argpyrimidine, a blue fluorophore in human lens proteins: high levels in brunescent cataractous lenses. Invest Ophthalmol Vis Sci 42, 12991304.Google Scholar
34 Ikeda, K, Higashi, T, Sano, H, et al. (1996) ɛ-(Carboxymethyl) lysine protein adduct is a major immunological epitope in proteins modified with advanced glycation end products of the Maillard reaction. Biochemistry 35, 80758083.Google Scholar
35 Nagaraj, RH, Shipanova, IN & Faust, FM (1996) Protein cross-linking by the Maillard reaction. Isolation, characterization, and in vivo detection of a lysine–lysine cross-link derived from methylglyoxal. J Biol Chem 271, 1933819345.Google Scholar
36 Ahmed, MU, Brinkmann-Frye, E, Degenhardt, TP, et al. (1997) N-epsilon-(carboxyethyl)lysine, a product of the chemical modification of proteins by methylglyoxal, increases with age in human lens proteins. Biochem J 324, 565570.Google Scholar
37 Glomb, MA & Monnier, VM (1995) Mechanism of protein modification by glyoxal and glycolaldehyde, reactive intermediates of the Maillard reaction. J Biol Chem 270, 1001710026.Google Scholar
38 Saxena, P, Saxena, AK, Cui, XL, et al. (2000) Transition metal-catalyzed oxidation of ascorbate in human cataract extracts: possible role of advanced glycation end products. Invest Ophthalmol Vis Sci 41, 14731481.Google Scholar
39 Sajithlal, GB, Chithra, P & Chandrakasan, G (1998) The role of metal-catalyzed oxidation in the formation of advanced glycation end products: an in vitro study on collagen. Free Radic Biol Med 25, 265269.Google Scholar
40 Mohan, V, Sandeep, S, Deepa, RB, et al. (2007) Epidemiology of type 2 diabetes: Indian scenario. Indian J Med Res 125, 217230.Google ScholarPubMed
41 Wild, S, Roglic, G, Green, A, et al. (2004) Global prevalence of diabetes: estimates for the year 2000 and projections for 2030. Diabetes Care 27, 10471053.Google Scholar
42 Nagasawa, T, Tabata, N, Ito, Y, et al. (2003) Inhibition of glycation reaction in tissue protein incubations by water soluble rutin derivative. Mol Cell Biochem 249, 310.Google Scholar
43 Cervantes-Laurean, D, Schramm, DD, Jacobson, EL, et al. (2006) Inhibition of advanced glycation end product formation on collagen by rutin and its metabolites. J Nutr Biochem 17, 531540.Google Scholar
44 Griffiths, LA & Barrow, A (1972) Metabolism of flavonoid compounds in germ-free rats. Biochem J 130, 11611162.Google Scholar
45 Matsuda, H, Wang, T, Managi, H, et al. (2003) Structural requirements of flavonoids for inhibition of protein glycation and radical scavenging activities. Bioorg Med Chem 11, 53175323.Google Scholar
Figure 0

Fig. 1 Inhibition of advanced glycation end products (AGE) formation by rutin. (a) Representative non-tryptophan AGE-related fluorescence of total soluble protein upon in vitro glycation in the absence and presence of rutin. Trace 1, protein alone (P); trace 2, P+100 mm fructose (F); trace 3, P+F+10 μm-rutin; trace 4, P+F+50 μm-rutin; trace 5, P+F+100 μm-rutin; trace 6, P+F+200 μm-rutin; trace 7, P+200 μm-rutin. (b) Fold change in non-tryptophan AGE fluorescence was calculated considering the emission intensity (at 440 nm) of P as one fold. Bars 1–7 of (b) correspond to traces 1–7 of (a) and bars 8 and 9 correspond to P+F+10 mm and 100 mm aminoguanidine, respectively. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Figure 1

Fig. 2 Inhibition of advanced glycation end products-mediated protein cross-links by rutin. (a) Representative SDS-PAGE profile of total soluble protein upon in vitro glycation in the absence and presence of rutin. Lane 1, molecular weight markers; lane 2, protein alone (P); lane 3, P+100 mm-fructose (F); lane 4, P+F+10 μm-rutin; lane 5, P+F+50 μm-rutin; lane 6, P+F+100 μm-rutin. (b) Densitometry analysis of cross-linked and aggregated proteins. Intensity of protein bands above 31 kDa was quantified considering the intensity of lane 2 (a) as 100 %. Bars 1–5 of (b) correspond to lanes 2–6 of (a). Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Figure 2

Fig. 3 Immunodetection of advanced glycation end products (AGE) in soluble lens protein. (a) Representative Western blot profile of total soluble protein upon in vitro glycation in the absence and presence of rutin. Blots were probed with anti-methylglyoxal-bovine serum albumin (top), anti-carboxy methyl lysine-keyhole limpet haemocyanin (middle) and anti-AGE-ribonuclease antibodies (bottom). Lane 1, molecular weight markers; lane 2, protein alone (P); lane 3, P+100 mm-fructose (F); lane 4, P+F+10 μm-rutin; lane 5, P+F+50 μm-rutin and lane 6, P+F+100 μm-rutin. (b) Densitometry analysis of AGE. Intensity of AGE signals was quantified considering the intensity of lane 2 (a) as 100 %. Bars 1–5 in (b) correspond to lanes 2–6 of (a). Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Figure 3

Fig. 4 The effect of rutin on the amount of glycated protein in total soluble protein upon in vitro glycation as analysed by phenyl boronate affinity chromatography. Trace 1, protein alone (P); trace 2, P+100 mm-fructose (F); trace 3, P+F+10 μm-rutin; trace 4, P+F+50 μm-rutin; trace 5, P+F+100 μm-rutin. OD, optical density.

Figure 4

Fig. 5 Protein carbonyl content of total soluble protein upon in vitro glycation in the absence and presence of rutin. Bar 1, protein alone (P); bar 2, P+100 mm-fructose (F); bar 3, P+F+10 μm-rutin; bar 4, P+F+50 μm-rutin; bar 5, P+F+100 μm-rutin; bar 6, P+F+10 mm-aminoguanidine; bar 7, P+F+100 mm-aminoguanidine. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 2 (P < 0·05).

Figure 5

Fig. 6 Chelation of metals by rutin. Percentage ascorbic acid unoxidised due to metal catalysed reaction in the absence and presence of rutin. Bar 1, ascorbic acid (AA)+CuCl2; bar 2, AA+CuCl2+50 μm-rutin; bar 3, AA+CuCl2+100 μm-rutin; bar 4, AA+CuCl2+500 μm-rutin; bar 5, AA+CuCl2+1000 μm-rutin. Values are means, with their standard errors represented by vertical bars of three independent experiments. * Mean values were significantly different from bar 1 (P < 0·05).

Figure 6

Fig. 7 Spectral shift of rutin in the presence of CuCl2. Absorption spectrum of 50 μm-rutin in the absence (trace 2) and presence of 1 μm-CuCl2 (trace 3), absorption spectrum of 100 μm-rutin in the absence (trace 4) and presence of 1 μm-CuCl2 (trace 5). Absorption spectrum of 1 μm-CuCl2 alone is also recorded (trace 1).

Figure 7

Fig. 8 Inhibition of post-Amadori product formation by rutin and aminoguanidine. Non-tryptophan advanced glycation end products fluorescence of bovine serum albumin (BSA) upon incubation with 0·4 m-ribose (R) in the absence and presence of rutin or aminoguanidine or both was recorded at 440 nm upon excitation at 370 nm. (a) Bars 1–5 correspond to BSA alone, BSA+R, BSA+R+50 μm-rutin, BSA+R+100 μm-rutin and BSA+R+200 μm-rutin, respectively. (b) Bars 1–6 correspond to BSA alone, BSA+R, BSA+R+100 μm-rutin, BSA+R+100 mm-aminoguanidine, BSA+R+100 μm-rutin+10 mm-aminoguanidine and BSA+R+100 μm-rutin+100 mm-aminoguanidine, respectively. Values are means, with their standard errors represented by vertical bars, n 3. * Mean values were significantly different from bar 2 (P < 0·05).