In Vitro Kinetic Studies of Formation of Antigenic Advanced Glycation End Products (AGEs)
NOVEL INHIBITION OF POST-AMADORI GLYCATION PATHWAYS*

(Received for publication, September 6, 1996, and in revised form, October 30, 1996)

A. Ashley Booth , Raja G. Khalifah Dagger , Parvin Todd and Billy G. Hudson Dagger

From the Department of Biochemistry and Molecular Biology, University of Kansas Medical Center, Kansas City, Kansas 66160-7421

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

Nonenzymatic protein glycation (Maillard reaction) leads to heterogeneous, toxic, and antigenic advanced glycation end products ("AGEs") and reactive precursors that have been implicated in the pathogenesis of diabetes, Alzheimer's disease, and normal aging. In vitro inhibition studies of AGE formation in the presence of high sugar concentrations are difficult to interpret, since AGE-forming intermediates may oxidatively arise from free sugar or from Schiff base condensation products with protein amino groups, rather than from just their classical Amadori rearrangement products. We recently succeeded in isolating an Amadori intermediate in the reaction of ribonuclease A (RNase) with ribose (Khalifah, R. G., Todd, P., Booth, A. A., Yang, S. X., Mott, J. D., and Hudson, B. G. (1996) Biochemistry 35, 4645-4654) for rapid studies of post-Amadori AGE formation in absence of free sugar or reversibly formed Schiff base precursors to Amadori products. This provides a new strategy for a better understanding of the mechanism of AGE inhibition by established inhibitors, such as aminoguanidine, and for searching for novel inhibitors specifically acting on post-Amadori pathways of AGE formation. Aminoguanidine shows little inhibition of post-Amadori AGE formation in RNase and bovine serum albumin, in contrast to its apparently effective inhibition of initial (although not late) stages of glycation in the presence of high concentrations of sugar. Of several derivatives of vitamins B1 and B6 recently studied for possible AGE inhibition in the presence of glucose (Booth, A. A., Khalifah, R. G., and Hudson, B. G. (1996) Biochem. Biophys. Res. Commun. 220, 113-119), pyridoxamine and, to a lesser extent, thiamine pyrophosphate proved to be novel and effective post-Amadori inhibitors that decrease the final levels of AGEs formed. Our mechanism-based approach to the study of AGE inhibition appears promising for the design and discovery of novel post-Amadori AGE inhibitors of therapeutic potential that may complement others, such as aminoguanidine, known to either prevent initial sugar attachment or to scavenge highly reactive dicarbonyl intermediates.


INTRODUCTION

Nonenzymatic protein glycation (glucosylation or glycosylation) by glucose is a complex cascade of condensations, rearrangements, fragmentations, and oxidative modifications that lead to poorly characterized heterogeneous products often collectively termed Advanced Glycation End Products or AGEs1 (1-7). These very slow Maillard reactions are believed to underlie the pathogenesis of diabetes (8-15) and possibly neurodegenerative amyloidal diseases such as Alzheimer's (16-21). Nonenzymatic glycation should normally always be occurring, although at a slower rate than in diabetes, and thus may contribute to the pathogenesis of aging (22-25). In vitro prepared serum proteins containing AGEs have also been shown to be toxic, immunogenic, and capable of triggering cellular injury responses after uptake by specific cellular receptors (26-31). The discovery of chemical agents that can inhibit deleterious glycation reactions is potentially of great therapeutic benefit to all these pathologies, but no such pharmacological agents have entered clinical practice to date.

Most kinetic studies of AGE inhibition so far have focused on observing the overall glycation of proteins in the presence of high, nonphysiological concentrations of reducing sugar. The elucidation of the mechanism of inhibition of any candidate AGE inhibitor under such conditions is an extremely difficult task due to the complexity of the glycation cascade (Scheme 1). For example, reactive AGE-forming intermediates can arise from oxidative reactions ("glycoxidation") of free sugar or from initial Schiff base condensation products with protein amino groups, rather than just from the "classical" Amadori rearrangement products. Furthermore, an inhibitor could potentially act at more than one step of the glycation pathway, so that its contributions to each step would have to be evaluated. This is typified by the prominent AGE inhibitor aminoguanidine, or guanylhydrazine (Scheme 2), that can potentially react as a hydrazine with carbonyls of Amadori intermediates or can scavenge reactive dicarbonyls through its guanidinium moiety. Additionally, as a hydrazine it can block the reactive open chain carbonyl form of reducing sugars (32, 33). Few studies have quantitatively measured the complete kinetics of protein glycation due to the slowness of the reactions with glucose, making it even more difficult to draw conclusions about inhibition. Limited studies have been carried out on small model Amadori compounds (34-36) or on partially glycated protein intermediates (37, 38).



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Scheme 1.




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Scheme 2.


We have recently reported a significant simplification in studying the kinetics and mechanism of protein glycation (39). Since glycation by glucose is usually a slow reaction (weeks and months), we have investigated glycation with the pentose ribose, a more reactive analogue of glucose (40, 41). Those studies led to the unique preparation, kinetic characterization, and stabilization of a reactive glycation intermediate in ribonuclease A. After removing excess and reversibly bound ribose from this presumed Amadori intermediate (Scheme 1), it rapidly forms AGEs with a half-time for the exponential kinetics of about 10 h (39). This "interrupted glycation" method provides a new mechanism-based strategy for a better understanding of AGE inhibition by established inhibitors, such as aminoguanidine, through isolating post-Amadori pathways of AGE formation (cf. Scheme 1) and thus removing effects arising from glycoxidation of free sugar or Schiff base (Namiki pathway) (35). More importantly, it opens the way to searching for novel inhibitors that specifically act on post-Amadori pathways of AGE formation. Baynes and co-workers (38) have recently emphasized the importance of Amadori products for the in vivo formation of AGEs. We note that exogenously administered Amadori and AGE proteins have been shown to produce diabetic-like glomerular sclerosis, basement membrane thickening, and albuminuria (42, 43).

We now report the successful use of the above approach to elucidate important aspects of the inhibition by aminoguanidine and to discover novel post-Amadori inhibitors of AGE formation. In particular, we examined several derivatives of vitamins B1 and B6 (Scheme 2) that were recently screened for possible AGE inhibition in the presence of high glucose (44). They were chosen for study due to the chemistry of their participation as cofactors in many alpha -carbonyl reactions in carbohydrate metabolism, which could relate to alpha -carbonyls of Amadori intermediates. Two derivatives, pyridoxamine and thiamine pyrophosphate, proved to be unique post-Amadori inhibitors of AGE formation. In contrast, the classic AGE inhibitor aminoguanidine (45) surprisingly showed little post-Amadori inhibition. We confirmed that our earlier inhibition results (44) and the present ones are generally not specific for the proteins used, even though there are individual variations in rates of AGE formation and inhibition.


EXPERIMENTAL PROCEDURES

Chemicals and Materials

Bovine pancreatic ribonuclease A was obtained from Worthington as a chromatographically pure and aggregate-free protein. Bovine serum albumin (fraction V, fatty acid free), human methemoglobin, D-ribose, pyridoxine, pyridoxal, pyridoxal 5'-phosphate, pyridoxamine, thiamine, thiamine monophosphate, thiamine pyrophosphate, and goat alkaline phosphatase-conjugated anti-rabbit IgG were all from Sigma. Aminoguanidine hydrochloride was purchased from Aldrich.

Preparation of Polyclonal Antibodies to AGE Proteins

Immunogen preparation was carried out primarily following earlier protocols (46-48). We prepared polyclonal antibodies against glucose-modified AGE-BSA antigen (designated R479) for experiments on glycation of RNase A and polyclonal antibodies against glucose-modified AGE-RNase antigen (designated R618) for experiments on glycation of serum albumin. Glycated antigens were prepared by incubating the proteins at 1.6 g in 15 ml of 1.5 M glucose in 0.4 M phosphate containing 0.05% sodium azide at pH 7.4 and 37 °C for 90 days. New Zealand White male rabbits of 8-12 weeks were immunized by subcutaneous administration of a 1-ml solution containing 1 mg/ml AGE-protein antigen in Freund's adjuvant. The primary injection used the complete adjuvant, and subsequently three boosters were made at 3-week intervals with Freund's incomplete adjuvant. The rabbits were bled 3 weeks after the last booster, and the serum was collected by centrifugation of clotted whole blood.

ELISA Detection of AGE Products

ELISA was performed according to methods described by Engvall (49), essentially as described earlier (39). Glycated protein samples were diluted to approximately 1.5 µg/ml in 0.1 M sodium carbonate buffer of pH 9.5-9.7. The protein was coated overnight at room temperature onto a 96-well polystyrene plates by pipetting 200 µl of the protein solution in each well (0.3 µg/well).2 After coating, the protein was washed from the wells with a saline solution containing 0.05% Tween 20. The wells were then blocked with 200 µl of 1% casein in carbonate buffer for 1.5 h at 37 °C followed by washing. Rabbit anti-AGE antibodies were diluted at a titer of 1:350 in incubation buffer and incubated for 1 h at 37 °C, followed by washing. As noted above, antibodies (R479) used to detect AGE in glycated RNase were raised against glycated BSA, and antibodies (R618) used to detect AGE in glycated BSA and glycated human methemoglobin were raised against glycated RNase. An alkaline phosphatase-conjugated antibody to rabbit IgG was then added as the secondary antibody at a titer of 1:2000 and incubated for 1 h at 37 °C, followed by washing. The p-nitrophenyl phosphate substrate solution was then added (200 µl/well) to the plates, with the absorbance of the released p-nitrophenolate being monitored at 410 nm with a Dynatech MR4000 microplate reader. The ELISA reader absorbances were monitored to ensure that readings were within the linear range of the instrument. Typically, readings of plates were taken at various time intervals after substrate was added in order to find the highest acceptable absorbances that provide the best dynamic range for each kinetic series. Absolute values of ELISA readings are thus not valid for comparison of different plates. Conversely, different series that need to be compared are plated and read together (same developing time).

Uninterrupted Ribose Glycation Assays

Bovine serum albumin, ribonuclease A, and human methemoglobin were incubated with ribose at 37 °C in 0.4 M sodium phosphate buffer of pH 7.5 containing 0.02% sodium azide. The protein (10.0 or 1.0 mg/ml), 0.05 M ribose, and prospective inhibitors at 0.5, 3, 15, or 50 mM were introduced into the incubation mixture simultaneously. Solutions were kept in the dark in capped tubes. Aliquots were taken and immediately frozen until analyzed by ELISA at the conclusion of the reaction. The incubations were for 3 (human methemoglobin) or 6 weeks (RNase, BSA). Glycation reaction mixtures were carefully monitored to make sure constant pH conditions were maintained throughout the duration of the experiments.

Interrupted (Post-Amadori) Ribose Glycation Experiments

Glycation was carried out by first incubating the protein (10 mg/ml) with ribose (0.5 M) at 37 °C in 0.4 M phosphate buffer of pH 7.5 containing 0.02% sodium azide for 24 h in the absence of inhibitors. Glycation was then interrupted to remove excess and reversibly bound (Schiff base) sugar by extensive dialysis against frequent cold buffer changes at 4 °C. The glycated BSA or RNase intermediate containing maximal amount of Amadori product and little AGE (depending on the protein) was then quickly warmed to 37 °C without re-addition of any ribose. This initiated conversion of Amadori intermediates to AGE products in the absence or presence of various concentrations (typically 3, 15, and 50 mM) of prospective inhibitors. Aliquots were taken at various intervals and frozen for later ELISA assays at the end of the reaction. Solutions were kept in the dark in capped tubes. The procedure has been fully described (39).

Numerical Analysis of Kinetics Data

We routinely fit kinetics data (time progress curves) to mono- or bi-exponential functions using nonlinear least squares methods utilizing either SCIENTIST 2.0 (MicroMath, Inc.) or ORIGIN (Microcal, Inc.) software that permit user-defined functions and control of parameters to iterate. Standard deviations of the parameters of the fitted functions (initial and final ordinate values and rate constants) were returned as measures of the precision of the fits. Apparent half-times for bi-exponential kinetics fits were determined with the "solve" function of MathCad software (MathSoft, Inc.).


RESULTS

Before presenting and then discussing the results, it may be useful to emphasize that there is no standard method of defining or following AGE formation and its inhibition. Quantitation of initial Schiff base condensation of labeled reducing sugars with protein amino groups provides little information on post-Amadori steps of AGE formation, since such steps may not lead to changes in the extent of labeling. Many studies of AGE formation have monitored the increase in blue fluorescence arising from "browning" glycation products. Such fluorescent changes can be produced by dicarbonyl or glycoxidation products that arise from free sugar, from the initial Schiff bases, and from Amadori and other intermediates (50-52). Carboxymethyllysine (CmL), a notable AGE, can also arise from a variety of glycoxidation intermediates besides the Amadori product (35, 36, 53). The acid-stable fluorescent AGE pentosidine (54-56) can be utilized in principle, but the chemical work-up, protein hydrolysis, and high performance liquid chromatography separation required for each time point makes its use inconvenient for large sets of kinetics. In this work we chose to use sensitive ELISA techniques (46-48, 57, 58) that utilize anti-AGE polyclonal antibodies developed against proteins typically glycated for 60-90 days with glucose. This approach recently proved highly suitable for detailed kinetics studies of the formation of antigenic AGE products and its inhibition (39, 44).2

The results in this section are presented as two series of inhibition experiments. In the first series, the indicated proteins are mixed with ribose to initiate glycation in the presence and absence of the inhibitors, and the formation of AGEs was monitored by ELISA. This assay is referred to as "overall glycation kinetics" or as "uninterrupted glycation." In the second series of experiments, an interrupted glycation method was used to follow "post-Amadori kinetics" of AGE formation in absence of ribose. The proteins were first incubated at 37 °C with ribose for 24 h during which Amadori intermediates (Scheme 1) accumulated (39). The excess and reversibly bound sugar was then removed by dialysis at 4 °C, and AGE formation was initiated (the zero time) in the presence and absence of inhibitors by warming the solutions back to 37 °C.

Inhibition by Vitamin B6 Derivatives of the Overall Kinetics of AGE Formation

The inhibitory effects of the B1 and B6 vitamins on the kinetics of antigenic AGE formation were evaluated by polyclonal antibodies specific for AGEs.3 Our initial inhibition studies were carried out on the glycation of bovine ribonuclease A (RNase) in the continuous presence of 0.05 M ribose. It has been shown elsewhere (39) that the rate of AGE formation is near-maximal at this concentration. Fig. 1 (control curves, filled rectangles) demonstrates that the formation of antigenic AGEs on RNase when incubated with 0.05 M ribose is relatively rapid, with a half-time of approximately 6 days under these temperature and buffer conditions. Pyridoxal 5'-phosphate (Fig. 1B) and pyridoxal (Fig. 1C) significantly inhibited the rate of AGE formation on RNase at concentrations of 50 and 15 mM. Surprisingly, pyridoxine, the alcohol form of vitamin B6 (Scheme 2), also moderately inhibited AGE formation on RNase (Fig. 1D). Of the B6 derivatives examined above, pyridoxamine at 50 mM provided the best inhibition of "final" levels of AGE formation on RNase over the 6-week period monitored (Fig. 1A).


Fig. 1. Effect of vitamin B6 derivatives on AGE formation during uninterrupted glycation of ribonuclease A by ribose. RNase (1 mg/ml) was incubated with 0.05 M ribose in the presence and absence of the various indicated derivatives in 0.4 M sodium phosphate buffer of pH 7.5 at 37 °C for 6 weeks. Aliquots were assayed by ELISA using R479 anti-AGE antibodies. Concentrations of the inhibitors were 0.5, 3.0, 15, and 50 mM. A, pyridoxamine (PM); B, pyridoxal-5'-phosphate (PLP); C, pyridoxal (PL); D, pyridoxine (PN).
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Inhibition by Vitamin B1 Derivatives of the Overall Kinetics of AGE Formation

All of the B1 vitamers inhibited antigenic AGE formation on RNase at high concentrations, but the inhibition appeared more complex than for the B6 derivatives (Fig. 2, A-C). In the case of thiamine pyrophosphate (Fig. 2A), both the rate of AGE formation and the final levels of AGE produced at the plateau appeared diminished by the compound. In the case of thiamine phosphate (Fig. 2B) and thiamine (Fig. 2C), there appeared little effect on the rate of AGE formation, but a substantial decrease in the final level of AGE formed in the presence of the highest concentration of inhibitor. In general, thiamine pyrophosphate demonstrated greater inhibition than the other two compounds at the lower concentrations examined.


Fig. 2. Effects of vitamin B1 derivatives and aminoguanidine on AGE formation during uninterrupted glycation of ribonuclease A by ribose. RNase (1 mg/ml) was incubated with 0.05 M ribose in the presence and absence of the various indicated derivatives in 0.4 M sodium phosphate buffer of pH 7.5 at 37 °C for 6 weeks. Aliquots were assayed by ELISA using R479 anti-AGE antibodies. Concentrations of the inhibitors were 0.5, 3.0, 15, and 50 mM. A, thiamine pyrophosphate (TPP); B, thiamine monophosphate (TP); C, thiamine (T); D, aminoguanidine (AG).
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Inhibition by Aminoguanidine of the Overall Kinetics of AGE Formation

Inhibition of AGE formation by aminoguanidine (Fig. 2D) was distinctly different from that seen by the B1 and B6 derivatives above. Increasing concentrations of aminoguanidine decreased the rate of AGE formation on RNase but did not reduce the final levels of AGE formed, so that the level of AGEs produced by the 6th week was almost identical to that of the control.

Inhibition of the Overall Kinetics of AGE Formation in Serum Albumin and Hemoglobin

Comparative studies were carried out with bovine serum albumin and human methemoglobin to determine whether the observed inhibition was protein-specific. The different derivatives of vitamin B6 (Fig. 3, A-D) and vitamin B1 (Fig. 4, A-C) exhibited similar inhibition trends when incubated with bovine serum albumin, with pyridoxamine and thiamine pyrophosphate being the most effective inhibitors in each of the respective families. Pyridoxine failed to inhibit AGE formation on BSA (Fig. 3D). Pyridoxal phosphate and pyridoxal (Fig. 3, B-C) mostly inhibited the rate of AGE formation but not the final levels. Pyridoxamine (Fig. 3A) again exhibited some inhibition at lower concentrations and at the highest concentration appeared to inhibit the final levels of AGE formation more effectively than the other B6 vitamers. In the case of the B1 vitamers, the overall extent of inhibition on BSA (Fig. 4, A-C) was less than that observed with RNase (Fig. 2, A-C). Higher concentrations of thiamine and thiamine monophosphate only slightly inhibited AGE formation on BSA (Fig. 4, B and C), whereas thiamine pyrophosphate inhibited the final levels of AGE formation without greatly affecting the rate of formation (Fig. 4A). Aminoguanidine again displayed the inhibition effects with BSA that it did with RNase (Fig. 4D), appearing to only slow the rate of AGE formation with lesser effects on decreasing the final levels of AGE.


Fig. 3. Effect of vitamin B6 derivatives on AGE formation during uninterrupted glycation of bovine serum albumin by ribose. BSA (10 mg/ml) was incubated with 0.05 M ribose in the presence and absence of the various indicated derivatives in 0.4 M sodium phosphate buffer of pH 7.5 at 37 °C for 6 weeks. Aliquots were assayed by ELISA using R618 anti-AGE antibodies. Concentrations of the inhibitors were 0.5, 3, 15, and 50 mM. A, pyridoxamine (PM); B, pyridoxal phosphate (PLP); C, pyridoxal (PL); D, pyridoxine (PN).
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Fig. 4. Effects of vitamin B1 derivatives and aminoguanidine on AGE formation during uninterrupted glycation of bovine serum albumin by ribose. BSA (10 mg/ml) was incubated with 0.05 M ribose in the presence and absence of the various indicated derivatives in 0.4 M sodium phosphate buffer of pH 7.5 at 37 °C for 6 weeks. Aliquots were assayed by ELISA using R618 anti-AGE antibodies. Concentrations of the inhibitors were 0.5, 3, 15, and 50 mM. A, thiamine pyrophosphate (TPP); B, thiamine monophosphate (TP); C, thiamine (T); D, aminoguanidine (AG).
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The kinetics of AGE formation were also examined with human methemoglobin in the presence of the B6 and B1 vitamers and aminoguanidine. The absolute rates of AGE formation appeared higher with human methemoglobin than with the other two proteins,2 but the compounds revealed largely similar inhibition trends (data not shown). Of the vitamin B6 derivatives, pyridoxamine showed the greatest inhibition at concentrations of 3 mM and above when compared with pyridoxal phosphate, pyridoxal, and pyridoxine. In the case of the B1 compounds, the inhibitory effects were more similar to the BSA inhibition trends than to RNase. The inhibition was modest at the highest concentrations tested (50 mM), being nearly 30-50% for all three vitamers (data not shown). It was primarily manifest as a decrease in the final levels of AGE.

Inhibition by Vitamin B6 Derivatives of the Kinetics of Post-Amadori Ribose AGE Formation

In the interrupted glycation assays for following post-Amadori AGE formation, kinetics were followed by incubating isolated Amadori intermediates of either RNase or BSA at 37 °C in absence of free or reversibly bound ribose. Ribose sugar that was initially used to prepare the intermediates was removed by cold dialysis after an initial glycation period of 24 h. Following this interruption, AGE formation resumes and the kinetics of this post-Amadori AGE formation is quite rapid (half-times of about 10 h) in absence of inhibitors (39). Fig. 5 shows the effects of pyridoxamine (Fig. 5A), pyridoxal phosphate (Fig. 5B), and pyridoxal (Fig. 5C) on the post-Amadori kinetics of BSA. Pyridoxine did not produce any inhibition (data not shown). Similar experiments were carried out on RNase. Pyridoxamine showed nearly complete inhibition at 15 and 50 mM (Fig. 5D). Pyridoxal did not show significant inhibition at 15 mM, the highest concentration tested, but pyridoxal phosphate, which is known to be an affinity label for the active site of RNase (59), showed significant inhibition at 15 mM (data not shown). Note that with BSA, unlike RNase, a significant amount (25-30%) of antigenic AGE formed during the 24-h initial incubation with ribose, as evidenced by the higher ELISA readings after removal of ribose at the zero time of Fig. 5, A-C. For both proteins, the inhibition when present appears to be manifest as a decrease in the final levels of AGEs formed rather than as a decrease in the rate of AGE formation.


Fig. 5. Effect of vitamin B6 derivatives on post-Amadori AGE formation after interrupted glycation by ribose. BSA and RNase were incubated for 24 h with 0.5 M ribose for 24 h at 37 °C followed by extensive dialysis for 24 h at 4 °C to remove excess and reversibly bound ribose. AGE formation was then initiated (zero time) by incubating the Amadori-rich proteins (BSA in A-C or and RNase in D) at 0.1 mg/ml in 0.4 M phosphate buffer of pH 7.5 at 37 °C in the absence and presence of 3, 15, and 50 mM concentrations of the indicated inhibitors. Aliquots were assayed by ELISA using R479 anti-AGE antibodies for RNase and R618 antibodies for BSA. A, pyridoxamine (PM); B, pyridoxal phosphate (PLP); C, pyridoxal (PL); D, pyridoxamine (PM).
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No comparative studies on inhibition of hemoglobin post-Amadori AGE formation were carried out by this assay, since the larger amount of AGE formed during the 24 h of initial glycation with ribose (data not shown) makes it difficult to study the post-Amadori component.

Inhibition by Vitamin B1 Derivatives of the Kinetics of Post-Amadori Ribose AGE Formation

Thiamine pyrophosphate inhibited AGE formation more effectively (Fig. 6) than the other B1 vitamers (data not shown) for both RNase and BSA. Thiamine showed no inhibition, whereas thiamine phosphate showed intermediate effects. As with the B6 experiments, the post-Amadori inhibition was manifest as a decrease in the final level of AGE formed.


Fig. 6. Effect of thiamine pyrophosphate on post-Amadori AGE formation after interrupted glycation by ribose. BSA and RNase were incubated for 24 h with 0.5 M ribose for 24 h at 37 °C followed by extensive dialysis for 24 h at 4 °C to remove excess and reversibly bound ribose. AGE formation was then initiated (zero time) by incubating the Amadori-rich proteins (RNase in A and BSA in B) at 0.1 mg/ml in 0.4 M phosphate buffer of pH 7.5 at 37 °C in the absence and presence of 3, 15, and 50 mM concentrations of the thiamine pyrophosphate. Aliquots were assayed by ELISA using R479 anti-AGE antibodies for RNase and R618 antibodies for BSA.
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Inhibition by Aminoguanidine and Nalpha -Acetyl-L-lysine of the Kinetics of Post-Amadori Ribose AGE Formation

Aminoguanidine was also tested for inhibition of the post-Amadori AGE formation kinetics on BSA and RNase (Fig. 7). At 50 mM the inhibition was about 20% in the case of BSA (Fig. 7B) and less than 15% in the case of RNase (Fig. 7A). The latter result fully agrees with our previously reported independent experiments, where up to 250 mM aminoguanidine was used (39). An additional experiment was carried out to test possible inhibition by simple amino-containing functionalities. We tested the effects of Nalpha -acetyl-L-lysine that contains only the free Nepsilon -amino group (data not shown). Nalpha -Acetyl-L-lysine up to 50 mM failed to show any detectable inhibition of antigenic AGE formation in this interrupted glycation assay.


Fig. 7. Effect of aminoguanidine on post-Amadori AGE formation after interrupted glycation by ribose. BSA and RNase were incubated for 24 h with 0.5 M ribose for 24 h at 37 °C followed by extensive dialysis for 24 h at 4 °C to remove excess and reversibly bound ribose. AGE formation was then initiated (zero time) by incubating the Amadori-rich proteins (RNase in A or and BSA in B) at 0.1 mg/ml in 0.4 M phosphate buffer of pH 7.5 at 37 °C in the absence and presence of 3, 15, and 50 mM concentrations of aminoguanidine. Aliquots were assayed by ELISA using R479 anti-AGE antibodies for RNase and R618 antibodies for BSA.
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DISCUSSION

Two different strategies have been utilized in the present work in order to better elucidate the kinetics and mechanism of AGE inhibition by aminoguanidine and the other compounds. In the first, we examined the much more rapid glycation by ribose, where the time course could be completely observed and quantitated (39), and we compared that with inhibition of glycation by glucose (44). In the second approach, we have utilized our unique ability to prepare ribose Amadori intermediates that are free of AGEs (39) to follow the extremely rapid kinetics of post-Amadori antigenic AGE formation on RNase and BSA in absence of free and reversibly bound ribose. Our initial attempts to isolate an Amadori-rich, AGE-free intermediate from glucose capable of producing significant amounts of antigenic AGEs have not been successful using a 3-day interruption4 (39).

Numerous studies have demonstrated that aminoguanidine is an inhibitor of many manifestations of nonenzymatic glycation (28, 45, 60, 61), and it recently entered second phase III clinical trials for ameliorating the complications of diabetes (11, 61). Our recent kinetic studies confirmed that aminoguanidine is a potent inhibitor of antigenic AGE formation induced by high glucose concentrations (44). However, the inhibition unexpectedly appeared to diminish at later stages of the kinetics (cf. Fig. 2D and Fig. 4D of Ref. 44). Due to the slowness of the glycation with glucose, this surprising observation could not be completely established. Furthermore, the basis for this diminished inhibition is open to question due to the possible long term instability of aminoguanidine and its potential to produce hydrogen peroxide (62). The present, more complete kinetics of aminoguanidine inhibition of ribose glycation (Fig. 2D and Fig. 4D) appear fully consistent with the earlier glucose findings. The ribose glycation results clearly demonstrate that aminoguanidine slows the rate of antigenic AGE formation in the presence of sugar but has little effect on the final amount of AGE formed. As a consequence, observations limited to the initial stages of either the glucose or the ribose glycation will show remarkable apparent inhibitor efficacy that may be misleading.

Mechanistically, these kinetics results indicate that aminoguanidine most likely inhibits in our assay by interacting with rate-determining initial reactants (protein or sugar). In the case of glycation by ribose, the overall rate of AGE formation has been shown to be strongly dependent on ribose concentration (39) but independent of protein over a 1000-fold concentration range.5 In terms of the classical pathway of glycation (Scheme 3), aminoguanidine could decrease the rate of initial Schiff base formation by complexing the acyclic free aldehyde forms of the sugars.6 Inhibition through formation of such an aminoguanidine-sugar interaction was first advanced by Khatami et al. (32), and recently a glucose-aminoguanidine adduct was produced, isolated, and structurally characterized by Hirsch et al. (33).


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Scheme 3.

The hypothesis that aminoguanidine does not significantly react with the Amadori or later intermediates on the path of formation of AGEs could be directly tested by observing its possible effects on the isolated post-Amadori kinetic, i.e. starting with protein Amadori intermediates. Preliminary studies had indicated low effects of aminoguanidine on the rate of post-Amadori AGE formation in RNase (39). Since ribose is closely related to the enzymatic substrate of RNase and Lys-41 of the active site most easily forms Amadori products (63), it was important to verify this for other proteins. Fig. 7B demonstrates weak or negligible effects of aminoguanidine on the post-Amadori formation of AGEs in serum albumin at inhibitor concentrations up to 50 mM. The findings on RNase were also independently re-determined over the same concentration range (Fig. 7A). These results are especially noteworthy, as aminoguanidine was originally proposed by its discoverers to be a nucleophilic blocker of Amadori glycation intermediates (45, 64).

Studies from several laboratories have also not supported this originally proposed mechanism. Instead, aminoguanidine, through its guanidinium functionality, was found to inhibit another AGE formation pathway by scavenging reactive dicarbonyl intermediates (Scheme 1) that arise from glycoxidation during glycation (65-68). Dicarbonyls can include glyoxal and glycoaldehyde that arise from free sugar or from Schiff bases (via the Namiki pathway) and "glucosones" (deoxydiketoses or deoxyaldoketoses) which can arise from Amadori intermediates (35, 36, 38, 53). Hirsch et al. (66) found very rapid irreversible formation of 5- and 6-substituted triazines from reaction of aminoguanidine with model dicarbonyls, while Chen and Cerami (68) have reported that reaction of a model Amadori compound with aminoguanidine only leads to formation of triazine and bis-hydrazone products of dicarbonyl fragments derived from the Amadori compound. Edelstein and Brownlee (67) also reported that no aminoguanidine adducts are formed with a model glycated peptide, concluding that it only acts on Amadori-derived fragments. Since reactive dicarbonyls can also lead to the formation of the AGE carboxymethyllysine (CmL), it is significant that Glomb and Monnier (35) demonstrated that aminoguanidine at 5 mM is entirely ineffective in preventing the formation CmL when starting from a model lysine Amadori product and that it has an effect only when glycation is started in the presence of free sugar.

Our recent studies on AGE inhibition in the presence of high glucose concentrations (44) revealed substantial inhibition by some derivatives of vitamins B1 and B6, notably pyridoxamine, pyridoxal phosphate, and thiamine pyrophosphate. As with aminoguanidine, the inability to observe the full course of the glucose glycation kinetics with RNase and BSA left unresolved the important question of whether the apparent decreased rate of AGE formation was also accompanied by a decrease in the final levels of AGEs formed. In the present ribose study, where we followed both the uninterrupted (Figs. 1, 2, 3, 4) and the post-Amadori "interrupted" (Figs. 5, 6, 7) glycation kinetics, the inhibition patterns shown by some of the derivatives of vitamins B1 and B6 differed substantially from those of aminoguanidine. For example, pyridoxamine displayed both a decrease in rate of AGE formation and a decrease in apparent final AGE levels. The latter effect was more prominent for BSA (Fig. 3A) than for RNase (Fig. 1A), and it was quite dramatic for hemoglobin (data not shown). The other derivatives such as pyridoxal and pyridoxal phosphate predominantly showed inhibition of the rate of formation of AGEs in RNase and BSA with some inhibition of final AGE levels at the highest concentrations with hemoglobin. In the case of the vitamin B1 derivatives, more consistent decreases in final AGE levels than rates were observed with RNase (Fig. 2), with more modest effects being seen with BSA (Fig. 4).

The observed decreases in rate of formation of AGEs in the ribose glycation for some of these inhibitors suggests, as in the case of aminoguanidine, that they exert some of their effects through interactions with the open chain aldehyde forms of the reducing sugars or with the protein sites of glycation. Little is known about the former possibility for these compounds. However, pyridoxal and pyridoxal phosphate, as aldehydes, are known to compete with sugars for Schiff base formation with protein amino groups and have, indeed, been proposed as inhibitors of glycation through this "competitive" mechanism (32, 69, 70). In the particular case of RNase, pyridoxal phosphate has been shown to act as an affinity label for the active site by interacting with critical Lys-41 and Lys-7 (59).

The suggestive decreases in final levels of AGE formed by some of these derivatives in the presence of ribose imply that they may exert inhibitory effects through an additional mechanism, namely at the Amadori product level within the framework of the Scheme 3. Our attempt to verify this hypothesis through observation of the post-Amadori kinetics of AGE formation has led to the most striking result of this work, namely the discovery of the first examples of what may be termed a novel class of "post-Amadori AGE inhibitors." Pyridoxamine proved unique among the vitamin B6 derivatives in showing striking inhibition with both BSA (Fig. 5A) and RNase (Fig. 5D) at concentrations as low as 15 mM. Similarly, thiamine pyrophosphate among the vitamin B1 compounds showed a dose-dependent decrease in final AGE levels formed with both proteins (Fig. 6, A-B), although its effects were less than those of pyridoxamine. A fixed time (6-7 d) comparison of the inhibition by the three inhibitors is given in Fig. 8 for both BSA and RNase. While they earlier displayed nearly equal inhibition potency in the glucose glycation reaction (cf. Fig. 5 of Ref. 44), pyridoxamine and thiamine pyrophosphate now display far greater potency than aminoguanidine in inhibiting post-Amadori formation of late antigenic AGEs.


Fig. 8. Comparison of the post-Amadori inhibition of AGE formation by thiamine pyrophosphate (TPP), pyridoxamine (PM), and aminoguanidine (AG) after interrupted glycation of RNase (A) and BSA (B) by ribose. The proteins were incubated for 24 h with 0.5 M ribose for 24 h at 37 °C followed by extensive dialysis for 24 h at 4 °C to remove excess and reversibly bound ribose. AGE formation was then initiated by incubating the Amadori-rich proteins at 0.1 mg/ml in 0.4 M phosphate buffer of pH 7.5 at 37 °C in the absence and presence of 3, 15, and 50 mM concentrations of the inhibitors. Aliquots were assayed by ELISA using R479 anti-AGE antibodies for RNase and R618 antibodies for BSA. The indicated percent inhibition (ordinate values) is computed by comparing ELISA readings in the absence and presence of the inhibitors at the completion of the experiments shown in Figs. 5, 6, 7 (RNase, 7 days; BSA, 6 days).
[View Larger Version of this Image (48K GIF file)]


The unique post-Amadori inhibition by these two derivatives indicates a novel although unknown mechanism of action, not shared with aminoguanidine, that remains to be investigated. The elucidation of the chemical basis of this inhibition requires both the prior identification of the structures of the dominant antigenic AGEs and the elucidation of the mechanisms of their formation from Amadori or other intermediates. Despite significant recent progress (71), advances in these directions have been very difficult to achieve in the last decade. Since the completion of our work,7 however, a report by Ulrich and co-workers (72) has appeared that describes independent studies showing that certain dicarbonyl AGE cross-links may be chemically broken by a compound related to thiamine. These findings raise the intriguing possibility that such mechanisms may be relevant to the post-Amadori inhibition that we have discovered with at least thiamine pyrophosphate and possibly pyridoxamine. Future studies along these directions are clearly of great interest and should be pursued.

In conclusion, our mechanism-based approach has led to the identification of pyridoxamine and thiamine pyrophosphate as novel inhibitors of AGE formation and first examples of what may be termed post-Amadori inhibitors. Amadori pathways of formation of AGEs may be of particular importance in vivo (38). Although these inhibitors belong to the B1 and B6 vitamins series, there is no evidence at present to suggest that they function as endogenous AGE inhibitors, since the levels needed for effective in vitro inhibition are far greater than their in vivo occurrence. Both contain an amino group, but a simple amino functionality is insufficient to inhibit post-Amadori formation of AGEs, since Nalpha -acetyl-lysine is not inhibitory. Furthermore, aminoguanidine, a strongly nucleophilic hydrazine capable of interacting with carbonyl groups, shows little inhibition (Fig. 7). Their interesting and rich chemical roles as coenzymes for alpha -carbonyl reactions in carbohydrate metabolism (cf. 73, 74) suggest that they may provide valuable leads for the design and discovery of potent post-Amadori inhibitors that could have therapeutic potential. By effectively targeting a different step of the glycation pathway, post-Amadori inhibitors may complement established inhibitors such as aminoguanidine that either prevent initial sugar attachment to proteins or that scavenge highly reactive dicarbonyl intermediates that may arise from glycoxidative pathways.


FOOTNOTES

*   This work was supported by National Institutes of Health Grant DK 43507 (to B. G. H.) and by Grant KS95GS45 from the American Heart Association, Kansas Affiliate, Inc. (to R. G. K.). The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    To whom correspondence should be addressed: Dept. of Biochemistry and Molecular Biology, University of Kansas Medical Center, 3901 Rainbow Blvd., Kansas City, KS 66160-7421. E-mail: rkhalifa{at}kumc.edu (to R. G. K.) and bhudson{at}kumc.edu (to B. G. H.).
1    The abbreviations used are: AGE, advanced glycation end products (Maillard products); BSA, bovine serum albumin; RNase, bovine pancreatic ribonuclease A; ELISA, enzyme-linked immunosorbent assay; CmL, Nepsilon -carboxymethyllysine.
2    The ELISA method can be used to quantitatively study kinetics of AGE formation (cf. Ref. 39) provided that there is a linear dependence of the readings on the coated protein concentration (75). We have previously determined by control experiments that the linear range for RNase and BSA is below a coating concentration of about 0.2-0.3 µg/well. Although this was also used for hemoglobin, it was subsequently determined that the range of linearity is substantially lower, thus partially contributing to the apparently faster glycation kinetics seen with this protein here and earlier (44).
3    Polyclonal anti-AGE antibodies have proven to be a sensitive analytical tool for the study of AGE formation in vitro and in vivo, although the nature of the dominant antigenic AGE epitope of hapten remains in doubt. Baynes and co-workers (71) recently demonstrated that the protein glycoxidation product carboxymethyllysine (CmL) is a dominant antigen of their antibodies, and they were able to rationalize why earlier studies had failed to reveal strong ELISA reactivity with model carboxymethyllysine compounds (48). Our preliminary characterization of our polyclonal antibodies reveals a strong, although variable, CML reactivity.5
4    The apparently lower Amadori build-up with glucose could be due to differences in rate constant ratios (k3 versus k4 + k5 in Scheme 3) rather than to differences in glycation mechanism between the two sugars.
5    R. G. Khalifah, manuscript in preparation.
6    Although at equilibrium the acyclic forms constitute about 0.002 and 0.05% for glucose and ribose, respectively (41, 76), these are the species that amino groups react with to initiate glycation.
7    A preliminary account of this work has been presented at the ASBMB/ASIP/AAI meeting, New Orleans, LA, June 2-6, 1996, and has been published in abstract form: Booth, A. A., Khalifah, R. G., and Hudson, B. G. (1996) FASEB J. 10, A1100 (Abstr. 583).

Acknowledgments

We express our appreciation to Drs. Milton Noelken and J. Wesley Fox and to Brian Cussimanio for many helpful discussions.


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