This Article Abstract Full Text (PDF) All Versions of this Article: 24/8/1342    most recent 01.ATV.0000133191.71196.90v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Naka, Y. Articles by Schmidt, A. M. Search for Related Content PubMed PubMed Citation Articles by Naka, Y. Articles by Schmidt, A. M. Related Collections Other anticoagulants Type 1 diabetes Type 2 diabetes Mechanism of atherosclerosis/growth factors Developmental biology

(Arteriosclerosis, Thrombosis, and Vascular Biology. 2004;24:1342.)
© 2004 American Heart Association, Inc.

Brief Reviews

RAGE Axis

Animal Models and Novel Insights Into the Vascular Complications of Diabetes

Yoshifumi Naka; Loredana G. Bucciarelli; Thoralf Wendt; Larisse K. Lee; Ling Ling Rong; Ravichandran Ramasamy; Shi Fang Yan; Ann Marie Schmidt

From the Department of Surgery, College of Physicians & Surgeons, Columbia University, New York, NY.

Correspondence to Dr Ann Marie Schmidt, Division of Surgical Science, Department of Surgery, College of Physicians & Surgeons, Columbia University, 630 West 168th Street, P&S 17-501, New York, NY 10032. E-mail ams11{at}columbia.edu

Series Editor: Richard A. Cohen
ATVB In Focus

Diabetic Vascular Disease: Pathophysiological Mechanisms in the Diabetic Milieu and Therapeutic Implications

	Abstract

Top Abstract Introduction Conclusions References

 
Receptor for AGE (RAGE) is a multi-ligand member of the immunoglobulin superfamily of cell surface molecules. Engagement of RAGE by its signal transduction ligands evokes inflammatory cell infiltration and activation in the vessel wall. In diabetes, when fueled by oxidant stress, hyperglycemia, and superimposed stresses such as hyperlipidemia or acute balloon/endothelial denuding arterial injury, the ligand–RAGE axis amplifies vascular stress and accelerates atherosclerosis and neointimal expansion. In this brief synopsis, we review the use of rodent models to test these concepts. Taken together, our findings support the premise that RAGE is an amplification step in vascular inflammation and acceleration of atherosclerosis. Future studies must rigorously test the potential impact of RAGE blockade in human subjects; such trials are on the horizon.

Ligand engagement of the receptor for advanced glycation end products (RAGE) evokes vascular inflammation and perturbation. In diabetes, when fueled by oxidation, hyperglycemia, and superimposed stresses, the ligand–RAGE axis accelerates atherosclerosis and neointimal expansion. Studies in rodent models of diabetes suggest that testing the impact of RAGE blockade in human subjects is logical.

Key Words: diabetes • animal models • receptors • inflammation • signal transduction

	Introduction

Top Abstract Introduction Conclusions References

 
The receptor for advanced glycation end products (RAGE) is a multi-ligand member of the immunoglobulin superfamily of cell surface molecules.^1,2 Its ability to recognize multiple classes of ligands, such as advanced glycation end products (AGEs), S100/calgranulins, amphoterin, amyloid-ß peptide and ß-sheet fibrils, and MAC-1,^3–8 suggests that the repertoire of RAGE-dependent effects in the tissues may be diverse. In this context, the function of this receptor does not appear to be to degrade/detoxify ligand, but rather, by RAGE cytosolic domain-triggered signal transduction, to propagate immune/inflammatory responses.^3,9

Although AGEs are an heterogeneous class of compounds, studies have shown that a particular class of these species, N carboxymethyl lysine (CML) adducts of proteins/lipids, are specific signal transduction ligands of RAGE.⁹ CML-modified adducts may be generated by a variety of stimuli. In addition to generation in hyperglycemia, CML adducts may also be generated by activation of the myeloperoxidase pathway.¹⁰ Recent studies have shown that peroxynitrite may induce formation of CML by cleavage of an Amadori product and, also, by the generation of reactive -oxoaldehydes from glucose.¹¹ These considerations highlight the concept that once set in motion, diabetes-associated hyperglycemia and oxidant stress magnify production of a wide array of biochemical species that accumulate to stimulate cellular activation and sustain tissue perturbation.

Furthermore, in diabetes, distinct mechanisms may be engaged to further fuel the cycle of AGE generation and oxidant stress.¹² One specific example is the polyol pathway. Glucose is reduced to sorbitol by aldose reductase, the central enzyme of this pathway. This results in generation of fructose; fructose is converted into fructose-3-phosphate by the action of 3-phosphokinase. A chief product of this reaction is 3-deoxyglucosone, a key precursor in the generation of multiple types of AGEs, such as CML adducts and others.^13,14 It has been shown that in renal failure, plasma levels of 3-deoxyglucosone increase in parallel with increased levels of aldose reductase in erythrocytes.¹⁴ Administration of an inhibitor of aldose reductase, epalrestat, to subjects with diabetes resulted in reduced levels of CML adducts and their precursors in erythrocytes and decreased plasma levels of thiobarbituric acid reactive substances.¹⁵ These considerations highlight the concept that multiple forces are in play in diabetes to augment generation of tissue injurious biochemical species that signal chronic cellular perturbation.

Indeed, once AGEs are formed, their interaction with RAGE triggers generation of proinflammatory cytokines, adhesion molecules, and chemokines. Attraction of inflammatory cells such as polymorphonuclear leukocytes, mononuclear phagocytes, and T-lymphocytes into the tissue provides a mechanism to sustain the inflammatory response. In the context of RAGE, these cells may harbor proinflammatory S100/calgranulins and amphoterin. Once these molecules are released into the tissue, S100/calgranulins/amphoterin–RAGE interaction may amplify tissue inflammation and injury by autocrine and paracrine pathways.^3,16–18

Models of Atherosclerosis in Diabetes
Multiple epidemiologic investigations support the premise that diabetes accelerates atherosclerosis; human subjects with diabetes display a striking acceleration of atherosclerosis, in addition to the increased incidence of cardiac events, such as heart attacks and strokes.^19–22 Studies in human subjects indicate that RAGE and its signal transduction ligands are expressed in diabetic vasculature and atherosclerotic plaques.^23,24 Cipollone et al showed that compared with nondiabetic human plaques, diabetic plaques were characterized by greater numbers of mononuclear phagocytes, T-lymphocytes, and HLA-DR⁺ cells, in parallel with increased expression of RAGE, activated NF-kB, cox-2, and matrix metalloproteinases. The extent of RAGE expression was found to correlate with levels of glycosylated hemoglobin.²⁴ Although such studies do not delineate the biochemical/molecular link between the ligand/RAGE axis, inflammation, and atherosclerosis, these experiments nevertheless provide support for the premise that RAGE may participate in augmentation of vascular injury and progression of atherosclerosis.

Studies in murine models are underway to test the premise that RAGE contributes to the acceleration of atherosclerosis in diabetes.

Animal Models and Accelerated Diabetic Atherosclerosis
The first murine model to support the concept that hyperglycemia accelerated atherosclerosis tested the hypothesis that induction of diabetes using multiple low-dose streptozotocin would result in enhanced atherosclerosis in mice fed Western-type diet.²⁵ In these first studies, wild-type BALB/c and C57BL/6 mice were used. In these animals, genetic manipulation was not used as a means to trigger/enhance the development of atherosclerosis. Rather, dietary modification induced hyperlipidemia. In this study, Kunjathoor et al showed that BALB/c mice fed an atherogenic diet and rendered diabetic with streptozotocin displayed a 17-fold increase in atherosclerotic lesion area compared with citrate-treated (nondiabetic) mice fed the same atherogenic diet. Although the lesions were limited to fatty streaks, histological studies nevertheless revealed the presence of both excess mononuclear phagocytes and smooth muscle cells in the plaques.²⁵ Interestingly, these investigators found that there were no differences in mean atherosclerotic lesion area between diabetic (streptozotocin) versus nondiabetic atherogenic diet-fed C57BL/6 mice.²⁵ These considerations underscore the critical influence that multiple factors may exert on atherosclerosis initiation and progress, such as genetic background, diet, and environment, especially in the setting of superimposed hyperglycemia.

In addition to dietary modulation of lipid profile, genetic modification provides a means to alter lipid profile in mice. To test the role of hyperglycemia in potentially accelerating atherosclerosis, we used mice in which genetic manipulation rendered the animals hyperlipidemic by deletion of apolipoprotein E (apo E–/–).^26–27 Apo E–/– mice display lesions of multiple phases of atherosclerosis distributed throughout the arterial tree.²⁸ On normal chow diet, work from the Russell Ross group showed that apo E–/– mice displayed foam cell lesions as early as 8 weeks of age; by age 15 weeks, advanced lesions were evident.²⁸ Advanced lesions consisted of a fibrous cap containing smooth muscle cells surrounded by a connective tissue matrix covering a necrotic core with foamy macrophages.²⁸ On induction of a Western-type diet, lesions generally were more advanced.²⁸

Based on the observation that apo E–/– mice developed complex lesions characteristic of advanced human plaques, we sought to test the hypothesis that induction of hyperglycemia in these animals would further accelerate atherosclerosis and lesion complexity. In the first studies, we rendered 6-week-old male apo E–/– mice diabetic with streptozotocin.²⁹ These apo E–/– mice were previously backcrossed >10 generations into C57BL/6. After 6 weeks of established diabetes, at age 13 to 14 weeks, diabetic apoE–/– mice exhibited discrete lesions at major branch points in the thoracic aorta and at the arch of the aorta. In contrast, age-matched euglycemic apoE–/– mice did not display lesions in the proximal aorta.³⁰ Quantitative morphometric analysis revealed 5-fold increase in mean lesion area at the level of the aortic sinus in diabetic apoE–/– mice compared with nondiabetic apoE–/– animals (Figure 1a). Histologic analysis of euglycemic apoE–/– mice revealed typical fatty streaks visualized with oil red O. At this age, the majority of lesions in the nondiabetic animals did not progress to advanced stages. However, in age-matched diabetic apoE–/– mice, larger, more advanced fibrous plaques with a propensity for cap formation were observed (Figure 1b).³⁰ Lesion complexity was defined by the presence of cholesterol clefts, necrosis, or fibrous cap formation.³⁰

View larger version (28K): [in this window] [in a new window]   Figure 1. Blockade of RAGE suppresses accelerated atherosclerosis in diabetic apo E–/– mice: early intervention. Apo E–/– mice were either rendered diabetic with streptozotocin or treated with citrate buffer (control). In diabetic mice, animals were treated with once daily vehicle, murine serum albumin (MSA), or different daily doses of sRAGE. After 6 weeks of diabetes or control treatment, the heart and aorta were dissected. The impact of RAGE blockade on lesion area (a) and complexity (b) is shown.

In this model, diabetes was followed by a time-dependent increase in plasma total cholesterol.³⁰ After 6 weeks of diabetes, 2-fold increase in cholesterol was noted in diabetic apoE–/– mice compared with nondiabetic animals, whereas plasma triglyceride levels were unchanged. Fractionation of plasma cholesterol by density gradient ultracentrifugation revealed significant increases in chylomicrons/very-low-density lipoprotein (2.6-fold) and intermediate-density lipoprotein/low-density lipoprotein (LDL) (2.5-fold) in age-matched diabetic versus euglycemic apoE–/– mice, whereas HDL was more modestly altered (1.5-fold higher in diabetic compared with control mice).³⁰ In contrast, density gradient ultracentrifugation showed minimal to no differences in plasma triglyceride profile.³⁰

In parallel with elevation of glucose, enhanced formation of AGEs in diabetic apoE–/– mice was shown by 2.3-fold increase in AGE-immunoreactive epitopes in acid-soluble material extracted from kidney tissue after 6 weeks of diabetes, compared with euglycemic apo E–/– controls and 2.5-fold increase in plasma AGEs in diabetic apoE–/– mice compared with nondiabetic control mice.³⁰ Further studies revealed that aortic lysates retrieved from diabetic apo E–/– mice displayed increased levels of the proinflammatory RAGE ligand family, S100/calgranulin epitopes, compared with nondiabetic apo E–/– mice of the same age.³¹

It is of interest that although Kunjathoor et al did not find substantial atherosclerosis in diabetic (streptozotocin) C57BL/6 mice,²⁵ the trigger to atherosclerosis, dietary-induced hyperlipidemia, differed from the means to induce hyperlipidemia in apoE–/– mice. These findings highlight the concept that in addition to genetic background, other influences, such as the degree and nature of the lipid elevation, may importantly influence the development and progression of atherosclerosis in diabetes.

Accelerated Diabetic Atherosclerosis: The Role of RAGE
Consequent to the development of the streptozotocin–apo E–/– model of complex accelerated atherosclerosis in murine diabetes, the impact of blockade of RAGE was tested. In the first studies, murine-soluble RAGE (sRAGE), the extracellular two-thirds of the receptor that functions to bind ligand and thereby block interaction with and activation of cell surface RAGE, was used.³² Soluble RAGE was administered once daily by intraperitoneal route to diabetic apo E–/– mice, commencing immediately at the time hyperglycemia developed. Compared with diabetic mice receiving mouse serum albumin (MSA), diabetic apo E–/– mice treated with sRAGE showed dose-dependent suppression of accelerated atherosclerosis (Figure 1a and 1b, respectively). In addition to diminished atherosclerotic lesion area, lesion complexity was decreased in sRAGE-treated diabetic mice.³⁰ This facet of the impact of RAGE blockade suggested that antagonism of this axis bore the potential to suppress lesion progression and, possibly, the development of highly inflamed unstable plaques.

Importantly, treatment of diabetic mice with sRAGE did not affect the degree of hyperglycemia or the level of insulinemia compared with diabetic mice treated with murine serum albumin. Total cholesterol and triglyceride were similarly unaffected by treatment with sRAGE, and lipid particle composition was also not changed in diabetic sRAGE-treated apoE–/– mice compared with mice receiving murine serum albumin.³⁰ These data suggested that the beneficial effects of blockade of RAGE were both glycemia-independent and lipid-independent, indicating that factors unique to the diabetic environment were favorably modulated. In this context, we speculate that hyperglycemia and hyperlipidemia fuel the generation of AGEs; thus, sRAGE exerts its impact downstream of the traditional risk factors.

Consistent with this premise, levels of kidney and plasma AGE in diabetic mice were suppressed to levels seen in nondiabetic animals by administration of sRAGE in a dose-dependent manner. Similar results were seen on examination of plasma AGEs.³⁰ These findings support the contention that triggers to AGE formation might also be suppressed by RAGE blockade. To begin to address this, LDL was isolated from sRAGE-treated and murine serum albumin-treated mice. Susceptibility to copper-induced oxidation of LDL³³ retrieved from sRAGE-treated diabetic apoE–/– mice was diminished compared with diabetic mice treated with murine serum albumin, as assessed by the mean lag time to formation of conjugated dienes.³⁰

Blockade of RAGE: Late Intervention
To determine the potential impact of RAGE blockade in established atherosclerotic lesions, the streptozotocin-induced diabetes apo E–/– model was used.³⁴ Mice were rendered diabetic with streptozotocin at age 6 weeks and left untreated until age 14 weeks. At age 14 weeks, certain diabetic apo E–/– mice were euthanized to establish the "baseline" atherosclerotic lesion area/complexity. Induction of diabetes was associated with increased atherosclerotic lesion area compared with nondiabetic controls at age 14 and 20 weeks (Figure 2b and 2a and 2d and 2c, respectively). In diabetic mice treated with sRAGE from ages 14 to 20 weeks, atherosclerotic lesion area was significantly reduced compared with mice treated with murine serum albumin (Figure 2e and 2d, respectively). Oil red O-stained cross-sections of the aorta through the aortic sinus revealed that compared with nondiabetic mice, diabetic mice displayed larger and more extensive atherosclerotic lesions at 14 weeks (Figure 2f and 2g, respectively) and 20 weeks (Figure 2h and 2i, respectively). In diabetic mice treated with sRAGE, atherosclerotic lesions were smaller than those observed in vehicle-treated diabetic mice at age 20 weeks (Figure 2j and 2i, respectively).

View larger version (50K): [in this window] [in a new window]   Figure 2. Blockade of RAGE suppresses accelerated atherosclerosis in diabetic apo E–/– mice: late intervention. Apo E–/– mice were rendered hyperglycemic using streptozotocin or were treated with citrate buffer at age 6 weeks. At age 14 weeks, mice were treated with sRAGE, 100 µg per day, or murine serum albumin (MSA). Mice were euthanized at age 20 weeks and the aortae dissected and photographed (a to e). In other studies, sections at the aortic root were prepared and stained with oil red O (f to j). Scale bar: a to e, 0.3 cm; f to j, 125 µm.

Quantitative morphometric analysis was performed and confirmed that diabetic mice treated with sRAGE at 20 weeks displayed a significant decrease in mean atherosclerotic lesion area compared with murine serum albumin-treated diabetic animals (Figure 3a). Although mean lesion area was increased in diabetic mice at 20 weeks versus 14 weeks, mean lesion area in sRAGE-treated diabetic mice at 20 weeks was not significantly different than that observed in diabetic mice at 14 weeks (Figure 3a).³⁴ In addition, at age 20 weeks, mean lesion area in sRAGE-treated diabetic mice was significantly reduced compared with lesions in nondiabetic animals of the same age (Figure 3a).³⁴

View larger version (20K): [in this window] [in a new window]   Figure 3. Blockade of RAGE suppresses established atherosclerosis in diabetic apo E–/– mice: lesion area and complexity. Quantification of mean atherosclerotic lesion area (a) and mean number of complex lesions per section (b) were determined.

Furthermore, we examined lesion complexity (as defined, fibrous caps, cholesterol caps, or lesion necrosis)³⁰ in these animals. In diabetic mice treated with sRAGE from age 14 weeks to 20 weeks, the mean number of complex lesions was significantly reduced compared with diabetic animals treated with murine serum albumin, and lesion complexity was not significantly different in sRAGE-treated diabetic mice at 20 weeks compared with diabetic mice at age 14 weeks (Figure 3b).³⁴ A trend toward decreased lesion complexity was observed in sRAGE-treated diabetic mice at age 20 weeks compared with nondiabetic animals of the same age, although the results did not achieve statistical significance (Figure 3b).³⁴ In parallel with stabilization of atherosclerotic lesion area and complexity, RAGE blockade was associated with decreased vascular expression of vascular cell adhesion molecule-1, JE-monocyte chemoattractant peptide-1, cyclooxygenase-2, nitrotyrosine epitopes, matrix metalloproteinase-9 (antigen and activity), and tissue factor epitopes (Figure 3b).³⁴

In addition to biochemical and molecular pathways linked to atherosclerosis, we examined collagen content within the atherosclerotic plaques using Picrosirius red staining and polarized light microscopy. Diabetes was associated with a significant increase in extent of collagen per lesion in diabetic mice versus nondiabetic controls at 20 weeks of age. In the presence of RAGE blockade, a significant decrease in collagen content per lesion was noted compared with that seen in diabetic mice treated with murine serum albumin.³⁴ The extent of collagen deposition in diabetic sRAGE-treated mice was not significantly different than that observed in nondiabetic animals of the same age or diabetic mice at age 14 weeks.³⁴ We propose that in diabetes, increased numbers of smooth muscle cells and collagen content in diabetic atherosclerotic plaques, the significant increase in numbers of mononuclear phagocytes, and the striking enhancement of proinflammatory mechanisms within the lesions tips the balance between inflammation and lesion stability. Furthermore, especially in diabetic lesions, increased matrix metalloproteinase expression/activity and generation of tissue factor antigen within the plaques enhances the likelihood of plaque progression and instability.

Certainly, these concepts require further testing in distinct species such as pigs or nonhuman primates to address the potential role of RAGE blockade in suppressing plaque instability.

Diabetes and Atherosclerosis: Other Models to Test the Impact of RAGE
It is important to note that the effects of RAGE blockade on atherosclerosis were not limited to apo E–/– mice. An additional murine model was used to trigger basal hypercholesterolemia on which to superimpose hyperglycemic stress. When mice deficient in the LDL receptor were rendered diabetic and fed a diet of normal chow, not enriched in fat, increased atherosclerotic lesion area ensued. On administration of sRAGE, accelerated atherosclerosis was attenuated.³⁵ These findings were in contradistinction to the work of Reavan et al. These investigators found that induction of diabetes by streptozotocin in LDL receptor–/– mice fed a high-fat diet over an extended time course did not result in acceleration of atherosclerosis.³⁶ We posit that the differences between these 2 study outcomes may be ascribed, at least in part, to the premise that at the aortic root, the degree of atherosclerosis that may be achieved is finite. Thus, especially over long time courses in Western diet-fed mice, differences between diabetic and nondiabetic groups may become less apparent as atherosclerosis in the nondiabetic animals continues to progress.

Furthermore, we recently extended these concepts to murine models of insulin-resistant, type 2 diabetes. To accomplish this, we bred apo E–/– mice into the db/db background. These animals, deficient in leptin receptor signaling, display striking hyperinsulinemia, hyperglycemia, and obesity. Compared with nondiabetic apo E–/– littermates, apo E–/–/db/db mice displayed increased atherosclerosis, which was decreased on daily administration of sRAGE.³⁷

Diabetes, Atherosclerosis, and Hyperlipidemic Mice: Effect of Distinct Interventions
The murine models of streptozotocin-induced diabetic apo E and LDL receptor–/– mice have also been used by other investigators to test the impact of distinct pathways and interventions. For example, Lin et al showed that dietary restriction of glycotoxins provides anti-atherogenic protection in streptozotocin-treated apo E–/– mice; these findings provide further support for the AGE hypothesis in vascular injury. In the AGE-restricted group of diabetic apo E–/– mice, immunohistochemistry revealed decreased accumulation of AGEs and AGE receptors including RAGE, in parallel with reduced numbers of inflammatory cells and expression of tissue factor, vascular cell adhesion molecule-1, and JE-monocyte chemoattractant peptide-1 in the vascular lesions.³⁸ Levi et al have shown that treatment of diabetic LDL receptor–/– mice with peroxisome proliferator-activated gamma agonists such as rosiglitazone attenuates atherosclerosis in these animals, without impacting on levels of blood glucose.³⁹ The role of angiotensin-converting enzyme was studied by Candido et al; these investigators showed that administration of perindopril for 20 weeks prevented diabetes-associated atherosclerosis in parallel with reduced aortic expression of angiotensin-converting enzyme, connective tissue growth factor, and vascular cell adhesion molecule-1 overexpression.⁴⁰ In other studies, Tse et al tested the impact of 17 ß-estradiol in diabetic male apo E–/– mice and demonstrated that chronic treatment with 17 ß-estradiol reduced lesion area in multiple vascular segments of these mice, in parallel with decreased blood glucose and levels of triglyceride.⁴¹

Thus, taken together, such mouse models of diabetic atherosclerosis provide a template for dissection of molecular pathways linked to the pathogenesis of macrovascular complications of diabetes and, also, the potential impact of therapeutic interventions.

Diabetes and the Problem of Restenosis
Epidemiologic studies indicate that in human subjects with diabetes, exaggerated restenosis commonly accompanies acute arterial injury, such as that induced by therapeutic angioplasty.^42–44 Studies further demonstrated that stenting of the treated vessel does not offer full protection from restenosis and coronary events.^42,43 Even with the recent development of sirolimus-coated stents, it is not yet clear if diabetic subjects will fully benefit from this novel therapy.^45–47

To dissect the biochemical and molecular events linked to enhanced restenosis in diabetic human subjects, it was first necessary to establish animal models to readily address these concepts.

Studies in Rats
The first studies using diabetic rats were performed in obese Zucker rats displaying type 2 insulin-resistant diabetes.⁴⁸ Interestingly, compared with induction of diabetes (type 1) in Sprague-Dawley rats by streptozotocin in which neointimal hyperplasia was not exaggerated, Park et al showed that obese Zucker rats subjected to carotid balloon injury displayed a >2-fold increase in neointimal area compared with lean Zucker (nondiabetic) rats on day 21 after injury.⁴⁸ In the intima of these animals, cell proliferation markedly increased, commencing at day 3 and persisting through day 14. This animal model was then used to test the role of RAGE blockade. Administration of sRAGE was begun just before arterial injury and was continued through the first week after balloon injury. Compared with vehicle treatment (albumin), sRAGE-treated rats displayed a significant decrease in neointimal expansion.⁴⁹ A key finding in this study was the marked reduction in incorporation of bromodeoxyuridine in the smooth muscle cells of the expanding neointima in sRAGE-treated rats. These experiments strongly suggested that RAGE-expressing smooth muscle cells, at least in part, contributed importantly to diabetes-associated enhanced neointimal expansion after acute injury.

Studies in Murine Models
These findings suggested that it was logical to further dissect the role of RAGE in arterial injury. In rat models, however, the inability to use transgenic/knockout approaches limited this approach. Furthermore, direct studies in murine models would facilitate the testing of genetically RAGE-modified mice, thereby supporting the premise that the chief target of sRAGE was the receptor itself. Thus, to use murine models, acute femoral artery endothelial injury was induced according to a previously-established and validated model.⁵⁰ Guide wire-induced injury to the femoral artery was performed and the impact of both pharmacological and genetic modification of RAGE was tested. RAGE and its ligands, CML-AGEs and S100/calgranulins, were upregulated in the femoral vessel wall after injury, particularly in smooth muscle cells.⁵¹ On day 28 after injury, a dose-dependent decrease in intima/media (I/M) ratio was observed in mice treated with sRAGE versus vehicle (murine serum albumin).⁵¹ Importantly, homozygous RAGE–/– mice displayed decreased I/M ratio on day 28 after injury compared with littermate control animals subjected to arterial denudation (Figure 4a through 4c). Numbers of proliferating smooth muscle cells were significantly reduced in RAGE–/– mice versus controls.⁵¹

View larger version (16K): [in this window] [in a new window]   Figure 4. Homozygous RAGE (0) mice and transgenic mice expressing signaling deficient dominant negative (DN) RAGE in smooth muscle cells display decreased neointimal expansion consequent to acute arterial injury. Homozygous RAGE–/– mice (a to c) and transgenic mice expressing DN RAGE selectively in smooth muscle cells (driven by the SM22 alpha promoter) (d) and wild-type littermates were subjected to femoral artery guide wire injury. Intima/media ratio was determined on day 28 after injury (a, d). Von Gieson elastic stain was performed on a representative femoral artery section from a wild-type RAGE-bearing (b) and a RAGE–/– mouse (c). Scale bar: 50 µm.

As homozygous RAGE–/– mice do not express RAGE in any cell type, an additional strategy was used to specifically dissect the role of smooth muscle cell RAGE in modulating neointimal expansion on acute arterial injury. Previous studies showed that deletion of the cytosolic domain of RAGE imparted a dominant-negative (DN) effect; when wild-type RAGE-bearing vascular or mononuclear phagocyte-like cells were transfected with constructs encoding DN RAGE, a DN effect ensued on incubation with RAGE ligands such as S100B or CML-AGE.^3,9 Because smooth muscle cells were the principal RAGE-expressing cells in the expanding neointima,⁵¹ these concepts were tested in transgenic mice expressing DN RAGE specifically in smooth muscle cells driven by the SM22 promoter. Compared with wild-type littermates, transgenic SM22 DN RAGE mice subjected to arterial injury displayed a significant decrease in I/M ratio on day 28 (Figure 4d). Thus, these experiments provided further support for roles for RAGE in neointimal expansion. In addition to pharmacological blockade of RAGE, genetically modified RAGE mice (deletion or interruption of smooth muscle cell signal transduction) displayed decreased injury-triggered neointimal expansion.

However, a limitation of inducing arterial injury in C57BL/6 mice is that there is little evidence of inflammatory cell influx into the injured vessel wall in wild-type animals. To address this concept, femoral artery injury was induced in apo E–/– mice based on the premise that basal vascular perturbation secondary to hyperlipidemia would augment the response to arterial injury, including migration of inflammatory cells. We found that I/M ratios were higher, reflecting enhanced neointimal expansion in apo E–/– mice vessels 28 days after injury versus C57BL/6 mice (2-fold higher I/M ratio).⁵¹ In euglycemic apo E–/– mice, administration of sRAGE diminished I/M ratio on day 28. In parallel, numbers of mononuclear phagocytes infiltrating the injured artery were also reduced.⁵¹ Thus, apo E–/– mice may provide a superior system to test the role of smooth muscle cell and mononuclear phagocyte RAGE in the response to acute arterial injury.

In addition, these studies highlighted the role of RAGE-dependent Jak/Stat signaling in smooth muscle cells. In femoral vessels after injury, although increased phosphorylation of ERK 1/2, protein kinase B (akt), and Jak2/Stat3 were observed versus sham treatment, sRAGE appeared to only exert its effects on Jak2/Stat3 signaling.⁵¹

Diabetes and Restenosis: Other Models and Distinct Interventions
Diabetic rodent models of arterial injury have also been tested for the impact of distinct interventions on neointimal expansion. Phillips et al used Western diet-fed apo E–/– mice to show that these mice develop insulin-resistant diabetes; administration of rosiglitazone prevented the development of hyperglycemia and hyperinsulinemia.⁵² In parallel, neointimal expansion was reduced by 65% after arterial injury in Peroxisome proliferator-activated gamma agonist (rosiglitazone) versus vehicle-fed apo E–/– mice. Macrophage infiltration into the expanding neointima was also reduced by this intervention.⁵² Note that these studies are in contradistinction to those of Levi et al³⁹ with respect to the effect of rosiglitazone on hyperglycemia. Specifically, in Levi’s studies, apo E–/– mice were made frankly diabetic by relative deficiency of insulin using streptozotocin;³⁹ in the Phillips studies, hyperglycemia was induced by feeding Western diet, thereby causing insulin resistance.⁵⁴

In other studies, Min et al administered troglitazone to Otsuka Long-Evans Tokushima fatty rats and found that smooth muscle cell proliferation was markedly reduced, in parallel with decreased neointimal expansion after carotid balloon injury.⁵³ The role of dietary glycotoxins (AGEs) on neointimal expansion was directly tested in apo E–/– mice by Lin et al. Mice were randomized to high-AGE or low-AGE diet (the latter with 10-fold lower AGE content) and subjected to femoral artery injury. In parallel with decreased neointimal expansion in the low-AGE diet-fed mice, AGE content was reduced in the injured vessel wall.⁵⁴

The complex nature of murine/rodent models in dissection of the biologic response to arterial injury superimposed on chronic hyperglycemia was underscored by the studies of Stephenson et al.⁵⁵ These investigators reported that db/db mice displayed markedly decreased neointimal expansion consequent to femoral artery endoluminal wire injury compared with wild-type controls.⁵⁵ Four hours after acute arterial injury, medial smooth muscle death was reduced in db/db versus wild-type mice. However, smooth muscle cell proliferation did not appear to differ between db/db versus wild-type mice.⁵⁵ These findings suggest important roles for leptin in modulation of stimulated smooth muscle cell properties. Oda et al reported that leptin stimulated phosphorylation and activation of MAP kinase and phosphatidylinositol 3-kinase activity in cultured smooth muscle cell; one consequence of which was increased smooth muscle cell proliferation and migration.⁵⁶ Taken together, these considerations underscore the complexity of these model systems and suggest that preclinical testing of novel therapeutic targets in restenosis ultimately requires the use of species such as pigs, rabbits, or nonhuman primates before testing in human subjects.^57,58

	Conclusions

Top Abstract Introduction Conclusions References

 
The ultimate goal of our studies is to determine the potential role of RAGE blockade as a therapeutic strategy in the macrovascular complications of diabetes. Thus, the development of key models to test the role of the receptor in a time-specific and cell-specific manner has provided a template for in-depth dissection of the role of RAGE in vascular pathology. The finding that blockade of RAGE affords benefit in mice bearing both insulin-deficient and insulin-resistant diabetes further supports the role of this receptor in hyperglycemic states. These considerations underscore the concept that the products of the downstream effects of high glucose and oxidant stress generate species that are signal transduction ligands of the receptor.

It is important to stress that RAGE-dependent mechanisms in vascular stimulation are not limited to diabetes. As the vasculature in euglycemic atherosclerotic plaques is also susceptible to oxidant stress, inflammation, and, thus, generation of AGEs, albeit to lesser degrees, it was logical to test the impact of RAGE blockade. Thus, it was not surprising that administration of sRAGE to euglycemic apo E–/– mice from ages 14 to 20 weeks attenuated atherosclerotic lesion area and complexity, without an impact on lipid levels.³⁴

In conclusion, these findings underscore the usefulness of rodent, and particularly mouse, models in dissection of the mechanisms linking RAGE to accelerated atherosclerosis and restenosis, particularly in diabetes. Propelled by compelling data in animal models, we propose that testing of RAGE blockade in a multi-targeted approach in diabetes may lead to a successful reduction of the macrovascular complications of types 1 and 2 diabetes. Clinical trials to address these issues in human subjects are on the horizon.

	Acknowledgments

 
Acknowledgments

These studies were supported by the Surgical Research Fund of the Department of Surgery, and grants from the USPHS, American Heart Association, LeDucq Foundation, and the Juvenile Diabetes Research Foundation International (JDRFI). R.R. is a recipient of the Established Investigator Award from the American Heart Association. A.M.S. is a recipient of a Burroughs Wellcome Fund Clinical Scientist Award in Translational Research.

Received December 23, 2003; accepted May 10, 2004.

	References

Top Abstract Introduction Conclusions References

 

1. Schmidt AM, Vianna M, Gerlach M, Brett J, Ryan J, Kao J, Esposito C, Hegarty H, Hurley W, Clauss M, Wang F, Pan YC, Tsang TC, Stern D. Isolation and characterization of binding proteins for advanced glycosylation end products from lung tissue which are present on the endothelial cell surface. J Biol Chem. 1992; 267: 14987–14997.[Abstract/Free Full Text]
2. Neeper M, Schmidt AM, Brett J, Yan SD, Wang F, Pan YC, Elliston K, Stern D, Shaw A. Cloning and expression of RAGE: a cell surface receptor for advanced glycosylation end products of proteins. J Biol Chem. 1992; 267: 14998–15004.[Abstract/Free Full Text]
3. Hofmann MA, Drury S, Fu C, Qu W, Taguchi A, Lu Y, Avila C, Kambham N, Bierhaus A, Nawroth P, Neurath MF, Slattery T, Beach D, McClary J, Nagashima M, Morser J, Stern D, Schmidt AM. RAGE mediates a novel proinflammatory axis: a central cell surface receptor for S100/calgranulin polypeptides. Cell. 1999; 97: 889–901.[CrossRef][Medline] [Order article via Infotrieve]
4. Hori O, Brett J, Slattery T, Cao R, Zhang J, Chen J, Nagashima M, Nitecki D, Morser J, Stern D, Schmidt AM. RAGE is a cellular binding site for amphoterin: mediation of neurite outgrowth and co-expression of RAGE and amphoterin in the developing nervous system. J Biol Chem. 1995; 270: 25752–25761.[Abstract/Free Full Text]
5. Taguchi A, Blood DC, del Toro G, Canet A, Lee DC, Qu W, Tanji N, Lu Y, Lalla E, Fu C, Hofmann MA, Kislinger T, Ingram M, Lu A, Tanaka H, Hori O, Ogawa S, Stern DM, Schmidt AM. Blockade of amphoterin/RAGE signaling suppresses tumor growth and metastases. Nature. 2000; 405: 354–360.[CrossRef][Medline] [Order article via Infotrieve]
6. Yan SD, Chen X, Fu J, Chen M, Zhu H, Roher A, Slattery T, Nagashima M, Morser J, Migheli A, Nawroth P, Godman G, Stern D, Schmidt AM. RAGE and amyloid-ß peptide neurotoxicity in Alzheimer’s disease. Nature. 1996; 382: 685–691.[CrossRef][Medline] [Order article via Infotrieve]
7. Yan SD, Zhu H, Zhu A, Golabek A, Du H, Roher A, Yu J, Soto C, Schmidt AM, Stern D, Kindy M. Receptor-dependent cell stress and amyloid accumulation in systemic amyloidosis. Nature Medicine. 2000; 6: 643–651.[CrossRef][Medline] [Order article via Infotrieve]
8. Chavakis T, Bierhaus A, Al-Fakhri N, Schneider D, Witte S, Linn T, Nagashima M, Morser J, Arnold B, Preissner KT, Nawroth PP. The Pattern Recognition Receptor (RAGE) is a counterreceptor for leukocyte integrins: a novel pathway for inflammatory cell recruitment. J Exp Med. 2003; 198: 1507–1515.[Abstract/Free Full Text]
9. Kislinger T, Fu C, Huber B, Qu W, Taguchi A, Yan SD, Hofmann M, Yan SF, Pischetsrider M, Stern D, Schmidt AM. N (carboxymethyl)lysine modifications of proteins are ligands for RAGE that activate cell signaling pathways and modulate gene expression. J Biol Chem. 1999; 274: 31740–31749.[Abstract/Free Full Text]
10. Anderson MM, Requena JR, Crowley JR, Thorpe SR, Heinecke J. The myeloperoxidase system of human phagocytes generates N-(carboxymethyl)lysine on proteins: a mechanism for producing advanced glycation end products at sites of inflammation. J Clin Invest. 1999; 104: 103–113.[Medline] [Order article via Infotrieve]
11. Nagai R, Unno Y, Hayashi MC, Masuda S, Hayase F, Kinae N, Horiuchi S. Peroxynitrite induces formation of N()-(carboxymethyl)lysine by the cleavage of Amadori product and generation of glucosone and glyoxal from glucose: novel pathways for protein modification by peroxynitrite. Diabetes. 2002; 51: 2833–2839.[Abstract/Free Full Text]
12. Brownlee M. Glycation products and the pathogenesis of diabetic complications. Diabetes Care. 1992; 1835–1843.
13. Niwa T. 3-deoxyglucosone metabolism, analysis, biological activity, and clinical implication. J Chromat Biomed Sci Appl. 1999; 731: 23–36.[CrossRef][Medline] [Order article via Infotrieve]
14. Hasuike Y, Nakanishi T, Otaki Y, Nanami M, Tanimoto T, Taniguchi N, Takamitsu Y. Plasma 3-deoxyglucosone elevation in chronic renal failure is associated with increased aldose reductase in erythrocytes. Am J Kid Dis. 2002; 40: 464–471.[CrossRef][Medline] [Order article via Infotrieve]
15. Hamada Y, Nakamura J, Naurse K, Komori T, Kato K, Kasuya Y, Nagai R, Hotta N. Epalrestat, an aldose reductase inhibitor, reduces the levels of CML protein adducts and their precursors in erythrocytes from diabetic patients. Diabetes Care. 2000; 23: 1539–1544.[Abstract]
16. Wang H, Bloom O, Zhang M, Vishnuhakat JM, Ombrellino M, Che J, Frazier A, Yang H, Ivanova S, Borovikova L, Manogue KR, Faist E, Abraham E, Andersson J, Andersson U, Molina PE, Abumrad NN, Sama A, Tracey KJ. HMG-1 as a late mediator of endotoxin lethality in mice. Science. 1999; 285: 248–251.[Abstract/Free Full Text]
17. Rammes A, Roth J, Goebeler M, Klempt M, Hartmann M, Sorg C. Myeloid-related protein (MRP) 8 and MRP14, calcium-binding proteins of the S100 family, are secreted by activated monocytes via a novel, tubulin-dependent pathway. J Biol Chem. 1997; 272: 9496–9502.[Abstract/Free Full Text]
18. Frosch M, Strey A, Vogl T, Wulffraat NM, Kuis W, Sunderkotter C, Harms E, Sorg C, Roth J. Myeloid-related proteins 8 and 14 are specifically secreted during interaction of phagocytes and activated endothelium and are useful markers for monitoring disease activity in pauciarticular-onset juvenile rheumatoid arthritis. Arthritis Rheum. 2000; 43: 628–637.[CrossRef][Medline] [Order article via Infotrieve]
19. King H, Aubert R, Herman W. Global burden of diabetes, 1995–2005. Prevalence, numerical estimates and projections. Diabetes Care. 1998; 21: 1414–1431.[Abstract]
20. Uusitupa MI, Niskanen LK, Siitonen O, Voutilainen E, Pyorala K. Five-year incidence of atherosclerotic vascular disease in relation to general risk factors, insulin level, and abnormalities in lipoprotein composition in non-insulin-dependent diabetic and non-diabetic subjects. Circ. 1990; 82: 27–36.[Abstract/Free Full Text]
21. Manson JE, Colditz GA, Stampfer MJ, Willett WC, Krolewski AS, Rosner B, Arky RA, Speizer FE, Hennekens CH. A prospective study of maturity-onset diabetes mellitus and risk of coronary heart disease and stroke in women. Arch Intern Med. 1991; 151: 1141–1147.[Abstract]
22. Kannel WB, McGee DL. Diabetes and cardiovascular disease: The Framingham Study. JAMA. 1979; 241: 2035–2038.[Abstract]
23. Ritthaler U, Deng Y, Zhang Y, Greten J, Abel M, Allenberg J, Otto G, Roth H, Bierhaus A, Ziegler R, Schmidt AM, Waldherr R, Wahl P, Stern D, Nawroth P. Expression of receptors for advanced glycation end products in peripheral occlusive vascular disease. Am J Pathol. 1995; 146: 688–694.[Abstract]
24. Cipollone F, Iezzi A, Fazia M, Zucchelli M, Pini B, Cuccurullo C, De Cesare D, De Blasis G, Muraro R, Bei R, Chiarelli F, Schmidt AM, Cuccurullo F, Mezzetti A. The Receptor RAGE as a progression factor amplifying arachidonate-dependent inflammatory and proteolytic response in human atherosclerotic plaques: role of glycemic control. Circ. 2003; 108: 1070–1077.[Abstract/Free Full Text]
25. Kunjathoor VV, Wilson DL, LeBoeuf RC. Increased atherosclerosis in streptozotocin-induced diabetic mice. J Clin Invest. 1996; 97: 1767–1773.[Medline] [Order article via Infotrieve]
26. Zhang S, Reddick RL, Piedrahita JA, Maeda N. Spontaneous hypercholesterolemia and arterial lesions in mice lacking apolipoprotein E. Science. 1992; 258: 468–471.[Abstract/Free Full Text]
27. Plump AS, Smith JD, Hayek T, Aalto-Setala K, Walsh A, Verstuyft JG, Rubin EM, Breslow JL. Severe hypercholesterolemia and atherosclerosis in apolipoprotein E-deficient mice created by homologous recombination in ES cells. Cell. 1992; 71: 343–353.[CrossRef][Medline] [Order article via Infotrieve]
28. Nakashima Y, Plump AS, Raines EW, Breslow JL, Ross R. ApoE-deficient mice develop lesions of all phases of atherosclerosis throughout the arterial tree. Arterioscler Thromb. 1994; 14: 133–140.[Abstract/Free Full Text]
29. Like AA, Rossini AA. Streptozotocin-induced pancreatic insulitis: new model of diabetes mellitus. Science. 1976; 193: 415–417.[Abstract/Free Full Text]
30. Park L, Raman KG, Lee KJ, Yan L, Ferran LJ, Chow WS, Stern D, Schmidt AM. Suppression of accelerated diabetic atherosclerosis by soluble Receptor for AGE (sRAGE). Nat Med. 1998; 4: 1025–1031.[CrossRef][Medline] [Order article via Infotrieve]
31. Kislinger T, Tanji N, Wendt T, Qu W, Lu Y, Ferran LJ, Jr., Taguchi A, Olson K, Bucciarelli L, Goova M, Hofmann MA, Cataldegirmen G, D’Agati V, Pischetsrieder M, Stern DM, Schmidt AM. RAGE mediates inflammation and enhanced expression of tissue factor in the vasculature of diabetic apolipoprotein E null mice. Arterio Thromb Vasc Biol. 2001; 21: 905–910.[Abstract/Free Full Text]
32. Wautier JL, Zoukourian C, Chappey O, Wautier MP, Guillausseau PJ, Cao R, Hori O, Stern D, Schmidt AM. Receptor-mediated endothelial cell dysfunction in diabetic vasculopathy: soluble receptor for advanced glycation endproducts blocks hyperpermeability. J Clin Invest. 1996; 97: 238–243.[Medline] [Order article via Infotrieve]
33. Morel DW, Chisolm GM. Antioxidant treatment of diabetic rats inhibits lipoprotein oxidation and cytotoxicity. J Lipid Res. 1989; 30: 1827–1834.[Abstract]
34. Bucciarelli LG, Wendt T, Qu W, Lu Y, Lalla E, Rong LL, Goova MT, Moser B, Kislinger TK, Lee DC, Kashyap Y, Stern DM, Schmidt AM. RAGE blockade stabilizes established atherosclerosis in diabetic apolipoprotein E null mice. Circ. 2002; 106: 2827–2835.[Abstract/Free Full Text]
35. Lee KJ, Lu Y, Ginsberg MD, Ferran LJ, Stern DM, Schmidt AM. A murine model of accelerated atherosclerosis in diabetic LDL Receptor deficient mice. Circ (Suppl). 1997; 96: I-175.
36. Reaven P, Merat S, Casanada F, Sutphin M, Palinski W. Effect of streptozotocin-induced hyperglycemia on lipid profiles, formation of advanced glycation endproducts in lesions, and extent of atherosclerosis in LDL receptor-deficient mice. Arterioscler Thromb Vasc Biol. 1997; 17: 2250–2256.[Abstract/Free Full Text]
37. Wendt TM., Bucciarelli L.G., Lu Y., Qu W., Fan L, Tsai M., Ferran LJ, Stern DM, Schmidt AM. Accelerated atherosclerosis and vascular inflammation develop in apo E null mice with type 2 diabetes. Circ (Suppl). 2000; 102: II-231.
38. Lin RY, Choudhury RP, Cai W, Lu M, Fallon JT, Fisher EA, Vlassara H. Dietary glycotoxins promote diabetic atherosclerosis in apolipoprotein E-deficient mice. Atherosclerosis. 2003; 168: 213–220.[CrossRef][Medline] [Order article via Infotrieve]
39. Levi Z, Shaish A, Yacov N, Levkovitz H, Trestman S, Gerber Y, Cohen H, Dvir A, Rhachmani R, Ravid M, Harats D. Rosiglitazone (PPAR gamma-agonist) attenuates atherogenesis with no effect on hyperglycaemia in a combined diabetes-atherosclerosis mouse model. Diabetes Obes Metab. 2003; 5: 45–50.[CrossRef][Medline] [Order article via Infotrieve]
40. Candido R, Jandeleit-Dahm KA, Cao Z, Nesteroff SP, Burns WC, Twigg SM, Dilley RJ, Cooper ME, Allen TJ. Prevention of accelerated atherosclerosis by angiotensin-converting enzyme inhibition in diabetic apolipoprotein E-deficient mice. Circulation. 2002; 106: 246–253.[Abstract/Free Full Text]
41. Tse J, Martin-McNaulty B, Halks-Miller M, Kauser K, DelVecchio V, Vergona R, Sullivan ME, Rubanyi GM. Accelerated atherosclerosis and premature calcified cartilaginous metaplasia in the aorta of diabetic male apo E knockout mice can be prevented by chronic treatment with 17 ß-estradiol. Atherosclerosis. 1999; 144: 303–313.[CrossRef][Medline] [Order article via Infotrieve]
42. Rosenman Y, Sapoznikov D, Mosseri M, Gilon D, Lotan C, Nassar H, Weiss, AT, Hasin Y, Gotsman MS. Long-term angiographic follow-up of coronary balloon angioplasty in patients with diabetes mellitus: a clue to the explanation of the results of the BARI study (Balloon Angioplasty Revascularization Investigation). J Am Coll Cardiol. 1997; 30: 1420–1425.[Abstract]
43. Abizaid A, Kornowski R, Mintz GS, Hong MK, Abizaid, AS, Mehran, R, Pichard AD, Kent KM, Statler LF, Wu H, Popma JJ, Leon MB. The influence of diabetes mellitus on acute and late clinical outcome following coronary stent implantation. J Am Coll Cardiol. 1998; 32: 584–589.[Abstract/Free Full Text]
44. The Bypass Angioplasty Revascularization Investigation (BARI) Investigators. Comparison of coronary bypass surgery with angioplasty in patients with multivessel disease. N Engl J Med. 1996; 335: 217–225.[Abstract/Free Full Text]
45. Morice MC, Serruys PW, Sousa JE, Fajadet J, Ban Hayashi E, Perin M, Colombo A, Schuler G, Barragan P, Guagliumi G, Molnar F, Falotico R, RAVEL study group. Randomized study with the sirolimus-coated Bx velocity balloon-expandable stent in the treatment of patients with de novo native coronary artery lesions. N Engl J Med. 2002; 346: 1770–1771.[Free Full Text]
46. Moses JW, Leon MB, Popma JJ, Fitzgerald PJ, Holmes DR, O’Shaughnessy C, Caputo RP, Kereiakes DJ, Williams DO, Teirstein PS, Jaeger JL, Kuntz RE; SIRIUS Investigators. Sirolimus-eluting stents versus standard stents in patients with stenosis in a native coronary artery. N Engl J Med. 2003; 349: 1315–1323.[Abstract/Free Full Text]
47. Lemos PA, Saia F, Ligthart JM, Arampatzis CA, Sianos G, Tanabe K, Hoye A, Degertekin M, Daemen J, McFadden E, Hofma S, Smits PC, deFeyter P, van der Giessen WJ, van Domburg RT, Serruys PW. Coronary restenosis after sirolimus-eluting stent implantation: morphological description and mechanistic analysis from a consecutive series of cases. Circ. 2003; 108: 257–160.[Abstract/Free Full Text]
48. Park SH, Marso SP, Zhou Z, Foroudi F, Topol EJ, Lincoff AM. Neointimal hyperplasia after arterial injury is increased in a rat model of non-insulin-dependent diabetes mellitus. Circulation. 2001; 104: 815–819.[Abstract/Free Full Text]
49. Zhou Z, Wang K, Penn MS, Marso SP, Lauer MA, Forudi F, Zhou X, Qu W, Lu Y, Stern DM, Schmidt AM, Lincoff AM, Topol EJ. Receptor for AGE (RAGE) mediates neointimal formation in response to arterial injury. Circulation. 2003; 107: 2238–2243.[Abstract/Free Full Text]
50. Roque M, Fallon JT, Badimon JJ, Zhang WX, Taubman MB, Reis ED. Mouse model of femoral artery denudation injury associated with the rapid accumulation of adhesion molecules on the luminal surface and recruitment of neutrophils. Arterioscler Thromb Vasc Biol. 2000; 20: 335–342.[Abstract/Free Full Text]
51. Sakaguchi T, Yan SF, Yan SD, Rong LL, Sousa M, Belov D, Andrassy M, Marso SP, Duda S, Arnold B, Liliensiek B, Nawroth PP, Stern DM, Schmidt AM, Naka, Y. Arterial restenosis: central role of RAGE-dependent neointimal expansion. J Clin Invest. 2003; 111: 959–972.[CrossRef][Medline] [Order article via Infotrieve]
52. Phillips JW, Barringhaus KG, Sanders JM, Yang Z, Chen M, Hesselbacher S, Czarnik AC, Ley K, Nadler J, Sarembock IJ. Rosiglitazone reduces the accelerated neointima after arterial injury in a mouse injury model of type 2 diabetes. Circulation. 2003; 108: 1994–1999.[Abstract/Free Full Text]
53. Min KM, Park SW, Cho KY, Song MS, Kim DK, Park GS, Lee MK. Troglitazone improves blood flow by inhibiting neointimal formation after balloon injury in Otsuka Long-Evans Tokushima fatty rats. Metabolism. 2002; 51: 998–1002.[CrossRef][Medline] [Order article via Infotrieve]
54. Lin RY, Reis ED, Dore AT, Lu M, Ghodsi N, Fallon JT, Fisher EA, Vlassara H. Lowering of dietary advanced glycation end products (AGE) reduces neointimal formation after arterial injury in genetically hypercholesterolemic mice. Atherosclerosis. 2002; 163: 303–311.[CrossRef][Medline] [Order article via Infotrieve]
55. Stephenson K, Tunstead J, Tsai A, Gordon R, Henderson S, Dansky HM. Neointimal formation after endovascular injury is markedly attenuated in db/db mice. Arterioscler Thromb Vasc Biol. 2003; 23: 2027–2033.[Abstract/Free Full Text]
56. Oda A, Taniguchi T, Yokoyama M. Leptin stimulates rat aortic smooth muscle cell proliferation and migration. Kobe J Med Sci. 2001; 47: 141–150.[Medline] [Order article via Infotrieve]
57. Babapulle MN, Eisenberg MJ. Coated stents for the prevention of restenosis: Part I. Circulation. 2002; 106: 2734–2740.[Free Full Text]
58. Babapulle MN, Eisenberg MJ. Coated stents for the prevention of restenosis: Part II. Circulation. 2002; 106: 2859–2866.[Free Full Text]

This article has been cited by other articles:

				C. Toth, L. L. Rong, C. Yang, J. Martinez, F. Song, N. Ramji, V. Brussee, W. Liu, J. Durand, M. D. Nguyen, et al. Receptor for Advanced Glycation End Products (RAGEs) and Experimental Diabetic Neuropathy Diabetes, April 1, 2008; 57(4): 1002 - 1017. [Abstract] [Full Text] [PDF]

				J. M. Englert, L. E. Hanford, N. Kaminski, J. M. Tobolewski, R. J. Tan, C. L. Fattman, L. Ramsgaard, T. J. Richards, I. Loutaev, P. P. Nawroth, et al. A Role for the Receptor for Advanced Glycation End Products in Idiopathic Pulmonary Fibrosis Am. J. Pathol., March 1, 2008; 172(3): 583 - 591. [Abstract] [Full Text] [PDF]

				G. Marsche, B. Weigle, W. Sattler, and E. Malle Soluble RAGE blocks scavenger receptor CD36-mediated uptake of hypochlorite-modified low-density lipoprotein FASEB J, October 1, 2007; 21(12): 3075 - 3082. [Abstract] [Full Text] [PDF]

				A. C. Brisset, H. Hao, E. Camenzind, M. Bacchetta, A. Geinoz, J.-C. Sanchez, C. Chaponnier, G. Gabbiani, and M.-L. Bochaton-Piallat Intimal Smooth Muscle Cells of Porcine and Human Coronary Artery Express S100A4, a Marker of the Rhomboid Phenotype In Vitro Circ. Res., April 13, 2007; 100(7): 1055 - 1062. [Abstract] [Full Text] [PDF]

				G. Marsche, M. Semlitsch, A. Hammer, S. Frank, B. Weigle, N. Demling, K. Schmidt, W. Windischhofer, G. Waeg, W. Sattler, et al. Hypochlorite-modified albumin colocalizes with RAGE in the artery wall and promotes MCP-1 expression via the RAGE-Erk1/2 MAP-kinase pathway FASEB J, April 1, 2007; 21(4): 1145 - 1152. [Abstract] [Full Text] [PDF]

				J. L. Figarola, N. Shanmugam, R. Natarajan, and S. Rahbar Anti-Inflammatory Effects of the Advanced Glycation End Product Inhibitor LR-90 in Human Monocytes Diabetes, March 1, 2007; 56(3): 647 - 655. [Abstract] [Full Text] [PDF]

				D. L. Basi, N. Adhikari, A. Mariash, Q. Li, E. Kao, S. V. Mullegama, and J. L. Hall Femoral artery neointimal hyperplasia is reduced after wire injury in Ref-1+/- mice Am J Physiol Heart Circ Physiol, January 1, 2007; 292(1): H516 - H521. [Abstract] [Full Text] [PDF]

H. Roy, S. Bhardwaj, M. Babu, I. Kokina, S. Uotila, T. Ahtialansaari, T. Laitinen, J. Hakumaki, M. Laakso, K.-H. Herzig, et al. VEGF-A, VEGF-D, VEGF receptor-1, VEGF receptor-2, NF-{kappa}B, and RAGE in atherosclerotic lesions of diabetic Watanabe heritable hyperlipidemic rabbits FASEB J, October 1, 2006; 20(12): 2159 - 2161. [Abstract] [Full Text] [PDF]