Diabetic Nephropathy - Pathology
Advanced Glycemic End products (AGEs) -
updated: 15 March 2008
Role of advanced glycation end products in diabetic nephropathy
J Am Soc Nephrol. 2003 Aug;14(8 Suppl 3):S254-8
Forbes JM, Cooper ME, Oldfield MD, Thomas MC.
Nonenzymatic reactions between sugars and the free amino groups on proteins, lipids, and nucleic acids result in molecular dysfunction through the formation of advanced glycation end products (AGE). AGE have a wide range of chemical, cellular, and tissue effects through changes in charge, solubility, and conformation that characterize molecular senescence. AGE also interact with specific receptors and binding proteins to influence the expression of growth factors and cytokines, including TGF-beta1 and CTGF, thereby regulating the growth and proliferation of the various renal cell types. It seems that many of the pathogenic changes that occur in diabetic nephropathy may be induced by AGE. Drugs that either inhibit the formation of AGE or break AGE-induced cross-links have been shown to be renoprotective in experimental models of diabetic nephropathy. AGE are able to stimulate directly the production of extracellular matrix and inhibit its degradation. AGE modification of matrix proteins is also able to disrupt matrix-matrix and matrix-cell interactions, contributing to their profibrotic action. In addition, AGE significantly interact with the renin-angiotensin system. Recent studies have suggested that angiotensin-converting enzyme inhibitors are able to reduce the accumulation of AGE in diabetes, possibly via the inhibition of oxidative stress. This interaction may be a particularly important pathway for the development of AGE-induced damage, as it also can be attenuated by antioxidant therapy. In addition to being a consequence of oxidative stress, it is now clear that AGE can promote the generation of reactive oxygen species. It is likely that therapies that inhibit the formation of AGE will form an important part of future therapy in patients with diabetes, acting synergistically with conventional approaches to prevent diabetic renal injury.
Publication Types:
Online - Article
AGE, RAGE, and ROS in diabetic nephropathy
Semin Nephrol. 2007 Mar;27(2):130-43
Tan AL, Forbes JM, Cooper ME.
Diabetic nephropathy is a major cause of morbidity and mortality in diabetic patients. Two key mechanisms implicated in the development of diabetic nephropathy include advanced glycation and oxidative stress. Advanced glycation is the irreversible attachment of reducing sugars onto amino groups of proteins to form advanced glycation end products (AGEs). AGE modification of proteins may lead to alterations in normal function by inducing cross-linking of extracellular matrices. Intracellular formation of AGEs also can cause generalized cellular dysfunction. Furthermore, AGEs can mediate their effects via specific receptors, such as the receptor for AGE (RAGE), activating diverse signal transduction cascades and downstream pathways, including generation of reactive oxygen species (ROS). Oxidative stress occurs as a result of the imbalance between ROS production and antioxidant defenses. Sources of ROS include the mitochondria, auto-oxidation of glucose, and enzymatic pathways including nicotinamide adenine dinucleotide phosphate reduced (NAD[P]H) oxidase. Beyond the current treatments to treat diabetic complications such as the optimization of blood pressure and glycemic control, it is predicted that new therapies designed to target AGEs, including AGE formation inhibitors and cross-link breakers, as well as targeting ROS using novel highly specific antioxidants, will become part of the treatment regimen for diabetic renal disease.
Publication Types:
Online - Abstract
AGE-RAGE and AGE Cross-link interaction: important players in the pathogenesis of diabetic kidney disease
Horm Metab Res. 2005 Apr;37 Suppl 1:26-34
Jensen LJ, Østergaard J, Flyvbjerg A.
At present, diabetic kidney disease affects about 15 - 25% of all type 1 diabetic patients and 20 - 40% of all patients with type 2 diabetes. The mechanisms underlying the development of diabetic kidney disease are extremely complex and not yet fully understood. Among the many potential pathogenic mechanisms responsible for the progression in diabetic kidney disease, the involvement of metabolic factors beyond blood glucose (such as advanced glycation end products (AGEs)) has been suggested. This review will present the emerging evidence in support of a significant role of AGE formation in the development of diabetic kidney disease. AGEs mediate their effects through two main pathways - through a receptor-independent AGE cross-link formation pathway and through a receptor-dependent pathway where AGEs bind to specific cell surface associated receptors, the receptor for AGE (RAGE) being the most well-characterised so far. First, we will describe the AGE-RAGE system, including its localisation in the normal kidney, and then move on to discuss in vitro and in vivo studies (that is, experimental and clinical data) in support of a pathogenic role of AGE-RAGE and AGE cross-link interaction in the development of diabetic kidney disease. Finally, the effects of known and potential inhibitors of AGE-RAGE and AGE cross-link systems in diabetic kidney disease will be examined.
Publication Types:
Online - Abstract
Advanced glycation end products and diabetic nephropathy
Am J Ther. 2005 Nov-Dec;12(6):562-72
Thomas MC, Forbes JM, Cooper ME.
Chronic hyperglycemia and oxidative stress in diabetes results in the formation and accumulation advanced glycation end products (AGEs). AGEs have a wide range of chemical, cellular, and tissue effects that contribute to the development of microvascular complications. In particular, AGEs appear to have a key role in the diabetic nephropathy. Their importance as downstream mediators of tissue injury in diabetic kidney disease is demonstrated by animal studies using inhibitors of advanced glycation to retard the development of nephropathy without directly influencing glycemic control. AGE modification of proteins may produce in changes charge, solubility, and conformation leading to molecular dysfunction as well as disrupting interactions with other proteins. AGEs also interact with specific receptors and binding proteins to influence the renal expression of growth factors and cytokines, implicated in the progression of diabetic renal disease. The effects of AGEs appears to be synergistic with other pathogenic pathways in diabetes including oxidative stress, hypertension, and activation of the renin-angiotensin system. Each of these pathways may be activated by AGEs, and each may promote the formation of AGEs in the vicious cycle associated with progressive renal damage. It is likely that therapies that inhibit the formation of AGEs or remove established AGE modifications will form an important component part of future therapy in patients with diabetes, acting in concert with conventional approaches to prevent diabetic renal injury.
Publication Types:
Online - Abstract
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