Aldose reductase: a window to the treatment of diabetic complications?

Kinetic studies on the aldose reductase protein (AR2) have shown that it does not behave as a classical enzyme in relation to ring aldose sugars. These results have been confirmed by X-ray crystallography studies, which have pinpointed binding sites for pharmacological “aldose reductase inhibitors”...

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Bibliographic Details
Published in:Progress in retinal and eye research 1998-07, Vol.17 (3), p.313-383
Main Authors: Crabbe, M.James C., Goode, Derek
Format: Article
Language:English
Subjects:
Aldehyde Reductase - antagonists & inhibitors
Aldehyde Reductase - chemistry
Aldehyde Reductase - physiology
Animals
Cataract - drug therapy
Cataract - etiology
Cattle
Diabetes Complications
Diabetes Mellitus - physiopathology
Diabetic Retinopathy - drug therapy
Diabetic Retinopathy - etiology
Enzyme Inhibitors - therapeutic use
Humans
Lens, Crystalline - enzymology
Rats
Retina - enzymology
Sugar Alcohols - metabolism
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Summary:Kinetic studies on the aldose reductase protein (AR2) have shown that it does not behave as a classical enzyme in relation to ring aldose sugars. These results have been confirmed by X-ray crystallography studies, which have pinpointed binding sites for pharmacological “aldose reductase inhibitors” (ARIs). As with non-enzymic glycation reactions, there is probably a free-radical element involved derived from monosaccharide autoxidation. In the case of AR2, there is free radical oxidation of NADPH by autoxidising monosaccharides, enhanced in the presence of the NADPH-binding protein. Whatever the behaviour of AR2, many studies have showed that sorbitol production is not an initiating aetiological factor in the development of diabetic complications in humans. Vitamin E ( α-tocopherol), other antioxidants and high fat diets can delay or prevent cataract in diabetic animals even though sorbitol and fructose levels are not modified; vitamin C acts as an ARI in humans. Protein post-translational modification by glyc-oxidation or other events is probably the key factor in the aetiology of diabetic complications. There is now no need to invoke AR2 in xylitol biosynthesis. Xylitol can be produced in the lens from glucose, via a pathway involving the enzymes myo-inositol-oxygen oxidoreductase, d-glucuronate reductase, l-gulonate NAD +-3-oxidoreductase and l-iditol-NAD +-5-oxidoreductase, all of which have recently been found in bovine and rat lens. This chapter investigates the molecular events underlying AR2 and its binding and kinetics. Induction of the protein by osmotic response elements is discussed, with detailed analysis of recent in vitro and in vivo experiments on numerous ARIs. These have a number of actions in the cell which are not specific, and which do not involve them binding to AR2. These include peroxy-radical radical scavenging and recently discovered effects of metal ion chelation. In controlled experiments, it has been found that incubation of rat lens homogenate with glucose and the copper chelator o-phenanthroline abolishes production of sorbitol. Taken together, these results suggest AR2 is a vestigial NADPH-binding protein, perhaps similar in function to a number of non-mammalian crystallins which have been recruited into the lens. There is mounting evidence for the binding of reactive aldehyde moieties to the protein, and the involvement of AR2 either as a `housekeeping' protein, or in a free-radial-mediated `catalytic' role. Interfering wit
ISSN:1350-9462
1873-1635
DOI:10.1016/S1350-9462(97)00013-X