Molecular implications of glycosaminoglycans in diabetes pharmacotherapy

Diabetes mellitus causes a wide range of metabolic derangements with multiple organ damage. The microvas-cular and macrovascular complications of diabetes result partly from the damage to the glycosaminoglycans (GAG) in the basement membrane. GAGs are negatively charged polysaccharides with repeating disaccharide units. They play a significant role in cellular proliferation and signal transduction. Destruction of extracellular matrix results in diseases in various organs including myocardial fibrosis, retinal damage and nephropathy. To substitute the natural GAGs pharmacotherapeutically, they have been synthesized by using basic disaccharide units. Among the four classes of GAGs, heparin is the most widely studied. Recent studies have revealed multiple significant GAG-protein interactions suggesting their use for the management of diabetic complications. More-over, they can act as biomarkers for assessing the disease progression. A number of GAG-based therapeutic agents are being evaluated for managing diabetic complications. The current review provides an outline of the role of GAGs in diabetes while covering their interaction with different molecular players that can serve as targets for the diagnosis, management and prevention of diabetes and its complications. The medicinal chemistry and clinical pharmacotherapeutics aspects have are covered to aid in the establishment of GAG-based therapies as a possible avenue for diabetes.

Automated summary

Diabetes mellitus leads to metabolic derangements and organ damage, partially due to glycosaminoglycan (GAG) damage in the basement membrane. GAGs are polysaccharides with repeating disaccharide units and play a significant role in cellular processes. The destruction of extracellular matrix can result in various diseases in organs. GAG-based therapeutic agents are being evaluated for managing diabetic complications.