Glycation of Immunoglobulin-G from Pentose Sugar: A Cause for Structural Perturbations.

ABSTRACT

BACKGROUND: Glycation of immunoglobulin-G (IgG) molecules with monosaccharides may cause significant structural disability, thus resulting in their loss of function. The accumulation of AGEs formed from glycation plays an important role in the aliments associated with metabolic diseases. Therefore, excess sugar in plasma interferes with the functioning of IgG and may contribute to a wide range of diabetes-associated complications. The long-term formation of these heterogeneous AGEs may accumulate and affect plasma proteins, especially long-lived proteins. In this study, we analyze immunoglobulin-G (IgG) glycation with 2'-deoxyribose (deoxyribose) instigated modification in IgG structure and AGEs formation. METHODS: This study aims to glycate IgG from varying concentrations of pentose sugar, 2'-deoxyribose (deoxyribose). Various physicochemical methods and techniques characterized post glycation of IgG, both the native and its glycated analogue. The glycated protein will be assessed for its stability and perturbations by UV-VIS., fluorescence and FT-IR spectroscopic techniques. Moreover, the early glycation product will be done by NBT assay, and other biochemical parameters like HMF, carbonyl content and thioflavin-T assays were also performed to see the biochemical changes induced in the glycated IgG macromolecule. RESULTS: Glycation of protein macromolecules generates stable early glycation products (Amadori products). Later, these Amadori products involved a series of chemical reactions to form more stable advanced glycation end products (AGEs). Our experimental study results could validate the modification in IgG structure and AGEs formation. CONCLUSION: The formation of IgG-AGEs from glycation of IgG with deoxyribose could exert cellular toxicity, and might initiates secondary complications of diabetes. Therefore, this study emphasized the glycation reaction of IgG from deoxyribose, which has not been reported yet.