Cytotoxic metabolites originating from the peripheral circulation can induce central nervous system complications associated with diabetes. Since a large proportion of these metabolites bind to plasma albumin, mechanisms for transporting albumin-metabolite complexes into the brain exist under diabetic conditions. Secreted protein acidic and rich in cysteine (SPARC) is one of the vesicular transport receptors responsible for albumin transport. This study aimed to investigate the changes in SPARC expression and cellular albumin transfer under high-glucose conditions and evaluate the permeability of molecules with high protein-bound properties to the brain tissue. Glucose (30 mM) increased SPARC expression, and intracellular albumin accumulation in NIH3T3 cells. In addition, these changes were observed in the brain of ob/ob mice. Brain microvessels function as a physiological barrier to limit the penetration of molecules from the peripheral blood circulation into the brain by forming tight junctions. Although protein expression of molecules involved in tight junction formation and cell adhesion was increased in the brain microvessels of ob/ob mice, molecular transfer into the brain through cellular junctions was not enhanced. However, Evans blue dye injected into the peripheral vein and endogenous advanced glycation end-products, exerted a high protein-binding property and accumulated in their brains. These observations indicate that peripheral molecules with high protein-binding properties invade the brain tissue and bind to albumin through transcytosis mediated by SPARC.
Keywords: Albumin; Blood-brain-barrier; Diabetes mellitus; Protein-binding; SPARC.
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