Abstract
The advanced stage of the glycation process (also called the “Maillard reaction”) that leads to the formation of advanced glycation end-products (AGEs) plays an important role in the pathogenesis of angiopathy in diabetic patients and in the aging process. AGEs elicit a wide range of cell-mediated responses that might contribute to diabetic complications, vascular disease, renal disease, and Alzheimer disease. Recently, it has been proposed that AGE are not only created from glucose per se, but also from dicarbonyl compounds derived from glycation, sugar autoxidation, and sugar metabolism. However, this advanced stage of glycation is still only partially characterized and the structures of the different AGEs that are generated in vivo have not been completely determined. Because of their heterogeneity and the complexity of the chemical reactions involved, only some AGEs have been characterized in vivo, including N-carboxymethyllysine (CML), pentosidine, pyrraline, and crosslines. In this article, we provide a brief overview of the pathways of AGE formation and of the immunochemical methods for detection of AGEs, and we also provide direct immunological evidence for the existence of five distinct AGE classes (designated as AGE-1 to -5) within the AGE-modified proteins and peptides in the serum of diabetic patients on hemodialysis. We also propose pathways for the in vivo formation of various AGEs by glycation, sugar autoxidation, and sugar metabolism.
Keywords: Advanced Glycation End-products, glycation end-products (AGEs), N-carboxymethyllysine (CML), Pyrraline, Pentosidine, Crossline, Imidazolones, Arg-Lys Imidazole (ALI), Vesperlysine A, Argpyrimidine
Call for Papers in Thematic Issues
From Molecular Mechanisms to Therapeutic Frontiers: The Versatile Roles of Chaperones in Medicine
Chaperones play critical roles in maintaining proteostasis by preventing protein misfolding and aggregation, which constitute central processes to the pathogenesis of numerous diseases such as neurodegeneration, cancer, and inflammatory disorders. This thematic issue will delve into the molecular mechanisms of chaperone function, their involvement in disease progression, and their potential ...read more
Metabolic Reprogramming and Molecular Pharmacology: Innovations in Drug Discovery and Therapeutic Targeting
Metabolic reprogramming is a hallmark of numerous diseases, including cancer, metabolic disorders, and neurodegeneration. Understanding the intricate cell signaling pathways, transduction pathways, and omics-based data is important for the development of novel pharmacological interventions. This special issue of Current Molecular Medicine will be devoted to the current advances in drug ...read more
Molecular and Cellular Mechanisms in Vertigo / Vestibular Disorders
Vertigo and vestibular diseases are common among middle-aged and older adults, significantly increasing the risk of falls and leading to injuries and disabilities. Despite their prevalence, therapeutic advancements are hindered by a limited understanding of the underlying molecular and cellular mechanisms. This Special Issue is dedicated to bridging this gap ...read more
Related Books
Microbial Insights into Wastewater Treatment and Environmental Sustainability
Biological Control for Plant Protection: Recent Advances in Research and Sustainability
From Genes to Algorithms: Navigating the Biotechnology Data Revolution
Phytochemical Arsenal: Understanding Plant Defense Mechanisms Against Nematodes
Controlled Environment Horticulture: Where Plant Biotechnology Meets Sustainable Future
Genetic Diversity of Coronaviruses: From SARSCoV to SARS-CoV-2 – (Part 2)
Wild Vegetables: Morphology, Phytochemistry and Utility - (Part 2)
A Practical Approach to Molecular Cloning
Organoid Technology: Disease Modelling, Drug Discovery, and Personalized Medicine
Arid and Semi-Arid Zones of Mexico: A Comprehensive Exploration of Biodiversity, Ecology, and Conservation
13