Energy’s long game: thermogenic adipocytes and the metabolic diseases of modern life Silvia Corvera, Michael P. Czech Volume 4, Issue 1

https://www.academia.edu/journals/academia-biology/articles?source=journal-top-nav Abstract The ability to generate, store, and mobilize energy is fundamental to life, and disruptions in these processes underlie metabolic disease. This review examines how these mechanisms evolved to rely profoundly on lipids, a large family of molecules that serve an unusually wide range of biological functions. From early evolutionary times, lipids have enabled chemiosmotic energy transduction, organized the endomembrane systems that synthesize and package neutral lipids, served as concentrated reservoirs of metabolic energy, and functioned as signaling molecules that coordinate cellular and systemic physiology. Adipocytes are specialized cells that can accumulate large amounts of lipid within specialized lipid droplet organelles. Over evolutionary time, mammals developed distinct adipocyte subtypes with tailored physiological roles. White adipocytes, characterized by a single large unilocular lipid droplet, coordinate energy storage and release in response to systemic cues. In contrast, the role of brown and beige adipocytes is to protect the organism from cold exposure by generating heat as a primary output of UCP1-mediated mitochondrial uncoupling. Crucially, this thermogenic process requires extensive systemic coordination: sympathetic neural input triggers lipolysis, vascular networks deliver fuel from multiple adipose depots, and hormonal signals integrate metabolic demand across organs. These requirements position thermogenic adipocytes as metabolic integration “nodes” that orchestrate whole-body fuel allocation and energy homeostasis. The presence of functional thermogenic adipocytes is strongly associated with improved cardiometabolic health, protecting against obesity, type 2 diabetes, and cardiovascular disease. Understanding how these specialized cells sense and respond to systemic signals offers a powerful entry point for developing strategies to counteract metabolic disease. https://www.academia.edu/2837-4010/4/1/10.20935/AcadBiol8131