Interaction Between Microglial Lipid Droplet Metabolism and Immune Polarisation After Stroke: Mechanisms and Therapeutic Prospects
J. C. S. Yang, Dongyan Wang, Xu Dong, Hong Huo, Ruiyu Tao, Youwei Zhang, Zhao Wang, Liping Wang, Ninghui Zhi
Abstract
The interaction between lipid droplet (LD) metabolism and immune polarisation of microglia after stroke plays a key role in the regulation of neuroinflammation and tissue repair. This review analysed the molecular mechanism, spatiotemporal specificity, and the dual role of the LD metabolism-immune axis in microglia after stroke. Microglial LDs can dynamically store neutral lipids and regulate the metabolite-immune network, playing a protective role in the early stage of stroke by isolating pro-inflammatory precursors, inhibiting oxidative stress and iron death, and maintaining energy buffer. Spatiotemporal analysis revealed significant heterogeneity in the distribution and function of LDs across different stages of stroke and in distinct brain areas (infarct core, peri-infarct region, and non-infarct area), directly correlating with the pro-inflammatory/anti-inflammatory phenotypic transformation of microglia. The development of LD-related biomarkers (such as near-infrared imaging), the repurpose of peroxisome proliferator-activated receptor γ agonists (rosiglitazone) and HDAC inhibitors (volinostat), as well as the design of novel drugs (such as Triggering Receptor Expressed on Myeloid Cells 2 agonists and perilipin 2 small interfering RNA) are expected to improve stroke outcomes by transforming metabolic homeostasis and immune balance. Multi-omics technology and intelligent delivery system should be combined to overcome the limitations of the blood-brain barrier, promote the clinical transformation of the "metabolism-immunity" collaborative intervention strategy, and provide a new paradigm for precision treatment of stroke.