Ganglioside GM1-enriched rafts regulate the neuronal chloride co-transporter 1 KCC2.

During brain development, dynamic remodeling of membrane lipid composition accompanies the maturation of inhibitory neurotransmission and the progressive establishment of low intracellular chloride levels. Central to this developmental transition is the neuronal K-Cl- cotransporter KCC2, whose stabilization at the plasma membrane enables the emergence of hyperpolarizing GABAergic signaling. Although KCC2 regulation by protein partners has been extensively characterized, whether lipid remodeling actively contributes to its membrane organization and chloride transport remains unclear. Here we identify the ganglioside GM1, a complex lipid abundant in plasma membrane of neurons, as a developmentally regulated lipid determinant of KCC2 membrane localization and function. We show that KCC2 interacts with GM1 within plasma membrane lipid rafts and that this interaction increases during postnatal brain maturation. Molecular modeling identified a conserved ganglioside-binding domain (GBD) in KCC2 centered on tryptophan 318 (W318). Biophysical analyses revealed a specific and saturable interaction between this domain and GM1 that is abolished by the epilepsy-associated W318S mutation. Disruption of KCC2-GM1 interactions, either by W318S mutation or by pharmacological depletion of GM1, excludes KCC2 from lipid rafts, alters its membrane diffusion and clustering, and reduces its surface stability. Functionally, these perturbations impair KCC2-mediated chloride extrusion and disrupt the somato-dendritic chloride gradient in hippocampal neurons. Consistent with these cellular effects, GM1-deficient (St3gal5-/-) mice exhibit selective reduced hippocampal KCC2 expression. Together, these findings reveal a lipid-protein mechanism that links developmental membrane remodeling to KCC2 stabilization and chloride homeostasis, highlighting membrane lipids as active regulators of transporter maturation and inhibitory circuit development.