Fasting triggers complex physiological and neuroimmune adaptations, yet its impact on hypothalamic microglia and the underlying regulatory role of glucocorticoids remains incompletely understood. The Show more
Fasting triggers complex physiological and neuroimmune adaptations, yet its impact on hypothalamic microglia and the underlying regulatory role of glucocorticoids remains incompletely understood. The present study focused on fasting-induced systemic changes and cellular adaptations seen in the hypothalamus where components of metabolic- hormonal- and immune regulations are integrated. Adult male microglia reporter (CX3CR1 Overnight fasting resulted in a decrease in energy expenditure and respiratory exchange ratio (RER) indicating conservation of energy and a metabolic shift towards utilization of fatty acids as alternative energy source. Fasting increased hypothalamic expression of orexigenic neuropeptides and mRNA levels of Pdk4, Glut1, and Mct2 genes, in line with metabolic compensation. Upregulation of hypothalamic Crh and increased plasma concentration of corticosterone indicated sustained activation of the HPA axis. Importantly, fasting promoted an anti-inflammatory milieu in the hypothalamus characterized by elevated Il-4, Il-10 and IkBα genes without significant activation of pro-inflammatory cytokines (e.g., Il-1β, Il-6, Tnfα). Morphological analysis revealed region-specific changes in microglia number and branching complexity, particularly in hypothalamic regions directly exposed to blood-borne signals. Functional profiling showed increased microglial expression of IkBα and decreased pIkBα, indicating suppressed NFkB signaling. Adrenalectomy (1 week) and acute pharmacological inhibition of corticosterone synthesis (methyrapone) revealed that fasting-induced anti-inflammatory and metabolic gene expression, as well as microglial plasticity were largely glucocorticoid dependent. Hypothalamic expression of fasting-related neuropeptides (Npy, Agrp) and genes, related to the metabolic shift (Pdk4, Glut-1, Mct2, Angptl4) as well as some immune-related genes (Il10, Iba1) was dependent on presence of the adrenal gland or fasting-induced elevation of corticosterone. These findings highlight short term fasting as a potent modulator of hypothalamic immune-metabolic crosstalk and reveal critical role of adrenal glucocorticoids in orchestrating microglial responses to energetic challenges. The results have potential implications for therapeutic interventions targeting metabolic and inflammatory disorders. Show less
The autophagosomal SNARE STX17 (syntaxin 17) promotes lysosomal fusion and degradation, but its autophagosomal recruitment is incompletely understood. Notably, PtdIns4P is generated on autophagosomes Show more
The autophagosomal SNARE STX17 (syntaxin 17) promotes lysosomal fusion and degradation, but its autophagosomal recruitment is incompletely understood. Notably, PtdIns4P is generated on autophagosomes and promotes fusion through an unknown mechanism. Here we show that soluble recombinant STX17 is spontaneously recruited to negatively charged liposomes and adding PtdIns4P to liposomes containing neutral lipids is sufficient for its recruitment. Consistently, STX17 colocalizes with PtdIns4P-positive autophagosomes in cells, and specific inhibition of PtdIns4P synthesis on autophagosomes prevents its loading. Molecular dynamics simulations indicate that C-terminal positively charged amino acids establish contact with membrane bilayers containing negatively charged PtdIns4P. Accordingly, Ala substitution of Lys and Arg residues in the C terminus of STX17 abolishes membrane binding and impairs its autophagosomal recruitment. Finally, only wild type but not Ala substituted STX17 expression rescues the autophagosome-lysosome fusion defect of STX17 loss-of-function cells. We thus identify a key step of autophagosome maturation that promotes lysosomal fusion. Show less