A post-inflammatory C3-high astrocyte state persists after inflammatory stimulus withdrawal and is attenuated by JAK inhibition

Reactive astrocytes contribute to neuroinflammation and synaptic dysfunction, but it remains unclear whether transient inflammatory stimulation causes a persistent reactive state after the initial inflammatory stimulus is removed. Here, we investigated whether transient exposure to a defined inflammatory cytokine/complement cocktail induces a persistent reactive astrocyte state and examined the signaling mechanism underlying its maintenance. Human astrocytes were exposed to the inflammatory stimulus and subsequently subjected to stimulus washout, followed by time-course analyses to compare the reversibility of inflammatory gene expression after stimulus removal. Following washout, the expression of several inflammatory response genes, including CXCL10 and NF-{kappa}B-associated genes such as NFKBIA, TNFAIP3, and RELB, returned toward baseline levels. In contrast, C3 expression remained elevated, indicating persistence of a post-inflammatory C3-high astrocyte state after withdrawal of the inflammatory stimulus. Pharmacological inhibition of JAK signaling reduced persistent C3 expression to near-baseline levels, supporting the involvement of JAK-dependent signaling in maintenance of this persistent state. Together, these findings suggest that transient inflammatory stimulation induces a post-inflammatory persistent C3-high astrocyte state that is maintained even after broader inflammatory gene responses have subsided. This persistent C3-high component is pharmacologically attenuated by JAK inhibition, identifying JAK-dependent pathways as modulators of persistent astrocyte inflammatory reactivity.