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ABSTRACT Astrocytes provide physical and metabolic support for neurons, regulate the blood–brain barrier, and react to injury, infection, and disease. When astrocytes become reactive, maintenance of the inflammatory state and its functional implications throughout chronic neuroinflammation are all poorly understood. Several models of acute inflammation have revealed astrocyte subpopulations that go beyond a two‐activation state model, instead encompassing distinct functional subsets. However, how reactive astrocyte (RA) subsets evolve over time during chronic inflammatory disease or infection has been difficult to address. Here we use a prolific human pathogen,Toxoplasma gondii, that causes lifelong infection in the brain alongside aLcn2CreERT2reporter mouse line to examine reactive astrocyte subsets during chronic neuroinflammation. Single‐cell RNA sequencing revealed diverse astrocyte populations including transcriptionally uniqueLcn2CreERT2+ RAs which change over the course of infection in a subset‐dependent manner. In addition to an immune‐regulatingLcn2CreERT2+ astrocyte population enriched with gene transcripts encoding chemokines CCL5, CXCL9, CXCL10, and receptors CCR7 and IL7R, a specific subset ofLcn2CreERT2+ astrocytes highly expressedtransthyretin(Ttr), a secreted carrier protein involved in glycolytic enzyme activation and potential vasculature regulation and angiogenesis. These findings provide novel information about the evolution and diversity of reactive astrocyte subtypes and functional signatures at different stages of infection, revealing an undocumented role for transthyretin‐expressing astrocytes in immune regulation at the central nervous system (CNS) vasculature. 

The mature mammalian cortex is composed of 6 architecturally and functionally distinct layers. Two key steps in the assembly of this layered structure are the initial establishment of the glial scaffold and the subsequent migration of postmitotic neurons to their final position. These processes involve the precise and timely regulation of adhesion and detachment of neural cells from their substrates. Although much is known about the roles of adhesive substrates during neuronal migration and the formation of the glial scaffold, less is understood about how these signals are interpreted and integrated within these neural cells. Here, we provide in vivo evidence that Cas proteins, a family of cytoplasmic adaptors, serve a functional and redundant role during cortical lamination.Castriple conditional knock-out (CasTcKO) mice display severe cortical phenotypes that feature cobblestone malformations. Molecular epistasis and genetic experiments suggest that Cas proteins act downstream of transmembrane Dystroglycan and β1-Integrin in a radial glial cell-autonomous manner. Overall, these data establish a new and essential role for Cas adaptor proteins during the formation of cortical circuits and reveal a signaling axis controlling cortical scaffold formation.