Distinct subtypes of astrocytes selectively regulate specific inhibitory synapses

Astrocyte functional heterogeneity within a given neuronal circuit remains largely undetermined, particularly their role at tripartite synapses. Here, we examine multiple functional characteristics of astrocytes distinguished by their specific spatial relation to inhibitory synapses made on distinct hippocampal CA1 pyramidal cell domains: astrocytes covering the peri-somatic area in stratum pyramidale (SP) receiving input from Parvalbumin interneurons, or the apical dendritic area in stratum radiatum (SR) innervated by inhibitory inputs from Somatostatin interneurons. Whole-cell dye-filling and confocal imaging of SR astrocytes showed a typical bushy organization of processes while those of SP astrocytes were more polarized, indicating astrocyte morphological heterogeneity. In addition, SP astrocytes formed a smaller, yet polarised syncytium and displayed greater input resistance relative to SR astrocytes. The two populations of astrocyte are functionally different as indicated by their intrinsic Ca ²⁺ signaling properties: SP astrocyte Ca ²⁺ events had a lower frequency and temporal density, but greater amplitude, relative to SR astrocytes. Using the territorial segregation of inhibitory synapses, we observed that the selective activation using DREADD or blockade with intracellular BAPTA of the two populations of astrocytes regulated inhibitory synapses exclusively in their own syncytial territory. Furthermore, each astrocyte population selectively mediated long-term depression at the respective inhibitory synapses through Ca ²⁺ -dependent modulation of post-synaptic targets. These results indicate domain-specific regulation of inhibitory synapses by distinct SP and SR astrocyte syncytia. Transcriptional analysis revealed enriched gene expression in SP relative to SR astrocytes, notably for regulation of cell growth and morphology, synaptic function and signaling. Overall, our findings reveal a functional specialization of astrocyte subtypes in the hippocampus, highlighting heterogeneous astrocyte regulation of hippocampal synaptic networks important for learning and memory.