Piccolo Regulates Secretion of the Extracellular Matrix Components Brevican and Tenascin R from Astrocytes to Drive Synapse Formation: Implications for Pontocerebellar Hypoplasia Type 3 (PCH3)
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Background
Astrocytes are crucial for CNS health, for instance via the secretion of extracellular matrix (ECM) components that are vital for synapse formation and maturation. While the scaffolding protein Piccolo is known for its role at synapses, its function in astrocytes and contribution to neurodegenerative disorders like Pontocerebellar Hypoplasia Type 3 (PCH3) are largely unknown. Understanding these mechanisms is key to elucidating PCH3 pathology.
Methods
We used a multi-faceted approach with a Pclo gt/gt rat model. Methods included RNA-sequencing for gene expression and GO analysis. Immunohistochemistry and immunocytochemistry assessed Piccolo localization, ECM component (Brevican [Bcan], Tenascin-R [TNR]) levels, distribution, and secretion in brain sections and primary astrocytes. Golgi morphology was evaluated via GM130 staining. Neuronal network formation and function were investigated by co-culturing wild-type neurons with Pclo wt/wt or Pclo gt/gt astrocytes in a Banker setup, assessing synapse density (immunostaining, RRP electrophysiology) and spontaneous activity (mEPSCs, mIPSCs). Astrocyte-conditioned media (ACM) experiments determined secreted factor roles.
Results
RNA-seq showed significant DEG increases in older versus young Pclo gt/gt rats (P25 vs. P5), which were strongly enriched in cell communication, signaling, and ECM GO terms. We identified a novel astrocyte-specific Piccolo isoform that partially localizes at the Golgi. Piccolo gene trap transposon mutation led to impaired ECM secretion (reduced extracellular Bcan, altered TNR) from astrocytes, correlating with a fragmented Golgi in Pclo gt/gt astrocytes. Functionally, Pclo gt/gt astrocytes significantly reduced synapse density and altered intrinsic activity (increased mEPSC frequency) in neuronal networks. This synaptic deficit was substantially rescued by Pclo wt/wt astrocyte conditioned media (ACM).
Conclusion
Our findings reveal a critical, unrecognized role for Piccolo in regulating astrocytic ECM secretion, essential for proper neuronal network formation and activity. Astrocytic Piccolo dysfunction disrupts this process, causing impaired synaptogenesis and altered intrinsic network activity, providing a novel cellular and molecular mechanism for neurodegenerative diseases like PCH3 and highlights astrocytes as potential therapeutic targets.
