Drp1-mediated mitochondrial fission controls cortical astrocyte organization and development (2023)

Undergraduate: Sprihaa Kolanukuduru

Faculty Advisor: Shveta Parekh
Department: Duke Cell Biology, Psychology & Neuroscience

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Mitochondrial homeostasis is essential to proper brain development and dysfunctional mitochondria are implicated in multiple neurodevelopmental disorders. Mitochondrial function and localization is regulated by mitochondrial fission, fusion, and trafficking, collectively referred to as mitochondrial dynamics, a process that is particularly important in highly branched cells of the brain. Astrocytes are glial cells characterized by their complex branched morphology that allows them to perform many functions such as inducing synaptogenesis in the developing cortex. Cortical astrocytes are organized in nonoverlapping territories in a phenotype described as tiling. Tiling is a hallmark of astrocyte maturity and is lost in disease, suggesting tiling is imperative to astrocyte development and function. However, the molecular mechanisms of how astrocytes establish tiling during development are not well understood. Past research in the Eroglu Lab has shown that early postnatal knockdown of Drp1, a regulator of mitochondrial fission, in astrocytes in the mouse cortex leads to astrocyte clustering. Therefore, we hypothesized that Drp1-induced mitochondrial fission regulates astrocyte organization and tiling in the developing and mature mouse cortex. We found that sparse Drp1 KD in astrocytes induces clustering into adulthood up to 6-month-old mice, indicating Drp1 control of astrocyte organization is not a transient developmental mechanism. Furthermore, we uncovered that Drp1 KD astrocyte clusters are multinucleated and have disorganized cell somas, confirming Drp1 controls the tiling phenotype of astrocytes. Lastly, we found that astrocyte-specific conditional KO of Drp1 results in disorganization and reduced astrocyte coverage in the cortex, coupled with heterogeneous upregulation of GFAP, a marker of astrocyte dysfunction. These findings indicate that Drp1 controls astrocyte organization and identity and underscore the importance and therapeutic potential of mitochondrial fission in the proper development of astrocytes.

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