Astrocytes control quiescent NSC reactivation via GPCR signaling-mediated F-actin remodeling.
Kun-Yang LinMahekta R GujarJiaen LinWei Yung DingJiawen HuangYang GaoYe Sing TanXiang TengLow Siok Lan ChristinePakorn KanchanawongYusuke ToyamaHongyan WangPublished in: Science advances (2024)
The transitioning of neural stem cells (NSCs) between quiescent and proliferative states is fundamental for brain development and homeostasis. Defects in NSC reactivation are associated with neurodevelopmental disorders. Drosophila quiescent NSCs extend an actin-rich primary protrusion toward the neuropil. However, the function of the actin cytoskeleton during NSC reactivation is unknown. Here, we reveal the fine filamentous actin (F-actin) structures in the protrusions of quiescent NSCs by expansion and super-resolution microscopy. We show that F-actin polymerization promotes the nuclear translocation of myocardin-related transcription factor, a microcephaly-associated transcription factor, for NSC reactivation and brain development. F-actin polymerization is regulated by a signaling cascade composed of G protein-coupled receptor Smog, G protein α q subunit, Rho1 guanosine triphosphatase, and Diaphanous (Dia)/Formin during NSC reactivation. Further, astrocytes secrete a Smog ligand folded gastrulation to regulate Gα q -Rho1-Dia-mediated NSC reactivation. Together, we establish that the Smog-Gα q -Rho1 signaling axis derived from astrocytes, an NSC niche, regulates Dia-mediated F-actin dynamics in NSC reactivation.
Keyphrases
- neural stem cells
- cell migration
- transcription factor
- white matter
- protein kinase
- zika virus
- dna binding
- smooth muscle
- intellectual disability
- resting state
- gene expression
- genome wide
- dna methylation
- autism spectrum disorder
- blood brain barrier
- subarachnoid hemorrhage
- drug induced
- congenital heart disease
- cerebral ischemia