Abstract
Granule neuron progenitors (GNPs) are the most abundant neuronal type in the cerebellum. GNP proliferation and thus cerebellar development require Sonic hedgehog (Shh) secreted from Purkinje cells. Shh signaling occurs in primary cilia originating from the mother centriole. Centrioles replicate only once during a typical cell cycle and are responsible for mitotic spindle assembly and organization. Recent studies have linked cilia function to cerebellar morphogenesis, but the role of centriole duplication in cerebellar development is not known. Here we show that centrosomal protein Cep120 is asymmetrically localized to the daughter centriole through its interaction with Talpid3 (Ta3), another centrosomal protein. Cep120 null mutant mice die in early gestation with abnormal heart looping. Inactivation of Cep120 in the central nervous system leads to both hydrocephalus, due to the loss of cilia on ependymal cells, and severe cerebellar hypoplasia, due to the failed proliferation of GNPs. The mutant GNPs lack Hedgehog pathway activity. Cell biological studies show that the loss of Cep120 results in failed centriole duplication and consequently ciliogenesis, which together underlie Cep120 mutant cerebellar hypoplasia. Thus, our study for the first time links a centrosomal protein necessary for centriole duplication to cerebellar morphogenesis.
Highlights
The cerebellum controls motor movement coordination, balance, equilibrium, and muscle tone
This study shows for the first time that a centrosomal protein necessary for centriole duplication is important in cerebellar morphogenesis
Ta3 is a centrosomal protein that is required for ciliogenesis and Hedgehog signaling [18,19]
Summary
The cerebellum controls motor movement coordination, balance, equilibrium, and muscle tone. Cerebellar development is a complex process requiring coordinated regulation of progenitor proliferation, neuronal differentiation and migration [1,2]. The GNPs leave the RL at around embryonic day 13 (E13) and migrate rostrally over the surface of the cerebellar anlage to form the external germinal layer (EGL). During the first two weeks after birth, the GNPs in the EGL undergo significant proliferation to generate the large pool of GNPs required for producing granule neurons. They exit cell cycle and migrate internally into the cortex of the cerebellum to establish the inner granule layer (IGL) under the Purkinje cell monolayer (PCL) [3]. Defects in any of these stages of cerebellar development result in cerebellar hypoplasia in humans and mice
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