Planar cell polarity (PCP) signaling plays a fundamental role in shaping the development and ongoing function of the nervous system, beginning from early stages of neural tube closure and spanning the maintenance of functional synapses in adults. While mutations in core PCP signaling proteins have long been suspected to underlie neural tube closure defects in humans, recent findings also implicate their potential involvement in neurodevelopmental and neuropsychiatric disorders. Missense and loss-of-function mutations in CELSR3, a core component of PCP signaling complexes, are highly associated with Tourette Disorder. Although the functional significance of these mutations has yet to be elucidated in animal and cell models, the expression patterns of Celsr3 in mice point to alterations in cortico-striato-thalamo-cortical circuits. Here, we briefly review the known functions of Celsr3 for nervous system development. We also propose circuit models for Tourette Disorder by hypothesizing roles for Celsr3 in controlling striatal neuromodulation via effects on cholinergic interneurons, and thalamic inhibition through its functions in thalamic reticular nuclei. Testing these and related hypotheses in animal and cell models will move us closer to unraveling the neuropathogenesis of Tourette Disorder, with the ultimate goal of developing more efficacious treatments for both motor and cognitive symptoms.
Keywords: Celsr3; Cholinergic interneurons; Planar cell polarity; Thalamic reticular nucleus; Tourette disorder.
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