Ciliary cAMP regulates Shh signal interpretation to drive polarisation of differentiating neurons

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This study investigated how differentiating neurons reinterpret Sonic hedgehog (Shh) signals during a switch between canonical and non-canonical Shh signalling by remodeling their primary cilium, using long-term live-tissue imaging. The authors found that the Shh modulators Smo and GPR161 both accumulate in the remodelled cilium, and that their balanced activity elevates ciliary cAMP, which suppresses Gli transcription factor activation and regulates actin dynamics to drive neuron polarisation. Disrupting this balance via Smo hyperactivation or GPR161 depletion reduced ciliary cAMP, caused inappropriate canonical Shh signalling activation, dysregulated actin dynamics, and led to multiple unstable axon-like projections. The paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Cellular differentiation is characterised by transitions in cell-state through reinterpretation of extracellular signals. However, the mechanisms facilitating context-dependent signal interpretation remain poorly understood. Differentiating neurons remodel a molecularly distinct primary cilium as they switch from canonical to non-canonical Shh signalling. Here, using long-term live-tissue imaging, we demonstrate that the opposing Shh signalling modulators Smo and GPR161 simultaneously accumulate in the remodelled primary cilium. The correct balance of Smo and GPR161 leads to elevated ciliary cAMP levels, which suppresses Gli transcription factor activation and regulates actin dynamics to drive neuron polarisation. Notably, disrupting this balance through Smo hyperactivation or GPR161 depletion results in reduced ciliary cAMP, inappropriate activation of canonical Shh signalling, dysregulated actin dynamics and initiation of multiple unstable axon-like projections. Thus, this study identifies shifts in ciliary cAMP levels as a key regulator of cellular signal interpretation, and links primary cilium-mediated signal transduction to precise control of cytoskeletal organisation.
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Abstract Cellular differentiation is characterised by transitions in cell-state through reinterpretation of extracellular signals. However, the mechanisms facilitating context-dependent signal interpretation remain poorly understood. Differentiating neurons remodel a molecularly distinct primary cilium as they switch from canonical to non-canonical Shh signalling. Here, using long-term live-tissue imaging, we demonstrate that the opposing Shh signalling modulators Smo and GPR161 simultaneously accumulate in the remodelled primary cilium. The correct balance of Smo and GPR161 leads to elevated ciliary cAMP levels, which suppresses Gli transcription factor activation and regulates actin dynamics to drive neuron polarisation. Notably, disrupting this balance through Smo hyperactivation or GPR161 depletion results in reduced ciliary cAMP, inappropriate activation of canonical Shh signalling, dysregulated actin dynamics and initiation of multiple unstable axon-like projections. Thus, this study identifies shifts in ciliary cAMP levels as a key regulator of cellular signal interpretation, and links primary cilium-mediated signal transduction to precise control of cytoskeletal organisation. Competing Interest Statement The authors have declared no competing interest.

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europepmc
last seen: 2026-05-20T01:45:00.602351+00:00
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License: CC-BY-4.0