A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience

Manon Rivagorda; David Romeo-Guitart; Victoria Blanchet; François Mailliet; Valérie Boitez; Natalie Barry; Dimitrije Milunov; Eleni Siopi; Nicolas Goudin; Stéphanie Moriceau; Chiara Guerrera; Michel Leibovici; Soham Saha; Patrice Codogno; Eugenia Morselli; Etienne Morel; Anne Sophie Armand; Franck Oury

doi:10.1038/s43587-024-00791-0

A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience

Manon Rivagorda, David Romeo-Guitart, Victoria Blanchet, François Mailliet, Valérie Boitez, Natalie Barry, Dimitrije Milunov, Eleni Siopi, Nicolas Goudin, Stéphanie Moriceau, Chiara Guerrera, Michel Leibovici, Soham Saha, Patrice Codogno, Eugenia Morselli, Etienne Morel, Anne Sophie Armand, Franck Oury^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Blood-borne factors are essential to maintain neuronal synaptic plasticity and cognitive resilience throughout life. One such factor is osteocalcin (OCN), a hormone produced by osteoblasts that influences multiple physiological processes, including hippocampal neuronal homeostasis. However, the mechanism through which this blood-borne factor communicates with neurons remains unclear. Here we show the importance of a core primary cilium (PC) protein–autophagy axis in mediating the effects of OCN. We found that the OCN receptor GPR158 is present at the PC of hippocampal neurons and mediates the regulation of autophagy machinery by OCN. During aging, autophagy and PC core proteins are reduced in neurons, and restoring their levels is sufficient to improve cognitive impairments in aged mice. Mechanistically, the induction of this axis by OCN is dependent on the PC-dependent cAMP response element-binding protein signaling pathway. Altogether, this study demonstrates that the PC–autophagy axis is a gateway to mediate communication between blood-borne factors and neurons, and it advances understanding of the mechanisms involved in age-related cognitive decline.

Original language	English
Article number	1318
Pages (from-to)	450-467
Number of pages	18
Journal	Nature Aging
Volume	5
Issue number	3
DOIs	https://doi.org/10.1038/s43587-024-00791-0
State	Published - 2025

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

ASJC Scopus subject areas

Neuroscience (miscellaneous)
Aging
Geriatrics and Gerontology

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Rivagorda, M., Romeo-Guitart, D., Blanchet, V., Mailliet, F., Boitez, V., Barry, N., Milunov, D., Siopi, E., Goudin, N., Moriceau, S., Guerrera, C., Leibovici, M., Saha, S., Codogno, P., Morselli, E., Morel, E., Armand, A. S., & Oury, F. (2025). A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience. Nature Aging, 5(3), 450-467. Article 1318. https://doi.org/10.1038/s43587-024-00791-0

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title = "A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience",

abstract = "Blood-borne factors are essential to maintain neuronal synaptic plasticity and cognitive resilience throughout life. One such factor is osteocalcin (OCN), a hormone produced by osteoblasts that influences multiple physiological processes, including hippocampal neuronal homeostasis. However, the mechanism through which this blood-borne factor communicates with neurons remains unclear. Here we show the importance of a core primary cilium (PC) protein–autophagy axis in mediating the effects of OCN. We found that the OCN receptor GPR158 is present at the PC of hippocampal neurons and mediates the regulation of autophagy machinery by OCN. During aging, autophagy and PC core proteins are reduced in neurons, and restoring their levels is sufficient to improve cognitive impairments in aged mice. Mechanistically, the induction of this axis by OCN is dependent on the PC-dependent cAMP response element-binding protein signaling pathway. Altogether, this study demonstrates that the PC–autophagy axis is a gateway to mediate communication between blood-borne factors and neurons, and it advances understanding of the mechanisms involved in age-related cognitive decline.",

author = "Manon Rivagorda and David Romeo-Guitart and Victoria Blanchet and Fran{\c c}ois Mailliet and Val{\'e}rie Boitez and Natalie Barry and Dimitrije Milunov and Eleni Siopi and Nicolas Goudin and St{\'e}phanie Moriceau and Chiara Guerrera and Michel Leibovici and Soham Saha and Patrice Codogno and Eugenia Morselli and Etienne Morel and Armand, {Anne Sophie} and Franck Oury",

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doi = "10.1038/s43587-024-00791-0",

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Rivagorda, M, Romeo-Guitart, D, Blanchet, V, Mailliet, F, Boitez, V, Barry, N, Milunov, D, Siopi, E, Goudin, N, Moriceau, S, Guerrera, C, Leibovici, M, Saha, S, Codogno, P, Morselli, E, Morel, E, Armand, AS & Oury, F 2025, 'A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience', Nature Aging, vol. 5, no. 3, 1318, pp. 450-467. https://doi.org/10.1038/s43587-024-00791-0

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T1 - A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience

AU - Rivagorda, Manon

AU - Romeo-Guitart, David

AU - Blanchet, Victoria

AU - Mailliet, François

AU - Boitez, Valérie

AU - Barry, Natalie

AU - Milunov, Dimitrije

AU - Siopi, Eleni

AU - Goudin, Nicolas

AU - Moriceau, Stéphanie

AU - Guerrera, Chiara

AU - Leibovici, Michel

AU - Saha, Soham

AU - Codogno, Patrice

AU - Morselli, Eugenia

AU - Morel, Etienne

AU - Armand, Anne Sophie

AU - Oury, Franck

PY - 2025/3

Y1 - 2025/3

N2 - Blood-borne factors are essential to maintain neuronal synaptic plasticity and cognitive resilience throughout life. One such factor is osteocalcin (OCN), a hormone produced by osteoblasts that influences multiple physiological processes, including hippocampal neuronal homeostasis. However, the mechanism through which this blood-borne factor communicates with neurons remains unclear. Here we show the importance of a core primary cilium (PC) protein–autophagy axis in mediating the effects of OCN. We found that the OCN receptor GPR158 is present at the PC of hippocampal neurons and mediates the regulation of autophagy machinery by OCN. During aging, autophagy and PC core proteins are reduced in neurons, and restoring their levels is sufficient to improve cognitive impairments in aged mice. Mechanistically, the induction of this axis by OCN is dependent on the PC-dependent cAMP response element-binding protein signaling pathway. Altogether, this study demonstrates that the PC–autophagy axis is a gateway to mediate communication between blood-borne factors and neurons, and it advances understanding of the mechanisms involved in age-related cognitive decline.

AB - Blood-borne factors are essential to maintain neuronal synaptic plasticity and cognitive resilience throughout life. One such factor is osteocalcin (OCN), a hormone produced by osteoblasts that influences multiple physiological processes, including hippocampal neuronal homeostasis. However, the mechanism through which this blood-borne factor communicates with neurons remains unclear. Here we show the importance of a core primary cilium (PC) protein–autophagy axis in mediating the effects of OCN. We found that the OCN receptor GPR158 is present at the PC of hippocampal neurons and mediates the regulation of autophagy machinery by OCN. During aging, autophagy and PC core proteins are reduced in neurons, and restoring their levels is sufficient to improve cognitive impairments in aged mice. Mechanistically, the induction of this axis by OCN is dependent on the PC-dependent cAMP response element-binding protein signaling pathway. Altogether, this study demonstrates that the PC–autophagy axis is a gateway to mediate communication between blood-borne factors and neurons, and it advances understanding of the mechanisms involved in age-related cognitive decline.

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A primary cilia–autophagy axis in hippocampal neurons is essential to maintain cognitive resilience

Abstract

Bibliographical note

ASJC Scopus subject areas

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