Circadian Rhythms in Rho1 Activity Regulate Neuronal Plasticity and Network Hierarchy

Author(s)

Petsakou, Afroditi; Blau, Justin; Sapsis, Themistoklis P.

Abstract

Neuronal plasticity helps animals learn from their environment. However, it is challenging to link specific changes in defined neurons to altered behavior. Here, we focus on circadian rhythms in the structure of the principal s-LNv clock neurons in Drosophila. By quantifying neuronal architecture, we observed that s-LNv structural plasticity changes the amount of axonal material in addition to cycles of fasciculation and defasciculation. We found that this is controlled by rhythmic Rho1 activity that retracts s-LNv axonal termini by increasing myosin phosphorylation and simultaneously changes the balance of pre-synaptic and dendritic markers. This plasticity is required to change clock network hierarchy and allow seasonal adaptation. Rhythms in Rho1 activity are controlled by clock-regulated transcription of Puratrophin-1-like (Pura), a Rho1 GEF. Since spinocerebellar ataxia is associated with mutations in human Puratrophin-1, our data support the idea that defective actin-related plasticity underlies this ataxia.

Date issued

2015-07

URI

http://hdl.handle.net/1721.1/107702

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Cell

Publisher

Elsevier

Citation

Petsakou, Afroditi, Themistoklis P. Sapsis, and Justin Blau. “Circadian Rhythms in Rho1 Activity Regulate Neuronal Plasticity and Network Hierarchy.” Cell 162.4 (2015): 823–835. © 2017 Elsevier

Version: Final published version

ISSN

0092-8674