RhoA drives actin compaction to restrict axon regeneration and astrocyte reactivity after CNS injury

Neuron. 2021 Nov 3;109(21):3436-3455.e9. doi: 10.1016/j.neuron.2021.08.014. Epub 2021 Sep 10.

Abstract

An inhibitory extracellular milieu and neuron-intrinsic processes prevent axons from regenerating in the adult central nervous system (CNS). Here we show how the two aspects are interwoven. Genetic loss-of-function experiments determine that the small GTPase RhoA relays extracellular inhibitory signals to the cytoskeleton by adapting mechanisms set in place during neuronal polarization. In response to extracellular inhibitors, neuronal RhoA restricts axon regeneration by activating myosin II to compact actin and, thereby, restrain microtubule protrusion. However, astrocytic RhoA restricts injury-induced astrogliosis through myosin II independent of microtubules by activating Yes-activated protein (YAP) signaling. Cell-type-specific deletion in spinal-cord-injured mice shows that neuronal RhoA activation prevents axon regeneration, whereas astrocytic RhoA is beneficial for regenerating axons. These data demonstrate how extracellular inhibitors regulate axon regeneration, shed light on the capacity of reactive astrocytes to be growth inhibitory after CNS injury, and reveal cell-specific RhoA targeting as a promising therapeutic avenue.

Keywords: F-actin density; RhoA; YAP signaling; astrocyte reactivity; axon regeneration; microtubule protrusion; myosin II.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Actins* / metabolism
  • Animals
  • Astrocytes / metabolism
  • Axons* / metabolism
  • Central Nervous System / metabolism
  • Central Nervous System / pathology
  • Central Nervous System Diseases* / metabolism
  • Central Nervous System Diseases* / pathology
  • Mice
  • Nerve Regeneration* / physiology
  • rhoA GTP-Binding Protein* / metabolism

Substances

  • Actins
  • RhoA protein, mouse
  • rhoA GTP-Binding Protein