Brains in metamorphosis: reprogramming cell identity within the central nervous system

P Arlotta, B Berninger - Current opinion in neurobiology, 2014 - Elsevier
P Arlotta, B Berninger
Current opinion in neurobiology, 2014Elsevier
Highlights•We review experimental evidence for the feasibility of direct reprogramming
within the brain.•First we discuss achievements in the attempt of glia-to-neuron
reprogramming in vivo.•This is followed by reviewing the state of the art of neuron-to-neuron
reprogramming.•The challenges ahead of in vivo lineage reprogramming are
discussed.During embryonic development, uncommitted pluripotent cells undergo
progressive epigenetic changes that lock them into a final differentiated state. Can …
Highlights
  • We review experimental evidence for the feasibility of direct reprogramming within the brain.
  • First we discuss achievements in the attempt of glia-to-neuron reprogramming in vivo.
  • This is followed by reviewing the state of the art of neuron-to-neuron reprogramming.
  • The challenges ahead of in vivo lineage reprogramming are discussed.
During embryonic development, uncommitted pluripotent cells undergo progressive epigenetic changes that lock them into a final differentiated state. Can mammalian cells change identity within the living organism? Direct lineage reprogramming of cells has attracted attention as a means to achieve organ regeneration. However, it is unclear whether cells in the CNS are endowed with the plasticity to reprogram. Neurons in particular are considered among the most immutable cell types, able to retain their class-specific traits for the lifespan of the organism. Here we focus on two experimental paradigms, glia-to-neuron and neuron-to-neuron conversion, to consider how lineage reprogramming has challenged the notion of CNS immutability, paving the way for the application of reprogramming strategies to reshape neurons and circuits in vivo.
Elsevier