Prion protein cleavage fragments regulate adult neural stem cell quiescence through redox modulation of mitochondrial fission and SOD2 expression.
Steven John CollinsCarolin TumpachBradley R GrovemanSimon C DrewCathryn L HaighPublished in: Cellular and molecular life sciences : CMLS (2018)
Neurogenesis continues in the post-developmental brain throughout life. The ability to stimulate the production of new neurones requires both quiescent and actively proliferating pools of neural stem cells (NSCs). Actively proliferating NSCs ensure that neurogenic demand can be met, whilst the quiescent pool makes certain NSC reserves do not become depleted. The processes preserving the NSC quiescent pool are only just beginning to be defined. Herein, we identify a switch between NSC proliferation and quiescence through changing intracellular redox signalling. We show that N-terminal post-translational cleavage products of the prion protein (PrP) induce a quiescent state, halting NSC cellular growth, migration, and neurite outgrowth. Quiescence is initiated by the PrP cleavage products through reducing intracellular levels of reactive oxygen species. First, inhibition of redox signalling results in increased mitochondrial fission, which rapidly signals quiescence. Thereafter, quiescence is maintained through downstream increases in the expression and activity of superoxide dismutase-2 that reduces mitochondrial superoxide. We further observe that PrP is predominantly cleaved in quiescent NSCs indicating a homeostatic role for this cascade. Our findings provide new insight into the regulation of NSC quiescence, which potentially could influence brain health throughout adult life.
Keyphrases
- neural stem cells
- reactive oxygen species
- oxidative stress
- stem cells
- poor prognosis
- platelet rich plasma
- binding protein
- healthcare
- dna binding
- white matter
- hydrogen peroxide
- signaling pathway
- protein protein
- multiple sclerosis
- mental health
- bone marrow
- young adults
- childhood cancer
- social media
- african american
- electron transfer
- brain injury