AI Article Synopsis
- Mitochondria play a crucial role in cell functions and have their own genome (mtDNA), which is significant for stem cell differentiation, particularly in neural stem cells (NSCs).
- In our study, we observed that as NSCs differentiate, their mtDNA content dramatically increases, even though mitochondrial transcription factor A levels remain unchanged.
- By inhibiting mtDNA replication, we found that while neurogenesis was significantly reduced, gliogenesis was not affected, indicating that mtDNA replication is vital for the development of neurons in fetal NSCs but operates through mechanisms unrelated to energy production or reactive oxygen species levels.
Article Abstract
Mitochondria are unique organelles that have their own genome (mtDNA) and perform various pivotal functions within a cell. Recently, evidence has highlighted the role of mitochondria in the process of stem cell differentiation, including differentiation of neural stem cells (NSCs). Here we studied the importance of mtDNA function in the early differentiation process of NSCs in two cell culture models: the CGR8-NS cell line that was derived from embryonic stem cells by a lineage selection technique, and primary NSCs that were isolated from embryonic day 14 mouse fetal forebrain. We detected a dramatic increase in mtDNA content upon NSC differentiation to adapt their mtDNA levels to their differentiated state, which was not accompanied by changes in mitochondrial transcription factor A expression. As chemical mtDNA depletion by ethidium bromide failed to generate living ρ° cell lines from both NSC types, we used inhibition of mtDNA polymerase-γ by 2'-3'-dideoxycytidine to reduce mtDNA replication and subsequently cellular mtDNA content. Inhibition of mtDNA replication upon NSC differentiation reduced neurogenesis but not gliogenesis. The mtDNA depletion did not change energy production/consumption or cellular reactive oxygen species (ROS) content in the NSC model used. In conclusion, mtDNA replication is essential for neurogenesis but not gliogenesis in fetal NSCs through as yet unknown mechanisms, which, however, are largely independent of energy/ROS metabolism.
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