Cerebral organoids display dynamic clonal growth and tunable tissue replenishment.
Dominik LindenhoferSimon HaendelerChristopher EskJamie B LittleboyClarisse Brunet AvalosJulia NaasFlorian G PflugEline G P van de VenDaniel ReumannAlexandre D BaffetArndt von HaeselerJürgen Arthur KnoblichPublished in: Nature cell biology (2024)
During brain development, neural progenitors expand through symmetric divisions before giving rise to differentiating cell types via asymmetric divisions. Transition between those modes varies among individual neural stem cells, resulting in clones of different sizes. Imaging-based lineage tracing allows for lineage analysis at high cellular resolution but systematic approaches to analyse clonal behaviour of entire tissues are currently lacking. Here we implement whole-tissue lineage tracing by genomic DNA barcoding in 3D human cerebral organoids, to show that individual stem cell clones produce progeny on a vastly variable scale. By using stochastic modelling we find that variable lineage sizes arise because a subpopulation of lineages retains symmetrically dividing cells. We show that lineage sizes can adjust to tissue demands after growth perturbation via chemical ablation or genetic restriction of a subset of cells in chimeric organoids. Our data suggest that adaptive plasticity of stem cell populations ensures robustness of development in human brain organoids.
Keyphrases
- single cell
- stem cells
- induced apoptosis
- induced pluripotent stem cells
- cell therapy
- cell cycle arrest
- neural stem cells
- cell fate
- endothelial cells
- single molecule
- copy number
- high resolution
- oxidative stress
- endoplasmic reticulum stress
- gene expression
- signaling pathway
- cerebral ischemia
- machine learning
- resting state
- mass spectrometry
- atrial fibrillation
- circulating tumor
- blood brain barrier
- functional connectivity
- cerebral blood flow
- genetic diversity