Publication date: 8 August 2017
Source:Cell Reports, Volume 20, Issue 6
Author(s): Cristina Valensisi, Colin Andrus, Sam Buckberry, Naresh Doni Jayavelu, Riikka J. Lund, Ryan Lister, R. David Hawkins
We currently lack a comprehensive understanding of the mechanisms underlying neural tube formation and their contributions to neural tube defects (NTDs). Developing a model to study such a complex morphogenetic process, especially one that models human-specific aspects, is critical. Three-dimensional, human embryonic stem cell (hESC)-derived neural rosettes (NRs) provide a powerful resource for in vitro modeling of human neural tube formation. Epigenomic maps reveal enhancer elements unique to NRs relative to 2D systems. A master regulatory network illustrates that key NR properties are related to their epigenomic landscapes. We found that folate-associated DNA methylation changes were enriched within NR regulatory elements near genes involved in neural tube formation and metabolism. Our comprehensive regulatory maps offer insights into the mechanisms by which folate may prevent NTDs. Lastly, our distal regulatory maps provide a better understanding of the potential role of neurological-disorder-associated SNPs.
Graphical abstract
Teaser
Neural rosettes offer a 3D model of neural tube development. Valensisi et al. show that these cells have distinct epigenomic landscapes compared to 2D neural stem cells. cis-regulatory elements identified in NRs harbor folate-associated CpGs, which may be important during neural tube development, and neurodevelopmental-disorder-associated variants.http://ift.tt/2uoH7Pv
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