Genome-wide RNA structure changes during human neurogenesis drive gene regulatory networks

The distribution, dynamics and function of RNA structures in human development is under- explored. Here, we systematically assayed RNA structural dynamics and its relationship with gene expression, translation and decay during human neurogenesis. We observed that the human ESC transcriptome is globally more structurally accessible than that of differentiated cells; and undergo extensive RNA structure changes, particularly in the 3UTR. Additionally, RNA structure changes during differentiation is associated with translation and decay. We also identified stage-specific regulation as RBP and miRNA binding, as well as splicing is associated with structure changes during early and late differentiation, respectively. Further, RBPs serve as a major factor in structure remodelling and co-regulates additional RBPs and miRNAs through structure. We demonstrated an example of this by showing that PUM2-induced structure changes on LIN28A enable miR-30 binding. This study deepens our understanding of the wide-spread and complex role of RNA-based gene regulation during human development.