Researchers have identified factors that spark the formation of pluripotent cells. Their findings, published in Developmental Cell, shed light on human embryonic development and help research into cell reprogramming and assisted conception.
Embryonic stem cells are widely known for their ability to differentiate into any cell type - a state called pluripotency. This state is short lived in the embryo, but is essential to normal development. In this study, the researchers mapped when and where genes were expressed (turned on or off) during early development of the mouse and common marmoset, a nonhuman primate species.
This allowed them to pinpoint changes that regulate pluripotency in both mammals. They analyzed the complex network of gene regulation that supports pluripotency, looking closely at how this network comes together and later collapses as cells exit the pluripotent state to become specialized cell types.
"Our goal was to generate a comprehensive map of gene expression in the early stages of embryogenesis in the mouse, which has traditionally been the best model for mammalian development, and to see how that knowledge could be translated to primates," explains Paul Bertone of the Wellcome Trust-MRC Stem Cell Institute.
To compare pluripotent cells in rodents and primates, the researchers used single-cell RNA sequencing on small clusters of cells (8-20 cells) to establish precise gene-expression patterns for specific stages of early development. The results provide a framework for understanding the emergence and progression of pluripotency in different mammals.
"Many of the genes that give rise to the pluripotent identity in mice were also expressed in marmoset, demonstrating a common foundation for pluripotency in mammals," says Austin Smith, also of the Stem Cell Institute. "But there were some differences in signaling pathways between the two species, indicating that lineage specification in primates is not entirely conserved."
"We found that WNT signaling in the marmoset is critical for normal differentiation of one of the first three cell lineages to emerge," Paul continues. "Inhibiting this pathway has a profound effect - one of those lineages is subsumed by pluripotent cells rather than forming correctly. It will be interesting to see through in vitro studies whether WNT and perhaps other pathways are similarly utilized in humans."
This highly interdisciplinary study blends traditional embryology, genomics and bioinformatics. The result is a valuable resource for identifying the factors and pathways that regulate pluripotency in different mammals. The findings can also be used to optimize embryonic stem-cell derivation, and reprogramming to pluripotency, in cell cultures. The knowledge gained helps researchers understand early lineage decisions in embryonic cells, potentially leading to improved methods for human blastocyst development for assisted conception.