AI Article Synopsis
- Endoderm formation in mammalian embryos begins in the blastocyst stage and continues during gastrulation, where primitive cells separate into distinct lineages.
- Researchers modeled definitive endoderm formation using early primitive ectoderm-like cells derived from embryonic stem cells, identifying key markers like Spink3 and Trh during the differentiation process.
- The study highlights the complexity of definitive endoderm lineages, suggesting that variations in culture conditions can influence the differentiation of these cells, emphasizing the need for refined protocols for proper progenitor formation in future research.
Article Abstract
Endoderm formation in the mammalian embryo occurs first in the blastocyst, when the primitive endoderm and pluripotent cells resolve into separate lineages, and again during gastrulation, when the definitive endoderm progenitor population emerges from the primitive streak. The formation of the definitive endoderm can be modeled using pluripotent cell differentiation in culture. The differentiation of early primitive ectoderm-like (EPL) cells, a pluripotent cell population formed from embryonic stem (ES) cells, was used to identify and characterize definitive endoderm formation. Expression of serine peptidase inhibitor, Kazal type 3 (Spink3) was detected in EPL cell-derived endoderm, and in a band of endoderm immediately distal to the embryonic-extra-embryonic boundary in pregastrula and gastrulating embryos. Later expression marked a region of endoderm separating the yolk sac from the developing gut. In the embryo, Spink3 expression marked a region of endoderm comprising the distal visceral endoderm, as determined by an endocytosis assay, and the proximal region of the definitive endoderm. This region was distinct from the more distal definitive endoderm population, marked by thyrotropin-releasing hormone (Trh). Endoderm expressing either Spink3 or Trh could be formed during EPL cell differentiation, and the prevalence of these populations could be influenced by culture medium and growth factor addition. Moreover, further differentiation suggested that the potential of these populations differed. These approaches have revealed an unexpected complexity in the definitive endoderm lineage, a complexity that will need to be accommodated in differentiation protocols to ensure the formation of the appropriate definitive endoderm progenitor in the future.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4048981 | PMC |
| http://dx.doi.org/10.1089/biores.2014.0010 | DOI Listing |
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