Achieving multifunctionality in a single, tissue-sized syncytiotrophoblast cell in humans.

The syncytiotrophoblast (STB) is a tissue-sized multinucleate cell in the human placenta that performs essential functions including molecular transport, metabolism, and hormone production-roles typically distributed across many cell types in multiple organs. To achieve these diverse tasks, the human STB is thought to regionally separate these functions by adapting its cytoplasmic structure, organelle distribution, and molecular composition across placental villous subtypes to meet local functional demands. How can a single, tissue-sized cytoplasm create localized cytoplasmic zones? Recent advances in single nucleus RNA sequencing (snRNAseq) in the human placenta and trophoblast organoids have revealed distinct nuclear subtypes within the STB, including a juvenile population recently incorporated into the syncytia, an oxygen-sensing nuclear subtype, and one that specializes in GTPase signaling and hormone production. Notably, the distribution of these subtypes changes throughout gestation in vivo and under varying culture conditions in vitro. These findings highlight a dynamic process of nuclear specialization that mirrors the functional diversity of the STB cytoplasm. In this review, we highlight research demonstrating both nuclear and cytoplasmic specialization in the STB and provide models for how this could be functionally established. Understanding the molecular mechanisms that enable the STB's ultrastructure to coordinate its diverse functions could illuminate novel therapeutic strategies for addressing pregnancy complications.

Duke Scholars

Author Amy Susanne Gladfelter Cell Biology