Abstract
Trophoblast giant cells (TGCs) are one of the cell types that form the placenta and play multiple essential roles in maintaining pregnancy in rodents. TGCs have large, polyploid nuclei resulting from endoreduplication. While previous studies have shown distinct gene expression profiles of TGCs, their chromatin structure remains largely unknown. An appropriate combination of canonical and non-canonical histones, also known as histone variants, allows each cell to exert its cell type-specific functions. Here, we aimed to reveal the dynamics of histone usage and chromatin structure during the differentiation of trophoblast stem cells (TSCs) into TGCs. Although the expression of most genes encoding canonical histones was downregulated, the expression of a few genes encoding histone variants such as H2AX, H2AZ, and H3.3 was maintained at a relatively high level in TGCs. Both the micrococcal nuclease digestion assay and nucleosome stability assay using a microfluidic device indicated that chromatin became increasingly loose as TSCs differentiated. Combinatorial experiments involving H3.3-knockdown and -overexpression demonstrated that variant H3.3 resulted in the formation of loose nucleosomes in TGCs. In conclusion, our study revealed that TGCs possessed loose nucleosomes owing to alterations in their histone composition during differentiation.
Highlights
The rodent placenta consists of a labyrinth zone and junctional zone
We found that Trophoblast giant cells (TGCs) nuclei had loose nucleosomes
The variation in histone subtypes/ variants decreased in TGCs, and relatively high expression of the histone variants H2AX, H2AZ, and H3.3 was observed
Summary
The rodent placenta consists of a labyrinth zone and junctional zone. The latter is further divided into the spongiotrophoblast and trophoblast giant cell (TGC) layers[1,2,3]. It was revealed that there were a few under- and over-replicated regions in the TGC genome, which suggested that their genomic DNA formed a polytene structure[6,7]. To organize such an unusual genome, TGCs are expected to possess a unique chromatin structure that has not been explored in details. Genes for histone variants are located away from the gene clusters and code for higher variations in amino acid sequences than canonical histones[15,16]. We examined the nucleosomal content, chromatin structure, and histone mobility of TGCs using a trophoblast stem cell (TSC) differentiation system[21], and observed that TGCs had loose nucleosome structures incorporated with histone variants, such as H2AX and H3.3
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