hnRNPL expression dynamics in the embryo and placenta.

Heterogeneous nuclear ribonucleoprotein L (hnRNPL) is a conserved RNA binding protein (RBP) that plays an important role in the alternative splicing of gene transcripts, and thus in the generation of specific protein isoforms. Global deficiency in hnRNPL in mice results in preimplantation embryonic lethality at embryonic day (E) 3.5. To begin to understand the contribution of hnRNPL-regulated pathways in the normal development of the embryo and placenta, we determined hnRNPL expression profile and subcellular localization throughout development. Proteome and Western blot analyses were employed to determine hnRNPL abundance between E3.5 and E17.5. Histological analyses supported that the embryo and implantation site display distinct hnRNPL localization patterns. In the fully developed mouse placenta, nuclear hnRNPL was observed broadly in trophoblasts, whereas within the implantation site a discrete subset of cells showed hnRNPL outside the nucleus. In the first-trimester human placenta, hnRNPL was detected in the undifferentiated cytotrophoblasts, suggesting a role for this factor in trophoblast progenitors. Parallel in vitro studies utilizing Htr8 and Jeg3 cell lines confirmed expression of hnRNPL in cellular models of human trophoblasts. These studies [support] coordinated regulation of hnRNPL during the normal developmental program in the mammalian embryo and placenta.

SLC20a1/PiT-1 is required for chorioallantoic placental morphogenesis.

The placenta mediates the transport of nutrients, such as inorganic phosphate (Pi), between the maternal and fetal circulatory systems. The placenta itself also requires high levels of nutrient uptake as it develops to provide critical support for fetal development. This study aimed to determine placental Pi transport mechanisms using in vitro and in vivo models. We observed that Pi (P33) uptake in BeWo cells is sodium dependent and that SLC20A1/Slc20a1 is the most highly expressed placental sodium-dependent transporter in mouse (microarray), human cell line (RT-PCR) and term placenta (RNA-seq), supporting that normal growth and maintenance of the mouse and human placenta requires SLC20A1/Slc20a1. Slc20a1 wild-type (Slc20a1+/+) and knockout (Slc20a1-/-) mice were produced through timed intercrosses and displayed yolk sac angiogenesis failure as expected at E10.5. E9.5 tissues were analyzed to test whether placental morphogenesis requires Slc20a1. At E9.5, the developing placenta was reduced in size in Slc20a1-/-. Multiple structural abnormalities were also observed in the Slc20a1-/-chorioallantois. We determined that monocarboxylate transporter 1 protein (MCT1+) cells were reduced in developing Slc20a1-/-placenta, confirming that Slc20a1 loss reduced trophoblast syncytiotrophoblast 1 (SynT-I) coverage. Next, we examined the cell type-specific Slc20a1 expression and SynT molecular pathways in silico and identified Notch/Wnt as a pathway of interest that regulates trophoblast differentiation. We further observed that specific trophoblast lineages express Notch/Wnt genes that associate with endothelial cell tip-and-stalk cell markers. In conclusion, our findings support that Slc20a1 mediates the symport of Pi into SynT cells, providing critical support for their differentiation and angiogenic mimicry function at the developing maternal-fetal interface.

Interaction of extraembryonic microglia and neonatal brain development.

Microglia are resident immune cells in the central nervous system (CNS), which, in a healthy state, promote CNS homeostasis and respond to CNS injury. In contrast, microglia are also implicated in pathological conditions where they may contribute to neural damage. Primitive microglia arise from extraembryonic progenitors in the yolk sac (YS). The extraembryonic origins of primitive microglia are distinct from other tissue macrophages. The YS is the first site of hematopoiesis in development. Uniquely, microglial pregenital cells in the mouse derive from an early myeloid branch of the hematopoietic lineage in the YS. Microglia are critical in several key stages of physiological brain development, including embryonic vasculogenesis, immunosurveillance, and neurogenesis. Abnormal microglial function has been linked to neurodevelopmental and neurodegenerative diseases, although mechanistic roles in disease etiology remain incompletely understood. Knowledge of species-specific differences between human, murine and other animal models is also critical to understanding translational relevance to human health and disease as biomedical understanding of the importance of primitive microglia advances. This significance drives the importance of understanding, comparatively, the extraembryonic origins and developmental mechanisms whereby human primitive microglia differentiate and migrate to inform translational research. A better understanding of the molecular drivers may lead to biomarkers and/or preventative or therapeutic measures for neonatal brain development and neurodegenerative diseases. Herein, the role of microglia in neonatal brain development is discussed, current understandings of the developmental origins of microglia are described, the ontogeny and phylogeny of microglia, and implications of in vitro microglia-like cell differentiation, with a specific interest on neurodegenerative diseases, are reviewed. Together, these emphasize the importance of leveraging the extraembryonic origins of microglia to not only better understand neurodevelopment and neurodegenerative diseases, but also to develop protective measures that are specific to human microglia.

Cellular Complexity of Hemochorial Placenta: Stem Cell Populations, Insights from scRNA-seq, and SARS-CoV-2 Susceptibility.

Purpose of Review: The placenta is a transient organ that forms de novo and serves a critical role in supporting fetal growth and development. Placental oxygen, nutrients, and waste are transported through processes that depend on vascular structure and cell type-specific expression and localization of membrane transporters. Understanding how the placenta develops holds great significance for maternal-fetal medicine. The purpose of this review is to examine current information regarding placental progenitor populations. Recent Findings: Recent advancements in single-cell RNA sequencing (scRNA-seq) provide unprecedented depth for the investigation of cell type-specific gene expression patterns in the placenta. Thus far, several mouse placenta scRNA-seq studies have been conducted which produced and analyzed transcriptomes of placental progenitors and cells of the fully developed placenta between embryonic day (E) 7.0 and E12.5. Together with human placenta scRNA-seq data which, in part, has been produced through coordinated research campaigns in the scientific community to understand the potential for SARS-CoV-2 infection, these mammalian studies lend fundamental insight into the cellular and molecular composition of hemochorial placentae found in both mouse and human. Summary: Single-cell placenta research has advanced understanding of tissue-resident stem cells and molecules that are poised to support maternal-fetal communication and nutrient transport. Herein, we provide context for these recent findings by reviewing placental anatomy and cell populations, and discuss recent scRNA-seq mouse placenta findings. Further research is needed to evaluate the utility of placental stem cells in the development of new therapeutic approaches for the treatment of wound healing and disease.