Thyroid hormone promotes fetal neurogenesis
Federico Salas-Lucia, … , Randy Stout, Antonio C. Bianco
Federico Salas-Lucia, … , Randy Stout, Antonio C. Bianco
Published September 4, 2025
Citation Information: JCI Insight. 2025;10(19):e194445. https://doi.org/10.1172/jci.insight.194445.
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Research Article Endocrinology Neuroscience

Thyroid hormone promotes fetal neurogenesis

Abstract

Maternal low thyroxine (T4) serum levels during the first trimester of pregnancy correlate with cerebral cortex volume and mental development of the progeny, but why neural cells during early fetal brain development are vulnerable to maternal T4 levels remains unknown. In this study, using iPSCs obtained from a boy with a loss-of-function mutation in MCT8 — a transporter previously identified as critical for thyroid hormone uptake and action in neural cells — we demonstrate that thyroid hormone induces transcriptional changes that promote the progression of human neural precursor cells along the dorsal projection trajectory. Consistent with these findings, single-cell, spatial, and bulk transcriptomics from MCT8-deficient cerebral organoids and cultures of human neural precursor cells underscored the necessity for optimal thyroid hormone levels for these cells to differentiate into neurons. The controlled intracellular activation of T4 signaling occurs through the transient expression of the enzyme type 2 deiodinase, which converts T4 into its active form, T3, alongside the coordinated expression of thyroid hormone nuclear receptors. The intracellular activation of T4 in neural precursor cells results in transcriptional changes important for their division mode and cell cycle progression. Thus, T4 is essential for fetal neurogenesis, highlighting the importance of adequate treatment for mothers with hypothyroidism.

Authors

Federico Salas-Lucia, Sergio Escamilla, Amanda Charest, Hanzi Jiang, Randy Stout, Antonio C. Bianco

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Figure 1

scRNA-seq analysis of D50 Control- and MCT8-COs.

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scRNA-seq analysis of D50 Control- and MCT8-COs. (A) Schematic represent...
(A) Schematic representation of generating D50 MCT8-COs and obtaining single-cell suspension for sc-RNA-seq analysis. (B) UMAP plot showing the cell clusters identified by principal component analysis in the indicated COs. (C) UMAP plots showing the distribution of markers for NPCs and neurons. (D) Dot plot showing the relative expression levels of the gene markers used to identify each cell population. (E) UMAP plot showing the cell types identified by manual curation in control COs. (F) Dot plot showing the relative expression levels of SLC16A2, THRB, and THRA in each cell population of the dorsal projection trajectory. (G) Interpretation of sequential gene expression changes during dorsal projection trajectory progression. (H) UMAP plot showing the cell types identified by manual curation in MCT8-COs. (I) Histogram of the relative number of cells in control and MCT8-COs. (J) Volcano plots showing the distribution of differentially expressed genes in MCT8-deficient versus control COs. iPSCs, induced pluripotent stem cells; COs, cortical organoids; NPCs, neural precursor cells; IPCs, intermediate precursor cells; DPT, dorsal projection trajectory; UMAP, uniform manifold approximation and projection. The χ2 test was used for multiple comparisons and pairwise cell proportions. ****P < 0.0001. Differentially expressed gene thresholds: P < 0.05 and average log2(fold change) = 0.26.