Abstract
Mutations in the thyroid hormone receptor α 1 gene (THRA) have recently been identified as a cause of intellectual deficit in humans. Patients present with structural abnormalities including microencephaly, reduced cerebellar volume and decreased axonal density. Here, we show that directed differentiation of THRA mutant patient-derived induced pluripotent stem cells to forebrain neural progenitors is markedly reduced, but mutant progenitor cells can generate deep and upper cortical layer neurons and form functional neuronal networks. Quantitative lineage tracing shows that THRA mutation-containing progenitor cells exit the cell cycle prematurely, resulting in reduced clonal output. Using a micropatterned chip assay, we find that spatial self-organization of mutation-containing progenitor cells in vitro is impaired, consistent with down-regulated expression of cell-cell adhesion genes. These results reveal that thyroid hormone receptor α1 is required for normal neural progenitor cell proliferation in human cerebral cortical development. They also exemplify quantitative approaches for studying neurodevelopmental disorders using patient-derived cells in vitro.
Highlights
Mutations in thyroid hormone receptor α1 cause premature neurogenesis and progenitor cell depletion in human cortical development
We report that mutations in the thyroid hormone receptor α1 gene (THRA) that result in intellectual disability reduce brain size
Based on the findings of a recent in vivo genetic labeling study of cortical neurogenesis in mouse, we presumed that RGs transit from a phase of symmetrical proliferation to a neurogenic phase, in which they divide asymmetrically to give rise to intermediate progenitor cells (IPCs) with variable but limited neurogenic potential [32]. We found that this model could largely account for differences in the clonal behavior of THRA mutation-containing vs. control cells, including the distribution of clone size and composition, under the single assumption that THRA mutation-containing RGs differentiated into IPCs at a higher rate compared with control RGs (Fig. 6 B and C)
Summary
Mutations in thyroid hormone receptor α1 cause premature neurogenesis and progenitor cell depletion in human cortical development. Using a micropatterned chip assay, we find that spatial self-organization of mutation-containing progenitor cells in vitro is impaired, consistent with down-regulated expression of cell–cell adhesion genes. These results reveal that thyroid hormone receptor α1 is required for normal neural progenitor cell proliferation in human cerebral cortical development. They exemplify quantitative approaches for studying neurodevelopmental disorders using patient-derived cells in vitro.
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