Abstract
Neural tube closure requires apical constriction during which contraction of the apical F-actin network forces the cell into a wedged shape, facilitating the folding of the neural plate into a tube. However, how F-actin assembly at the apical surface is regulated in mammalian neurulation remains largely unknown. We report here that formin homology 2 domain-containing 3 (Fhod3), a formin protein that mediates F-actin assembly, is essential for cranial neural tube closure in mouse embryos. We found that Fhod3 is expressed in the lateral neural plate but not in the floor region of the closing neural plate at the hindbrain. Consistently, in Fhod3-null embryos, neural plate bending at the midline occurred normally, but lateral plates seemed floppy and failed to flex dorsomedially. Because the apical accumulation of F-actin and constriction were impaired specifically at the lateral plates in Fhod3-null embryos, we concluded that Fhod3-mediated actin assembly contributes to lateral plate-specific apical constriction to advance closure. Intriguingly, Fhod3 expression at the hindbrain was restricted to neuromeric segments called rhombomeres. The rhombomere-specific accumulation of apical F-actin induced by the rhombomere-restricted expression of Fhod3 was responsible for the outward bulging of rhombomeres involving apical constriction along the anteroposterior axis, as rhombomeric bulging was less prominent in Fhod3-null embryos than in the wild type. Fhod3 thus plays a crucial role in the morphological changes associated with neural tube closure at the hindbrain by mediating apical constriction not only in the mediolateral but also in the anteroposterior direction, thereby contributing to tube closure and rhombomere segmentation, respectively.
Highlights
Neural tube closure requires apical constriction during which contraction of the apical F-actin network forces the cell into a wedged shape, facilitating the folding of the neural plate into a tube
To clarify the role of formin homology domain– containing 3 (Fhod3) during neural development in mice, we examined the effect of Fhod3 deficiency on neurulation
We identified the critical role of Fhod3 in neurulation during mouse embryonic development
Summary
Loss of Fhod prevents the rostrally directed closure of the neural tube at the hindbrain. It seems that Fhod depletion causes morphological changes in lateral neural plates, thereby resulting in abortion of rostrally directed closure I, which is most evident at the level of rhombomere 4. The apical accumulation of F-actin at the convex surface of bilateral neural plates of Fhod3null embryos was significantly decreased, the intensity at the lateral membranes was not substantially altered (Fig. 4C). It seems that Fhod promotes anteroposterior-oriented apical constriction by inducing the rhombomere-specific accumulation of F-actin Consistent with this idea, longitudinal sections of the neural tube in WT embryos showed uneven F-actin distribution along the anteroposterior axis; the intensity of apical F-actin in the rhombomere regions was relatively high compared with that in boundary regions (Fig. 8C). Contraction along the anteroposterior axis at the lateral plate, caused by the Fhod3-dependent accumulation of apical F-actin at the rhombomere centers, seems to be responsible for the morphological segmentation of rhombomeres
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