AI Article Synopsis
- Scientists studied how the spine develops in humans and mice, focusing on a special process in cells called the segmentation clock.
- They found that although human and mouse cells have different timing for this process, they still follow a similar pattern and are influenced by the same signals.
- This research helps us understand more about human development and how it might be similar to what happens in mice.
Article Abstract
The segmental organization of the vertebral column is established early in embryogenesis, when pairs of somites are rhythmically produced by the presomitic mesoderm (PSM). The tempo of somite formation is controlled by a molecular oscillator known as the segmentation clock. Although this oscillator has been well-characterized in model organisms, whether a similar oscillator exists in humans remains unknown. Genetic analyses of patients with severe spine segmentation defects have implicated several human orthologues of cyclic genes that are associated with the mouse segmentation clock, suggesting that this oscillator might be conserved in humans. Here we show that human PSM cells derived in vitro-as well as those of the mouse-recapitulate the oscillations of the segmentation clock. Human PSM cells oscillate with a period two times longer than that of mouse cells (5 h versus 2.5 h), but are similarly regulated by FGF, WNT, Notch and YAP signalling. Single-cell RNA sequencing reveals that mouse and human PSM cells in vitro follow a developmental trajectory similar to that of mouse PSM in vivo. Furthermore, we demonstrate that FGF signalling controls the phase and period of oscillations, expanding the role of this pathway beyond its classical interpretation in 'clock and wavefront' models. Our work identifying the human segmentation clock represents an important milestone in understanding human developmental biology.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7336868 | PMC |
| http://dx.doi.org/10.1038/s41586-019-1885-9 | DOI Listing |
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Article Synopsis
- The processes of primary and secondary neurulation, which lead to spinal cord formation, are not fully understood in humans due to difficulties accessing embryos at the relevant stages (3-7 weeks post-conception).
- Analysis of 108 human embryos reveals that while primary neurulation is similar to that in mice, it has distinct differences; secondary neurulation begins later and forms a single lumen, unlike the multiple lumens seen in chicks.
- Key differences in neurulation timing between humans and mice were noted, such as the rate of somite formation and the termination of axial elongation associated with apoptosis in the embryonic tailbud; these findings can aid current research on neurulation using stem cell-derived organoids
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