Biological rhythms are widespread, allowing organisms to temporally organize their behavior and metabolism in advantageous ways. Such proper timing of molecular and cellular events is critical to their development and health. This is best understood in the case of the circadian clock that orchestrates the daily sleep/wake cycle of organisms. Temporal rhythms can also be used for spatial organization, if information from an oscillating system can be recorded within the tissue in a manner that leaves a permanent periodic pattern. One example of this is the "segmentation clock" used by the vertebrate embryo to rhythmically and sequentially subdivide its elongating body axis. The segmentation clock moves with the elongation of the embryo, such that its period sets the segment length as the tissue grows outward. Although the study of this system is still relatively young compared to the circadian clock, outlines of molecular, cellular, and tissue-level regulatory mechanisms of timing have emerged. The question remains, however, is it truly a clock? Here we seek to introduce the segmentation clock to a wider audience of chronobiologists, focusing on the role and control of timing in the system. We compare and contrast the segmentation clock with the circadian clock, and propose that the segmentation clock is actually an oscillatory ruler, with a primary function to measure embryonic space.
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| http://dx.doi.org/10.1111/dgd.12242 | DOI Listing |
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- 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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