1. Cell-autonomous generation of the wave pattern within the vertebrate segmentation clock
- Author
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Bercowsky-Rama A, Laurel Rohde, Guillaume Valentin, Naganathan, Ravi A. Desai, Andrew C. Oates, Frank Jülicher, Daniele Soroldoni, Strnad P, and Jose Negrete
- Subjects
Wavefront ,Segmentation Clock ,biology ,Computer science ,business.industry ,Vertebrate ,Pattern recognition ,Kinematic wave ,Position (vector) ,Cell autonomous ,biology.animal ,Segmentation ,Timer ,Artificial intelligence ,business - Abstract
Sequential segmentation of the body axis is fundamental to vertebrate embryonic patterning. This relies on the segmentation clock, a multi-cellular oscillating genetic-network, which mainifests as tissue-level kinematic waves of gene expression that arrest at the position of each new segment. How this hallmark wave pattern is generated is an open question. We compare cellular-resolution oscillatory patterns in the embryo to those generated cell-autonomously in culture without extrinsic signals. We find striking similarity, albeit with greater variability in the timing of clock arrest in culture. Our simple physical description of a clock controlled by a noisy cell-intrinsic timer captures these dynamics. We propose the segmentation clock integrates an intrinsic, timer-driven oscillatory program, which underlies the waves and arrest, with extrinsic cues regulating the intrinsic timer’s duration and precision.One-sentence SummarySegmentation clock and wavefront activities underlying tissue-level wave patterns are cell-autonomous properties in the PSM.
- Published
- 2021
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