Organization principles of the embryonic cell cycle in Drosophila melanogaster

dc.contributor.advisor

Di Talia, Stefano

dc.contributor.author

Deneke, Victoria

dc.date.accessioned

2019-06-07T19:49:19Z

dc.date.available

2019-06-07T19:49:19Z

dc.date.issued

2019

dc.department

Cell Biology

dc.description.abstract

Early development in most metazoans is characterized by remarkably fast and coordinated cell cycles. Nonetheless, it is unclear what organizational principles underlie cell cycle synchronization across a large developing embryo. We found that cell cycle synchronization in Drosophila arises through the self-organized positioning of nuclei, which is regulated by the spatiotemporal dynamics of the cell cycle, cortical contractions, and cytoplasmic streaming. First, local Cdk1 downregulation at mitotic exit initiates the damped spreading of PP1 activity, which is responsible for recruiting myosin II to cortical regions that surround the nuclei, where gradients of contractility are generated. These gradients drive cortical and cytoplasmic flows that properly position the nuclei across the embryo. Uniform positioning of nuclei across the embryo is required for the emergence of synchronous cell cycles. Once at the surface of the embryo, nuclei undergo four metachronous cell cycles, which spread in a wave-like manner with remarkable speed across the large distance of the egg. Using a Cdk1 biosensor, we found that travelling waves of Cdk1 activity propagate through the embryo and synchronize the cell cycle during S-phase through an active mechanism, while mitotic events simply follow S-phase synchronization with a delay. Taken together, a self-organized mechanism that spreads nuclei uniformly is required early on in development to give rise to synchronous divisions. Cell cycle synchrony is then maintained by waves of Cdk1 activity, ensuring that all nuclei initiate the mid-blastula transition simultaneously. This work highlights the importance of chemical waves and cytoplasmic flows in the spatiotemporal regulation of the cell cycle of large embryos.

dc.identifier.uri

https://hdl.handle.net/10161/18791

dc.subject

Developmental biology

dc.subject

Cellular biology

dc.subject

Biophysics

dc.subject

Cell cycle

dc.subject

Chemical Waves

dc.subject

Cytoplasmic flows

dc.subject

Drosophila embryogenesis

dc.subject

Synchronization

dc.title

Organization principles of the embryonic cell cycle in Drosophila melanogaster

dc.type

Dissertation

Files

Original bundle

Now showing 1 - 1 of 1
Loading...
Thumbnail Image
Name:
Deneke_duke_0066D_15161.pdf
Size:
7.8 MB
Format:
Adobe Portable Document Format

Collections