Symmetry-­breaking in branching epithelia: cells on micro-patterns under flow challenge the hypothesis of positive feedback by a secreted autocrine inhibitor of motility.

Kimberly Martin, Xiaofei Yuan, Greg Stimac, Kieran Bannerman, Jamie Anderson, Chloe Roy, Fokion Glykofrydis, Huabing Yin, Jamie Davies

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

Branching morphogenesis of epithelia involves division of cells into leader (tip) and follower (stalk) cells. Published work on cell lines in culture has suggested that symmetry-breaking takes place via a secreted autocrine inhibitor of motility, the inhibitor accumulating more in concave regions of the culture boundary, slowing advance of cells there, and less in convex areas, allowing advance and a further exaggeration of the concave/convex difference. Here we test this hypothesis using a two-dimensional culture system that includes strong flow conditions to remove accumulating diffusible secretions. We find that, while motility does indeed follow boundary curvature in this system, flow makes no difference: this challenges the hypothesis of control by a diffusible secreted autocrine inhibitor.
Original languageEnglish
JournalJournal of Anatomy
Early online date29 Mar 2017
DOIs
Publication statusE-pub ahead of print - 29 Mar 2017

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