| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 2039707 | Cell Reports | 2016 | 9 Pages |
•Microtubule plus-end polarization in the Drosophila germarium breaks chiral symmetry•Germarial microtubule organization is required for subsequent planar cell polarity•Atypical cadherin Fat2 regulates germarial microtubule plus-end polarity, not alignment•Fat2 acts prior to rotation to control follicle PCP and elongation
SummaryPlanar cell polarity (PCP) information is a critical determinant of organ morphogenesis. While PCP in bounded epithelial sheets is increasingly well understood, how PCP is organized in tubular and acinar tissues is not. Drosophila egg chambers (follicles) are an acinus-like “edgeless epithelium” and exhibit a continuous, circumferential PCP that does not depend on pathways active in bounded epithelia; this follicle PCP directs formation of an ellipsoid rather than a spherical egg. Here, we apply an imaging algorithm to “unroll” the entire 3D tissue surface and comprehensively analyze PCP onset. This approach traces chiral symmetry breaking to plus-end polarity of microtubules in the germarium, well before follicles form and rotate. PCP germarial microtubules provide chiral information that predicts the direction of whole-tissue rotation as soon as independent follicles form. Concordant microtubule polarity, but not microtubule alignment, requires the atypical cadherin Fat2, which acts at an early stage to translate plus-end bias into coordinated actin-mediated collective cell migration. Because microtubules are not required for PCP or migration after follicle rotation initiates, while dynamic actin and extracellular matrix are, polarized microtubules lie at the beginning of a handoff mechanism that passes early chiral PCP of the cytoskeleton to a supracellular planar polarized extracellular matrix and elongates the organ.
Graphical AbstractFigure optionsDownload full-size imageDownload as PowerPoint slide
