Abstract
Symmetry breaking is involved in many developmental processes that form bodies and organs. One of them is the epithelial rotation of developing tubular and acinar organs. However, how epithelial cells move, how they break symmetry to define their common direction, and what function rotational epithelial motions have remains elusive. Here, we identify a dynamic actomyosin network that breaks symmetry at the basal surface of the Drosophila follicle epithelium of acinar-like primitive organs, called egg chambers, and may represent a candidate force-generation mechanism that underlies the unidirectional motion of this epithelial tissue. We provide evidence that the atypical cadherin Fat2, a key planar cell polarity regulator in Drosophila oogenesis, directs and orchestrates transmission of the intracellular actomyosin asymmetry cue onto a tissue plane in order to break planar actomyosin symmetry, facilitate epithelial rotation in the opposite direction, and direct the elongation of follicle cells. In contrast, loss of this rotational motion results in anisotropic non-muscle Myosin II pulses that are disorganized in plane and causes cell deformations in the epithelial tissue of Drosophila eggs. Our work demonstrates that atypical cadherins play an important role in the control of symmetry breaking of cellular mechanics in order to facilitate tissue motion and model epithelial tissue. We propose that their functions may be evolutionarily conserved in tubular/acinar vertebrate organs.
Highlights
Functional organ morphogenesis [1,2,3] has been linked to turns and rotations of epithelial sheets [4,5,6,7,8,9] relative to the organ or body anterior-posterior (AP) axis
It has been shown that microtubule (MT) growth predicts the direction of epithelial rotation in early and mid-oogenesis and that their planar symmetry breaking during rotation initiation is regulated by the atypical cadherin Fat2 [24, 25]
myosin II (Myo-II) behaviour is highly dynamic at the basal surface of the follicle epithelium
Summary
Functional organ morphogenesis [1,2,3] has been linked to turns and rotations of epithelial sheets [4,5,6,7,8,9] relative to the organ or body anterior-posterior (AP) axis. In contrast to the Drosophila hindgut and male genitalia where cell membranes adopt a specific form of asymmetry called planar cell chirality (PCC), the follicle epithelium displays no apparent membrane PCC (S1A Fig, Material and Methods), and different egg chamber units in one animal can rotate clockwise or anticlockwise performing more than three full rotations around their AP axis during early and mid-oogenesis [8, 15]. This suggests that an alternative, possibly myoID-independent, mechanism drives this collective cell behaviour. To test this hypothesis we investigated the function of Myo-II, its connection to the PCP pathway in Drosophila epithelial rotation, and the role of their interplay in this epithelial tissue
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