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Basal actomyosin pulses expand epithelium coordinating cell flattening and tissue elongation.

Shun LiZong-Yuan LiuHao LiSijia ZhouJiaying LiuNingwei SunKai-Fu YangVanessa DougadosThomas MangeatKarine BelguiseXi-Qiao FengYiyao LiuXiao-Bo Wang
Published in: Nature communications (2024)
Actomyosin networks constrict cell area and junctions to alter cell and tissue shape. However, during cell expansion under mechanical stress, actomyosin networks are strengthened and polarized to relax stress. Thus, cells face a conflicting situation between the enhanced actomyosin contractile properties and the expansion behaviour of the cell or tissue. To address this paradoxical situation, we study late Drosophila oogenesis and reveal an unusual epithelial expansion wave behaviour. Mechanistically, Rac1 and Rho1 integrate basal pulsatile actomyosin networks with ruffles and focal adhesions to increase and then stabilize basal area of epithelial cells allowing their flattening and elongation. This epithelial expansion behaviour bridges cell changes to oocyte growth and extension, while oocyte growth in turn deforms the epithelium to drive cell spreading. Basal pulsatile actomyosin networks exhibit non-contractile mechanics, non-linear structures and F-actin/Myosin-II spatiotemporal signal separation, implicating unreported expanding properties. Biophysical modelling incorporating these expanding properties well simulates epithelial cell expansion waves. Our work thus highlights actomyosin expanding properties as a key mechanism driving tissue morphogenesis.
Keyphrases
  • single cell
  • cell therapy
  • stem cells
  • gene expression
  • high resolution
  • dna methylation
  • genome wide
  • cell proliferation
  • induced apoptosis
  • sensitive detection
  • cell cycle arrest
  • fluorescent probe
  • living cells