WAVE facilitates polarized E-cadherin transport.

Cadherin dynamics drive morphogenesis, while defects in cadherin polarity contribute to diseases, including cancers. However, the forces polarizing cadherin membrane distribution are not well understood. We previously showed that WAVE-dependent branched actin polarizes cadherin distribution and suggested that one mechanism is protein transport. While previous studies suggested that WAVE is enriched at various endocytic organelles, the role of WAVE in protein traffic is understudied. Here we test the model that WAVE regulates cadherin by polarizing its transport. In support of this model we show that 1) endogenously tagged WAVE accumulates in vivo at several endocytic organelles, including recycling endosomes and at the Golgi; 2) likewise, cadherin protein accumulates at recycling endosomes and the Golgi; 3) loss of WAVE components reduces cadherin accumulation at apically directed RAB-11-positive recycling endosomes and increases accumulation at the Golgi. In addition, live imaging illustrates that dynamics and velocity of recycling endosomes enriched for RAB-11::GFP and RFP::RME-1 are reduced in animals depleted of WAVE components and RAB-11::GFP movements are misdirected, suggesting that WAVE powers and directs their movements. This in vivo study demonstrates the importance of WAVE in promoting polarized transport in epithelia and supports a model that WAVE promotes cell-cell adhesion and polarity by promoting cadherin transport.

E-Cadherin/HMR-1 Membrane Enrichment Is Polarized by WAVE-Dependent Branched Actin.

Polarized epithelial cells adhere to each other at apical junctions that connect to the apical F-actin belt. Regulated remodeling of apical junctions supports morphogenesis, while dysregulated remodeling promotes diseases such as cancer. We have documented that branched actin regulator, WAVE, and apical junction protein, Cadherin, assemble together in developing C. elegans embryonic junctions. If WAVE is missing in embryonic epithelia, too much Cadherin assembles at apical membranes, and yet apical F-actin is reduced, suggesting the excess Cadherin is not fully functional. We proposed that WAVE supports apical junctions by regulating the dynamic accumulation of Cadherin at membranes. To test this model, here we examine if WAVE is required for Cadherin membrane enrichment and apical-basal polarity in a maturing epithelium, the post-embryonic C. elegans intestine. We find that larval and adult intestines have distinct apicobasal populations of Cadherin, each with distinct dependence on WAVE branched actin. In vivo imaging shows that loss of WAVE components alters post-embryonic E-cadherin membrane enrichment, especially at apicolateral regions, and alters the lateral membrane. Analysis of a biosensor for PI(4,5)P2 suggests loss of WAVE or Cadherin alters the polarity of the epithelial membrane. EM (electron microscopy) illustrates lateral membrane changes including separations. These findings have implications for understanding how mutations in WAVE and Cadherin may alter cell polarity.