aPKC is a key polarity determinant in coordinating the function of three distinct cell polarities during collective migration.

Apical-basal polarity is a hallmark of epithelia and needs to be remodeled when epithelial cells undergo morphogenetic cell movements. Here, we analyze border cells in the Drosophila ovary to address how apical-basal polarity is remodeled and turned into front-back and inside-outside as well as apical-basal polarities, during collective migration. We find that the Crumbs (Crb) complex is required for the generation of the three distinct but interconnected cell polarities of border cells. Specifically, the Crb complex, together with the Par complex and the endocytic recycling machinery, ensures the strict distribution of two distinct populations of aPKC at the inside apical junction and near the outside lateral membrane. Interestingly, aPKC distributed near the outside lateral membrane interacts with Sif and promotes Rac-induced protrusions, whereas alteration of the aPKC distribution pattern changes the pattern of protrusion formation, leading to disruption of all three polarities. Therefore, we demonstrate that aPKC, spatially controlled by the Crb complex, is a key polarity molecule coordinating the generation of three distinct but interconnected cell polarities during collective migration.

Differential contribution of the two waves of cardiac progenitors and their derivatives to aorta and pulmonary artery.

During mouse development, part of the cells derived from the second heart field (SHF) progenitors contributes to the elongation and enlargement of the outflow tract (OFT) that subsequently septates into the trunks of aorta (Ao) and pulmonary artery (PA). Thus, the cardiac progenitor-originated cells are distributed to both Ao and PA. Here, we investigated that how these cells are assigned to the two great arteries during OFT septation through lineage tracing technology. By use of the inducible Mef2c-AHF-CreERT2; Rosa26-mTmG reporter system, two waves of SHF progenitors and their derivatives were identified, and they made differential contribution to the Ao and PA, respectively. While the early wave of cells (at E7.5) was preferentially destined to the Ao, the second wave of cells (from E8.5 till E11.5) made its favorite path to the PA. In addition, we unveiled PDK1 as a critical regulator of the second wave of cells as deletion of Pdk1 resulted in poorly developed PA leading to pulmonary stenosis. Thus, this study provides insights into the understanding of the pre-determined cell fate of the cardiac progenitor-derived cells with preferential contribution to the Ao and PA, as well as of the pathogenesis of pulmonary stenosis.