To form epithelial organs cells must polarize and generate de novo an apical domain and lumen. Epithelial polarization is masterminded by polarity complexes, which are thought to direct downstream events such as polarized membrane traffic, though this interconnection is not well understood. We report that Rab11a regulates apical traffic and lumen formation via the Rab GEF Rabin8, and its target Rab8a. Rab8a/11a act via the exocyst to target Par3 to the apical surface, and control apical Cdc42 activation via the Cdc42 GEF, Tuba. These components assemble at a transient apical membrane initiation site to form the lumen. This Rab11a-directed network directs Cdc42-dependent apical exocytosis during lumen formation, revealing a novel interplay of the machineries of vesicular transport and polarization.Most internal epithelial organs consist of a monolayer of polarized epithelial cells surrounding a central lumen. Polarization requires the interaction of the signaling complexes and scaffolds that define cortical domains with the polarized membrane sorting machinery 1 . In yeast, traffic from the trans-Golgi network to the surface is regulated by Ypt32p and Sec4p 2 , homologs of mammalian Rab11 and Rab8, respectively. These are linked by Sec2p (homolog of mammalian Rabin8), a guanine nucleotide exchange factor (GEF) for Sec4p, which is recruited by Ypt32p. Sec2p and Sec4p in turn interact with the exocyst, which docks vesicles to the surface 3 .Definition of cortical domains in metazoa involves a complex of Par3, Par6, atypical PKC (aPKC), and the GTPase Cdc42 4 . This complex is a master regulator of polarity, conventionally depicted upstream of membrane trafficking machinery. How this complex interfaces with membrane transport is poorly understood.Here we show a molecular mechanism for lumen and apical surface formation, linking Rab8a/ 11a, exocyst, annexin2, Cdc42 and its GEF Tuba, and the Par3/aPKC complex. This novel NIH Public Access Author ManuscriptNat Cell Biol. Author manuscript; available in PMC 2010 November 8. Published in final edited form as:Nat Cell Biol. 2010 November ; 12(11): 1035-1045. doi:10.1038/ncb2106. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript pathway shows how the membrane traffic and cortical polarity machineries cooperate to generate the apical surface and lumen. RESULTS Apical polarization during lumen formationUpon plating into 3D culture, individual MDCK cells proliferate and assemble into cyst structures -a polarized spherical monolayer surrounding a central lumen. Lumenogenesis requires the apical membrane determinant gp135/podocalyxin 5 (PCX in figures). Initially, MDCK aggregates have podocalyxin at the ECM-contacting surface (Fig. 1a, 12 h; Fig. S1a), before polarity inversion occurs, with β-catenin and Na/K-ATPase at cell-cell junctions and podocalyxin now at the lumen (Fig. 1a, 24-48 h, arrows; Fig. S1d) 6,7 . Early lumens occur at a site previously termed the "Pre-Apical Patch" (PAP), where opposing plasma membranes are separated, but the po...
PTEN controls three-dimensional (3D) glandular morphogenesis by coupling juxtamembrane signaling to mitotic spindle machinery. While molecular mechanisms remain unclear, PTEN interacts through its C2 membrane-binding domain with the scaffold protein b-Arrestin1. Because b-Arrestin1 binds and suppresses the Cdc42 GTPase-activating protein ARHGAP21, we hypothesize that PTEN controls Cdc42-dependent morphogenic processes through a b-Arrestin1-ARHGAP21 complex. Here, we show that PTEN knockdown (KD) impairs b-Arrestin1 membrane localization, b-Arrestin1-ARHGAP21 interactions, Cdc42 activation, mitotic spindle orientation and 3D glandular morphogenesis. Effects of PTEN deficiency were phenocopied by b-Arrestin1 KD or inhibition of b-Arrestin1-ARHGAP21 interactions. Conversely, silencing of ARHGAP21 enhanced Cdc42 activation and rescued aberrant morphogenic processes of PTEN-deficient cultures. Expression of the PTEN C2 domain mimicked effects of full-length PTEN but a membrane-binding defective mutant of the C2 domain abrogated these properties. Our results show that PTEN controls multicellular assembly through a membrane-associated regulatory protein complex composed of b-Arrestin1, ARHGAP21 and Cdc42.
Epithelial cells polarize and orient polarity in response to cell-cell and cell-matrix adhesion. Although there has been much recent progress in understanding the general polarizing machinery of epithelia, it is largely unclear how this machinery is controlled by the extracellular environment. To explore the signals from cell-matrix interactions that control orientation of cell polarity, we have used three-dimensional culture systems in which Madin-Darby canine kidney (MDCK) cells form polarized, lumen-containing structures. We show that interaction of collagen I with apical 1-integrins after collagen overlay of a polarized MDCK monolayer induces activation of Rac1, which is required for collagen overlay-induced tubulocyst formation. Cysts, comprised of a monolayer enclosing a central lumen, form after embedding single cells in collagen. In those cultures, addition of a 1-integrin function-blocking antibody to the collagen matrix gives rise to cysts that have defects in the organization of laminin into the basement membrane and have inverted polarity. Normal polarity is restored by either expression of activated Rac1, or the inclusion of excess laminin-1 (LN-1). Together, our results suggest a signaling pathway in which the activation of 1-integrins orients the apical pole of polarized cysts via a mechanism that requires Rac1 activation and laminin organization into the basement membrane. INTRODUCTIONPolarization of cells is a fundamental process in biology. Epithelial cells polarize into apical and basolateral poles. Much has been learned recently about the mechanisms of epithelial polarization. Three major polarization complexes, the Par3/Par6/atypical protein kinase C (aPKC), Crumbs/ PATJ/Stardust, and Scribble/Discs Large/Lethal Giant Larvae complexes are conserved from Caenorhabditis elegans and Drosophila to mammals and are essential for epithelial polarization (Roh and Margolis, 2003;Macara, 2004). Cell polarization also requires interactions of the cells with each other and the extracellular matrix (ECM), as well as polarized organization of the cytoskeleton and membrane traffic, although how these processes are connected to the three polarization complexes is largely obscure (Vega-Salas et al., 1987;Yeaman et al., 1999;O'Brien et al., 2002;Mostov et al., 2003;Nelson, 2003;Zegers et al., 2003).Formation of epithelial tissues requires that the orientation of polarity of individual epithelial cells be coordinated in space and time. This was underappreciated in studies using cells grown on filter supports, because the filter provides an overriding extrinsic cue to orient the cells with the basolateral surface facing the filter and the apical surface opposite. Building on earlier observations (Wang et al., 1990a), we found that generation of epithelial polarity can be uncoupled from the orientation of that polarity (O'Brien et al., 2001). Madin-Darby canine kidney (MDCK) epithelial cells grown in three-dimensional (3D) collagen gels form cysts, where the apical surface of a polarized monolayer of cells fa...
The asymmetric polarization of cells allows specialized functions to be performed at discrete subcellular locales. Spatiotemporal coordination of polarization between groups of cells allowed the evolution of metazoa. For instance, coordinated apical-basal polarization of epithelial and endothelial cells allows transport of nutrients and metabolites across cell barriers and tissue microenvironments. The defining feature of such tissues is the presence of a central, interconnected luminal network. Although tubular networks are present in seemingly different organ systems, such as the kidney, lung, and blood vessels, common underlying principles govern their formation. Recent studies using in vivo and in vitro models of lumen formation have shed new light on the molecular networks regulating this fundamental process. We here discuss progress in understanding common design principles underpinning de novo lumen formation and expansion.
SUMMARY The formation of epithelial tissues containing lumens requires not only the apical-basolateral polarization of cells, but also the coordinated orientation of this polarity such that the apical surfaces of neighboring cells all point toward the central lumen. Defects in extracellular matrix (ECM) signaling lead to inverted polarity so that the apical surfaces face the surrounding ECM. We report a molecular switch mechanism controlling polarity orientation. ECM signals through a β1-integrin/FAK/p190RhoGAP complex to down-regulate a RhoA/ROCK/Ezrin pathway at the ECM interface. PKCβII phosphorylates the apical identity-promoting Podocalyxin/NHERF1/Ezrin complex, removing Podocalyxin from the ECM-abutting cell surface and initiating its transcytosis to an apical membrane initiation site for lumen formation. Inhibition of this switch mechanism results in the retention of Podocalyxin at the ECM interface and the development instead of collective front-rear polarization and motility. Thus, ECM-derived signals control the morphogenesis of epithelial tissues by controlling the collective orientation of epithelial polarization.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
