Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press Remodeling Epithelial Cell Organization: Transitions Between Front–Rear and Apical–Basal Polarity W.JamesNelson DepartmentsofBiologyandMolecularandCellularPhysiology,StanfordUniversity, Stanford,California94305 Correspondence:[email protected] Polarized epithelial cells have a distinctive apical–basal axis of polarity for vectorial transport of ions and solutes across the epithelium. In contrast, migratory mesenchymal cells have afront–rearaxis of polarity. During development, mesenchymal cells convert toepitheliabycoalescingintoaggregatesthatundergoepithelialdifferentiation.Signaling networks and protein complexes comprising Rho family GTPases, polarity complexes (Crumbs, PAR, and Scribble), and their downstream effectors, including the cytoskeleton and the endocytic and exocytic vesicle trafficking pathways, together regulate the distri- butions of plasma membrane and cytoskeletal proteins between front–rear and apical– basal polarity. The challenge is to understand how these regulators and effectors are adaptedtoregulatesymmetrybreakingprocessesthatgeneratecellpolaritiesthatarespe- cializedfordifferentcellularactivitiesandfunctions. THEBASICDESIGNOFPOLARIZED This conserved function of polarized epi- EPITHELIALCELLS thelial cells requires that membrane proteins aresortedandretainedinthecorrectapicalor Epithelial cells are distinguished from other basolateral membrane domain (Fig. 1B). A celltypesbytheirorganizationintoadherent majorsortingsitefornewlysynthesizedplasma- groupsofcellsthatpartitiontheorganisminto membraneproteinsisthetrans-Golgicomplex discrete compartments—generally, a special- (TGN) (the exocytic pathway) (reviewed in ized internal compartment separated and Folsch 2008; Mellman and Nelson 2008), but protected from the external environment by additional sorting events between the TGN the epithelium. This organization provides a and plasma membrane domains (Gravotta number of unique physiological properties. et al. 2007) and different membrane domains Most importantly, aclosed epithelium enables (transcytosis) (Casanova et al. 1990) occur in the regulated exchange of nutrients and waste the endocytic pathway (Fig. 1B). Some vesicle betweentheinternalandexternalenvironments trafficking between the TGN and the plasma (Fig.1A)(reviewedinCereijidoetal.2004). Editors:BruceBowermanandRongLi AdditionalPerspectivesonSymmetryBreakinginBiologyavailableatwww.cshperspectives.org Copyright#2009ColdSpringHarborLaboratoryPress;allrightsreserved;doi:10.1101/cshperspect.a000513 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 1 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press W.J.Nelson A Functional apical–basal polarity B Structural apical–basal polarity Primary 2Cl– Na+ cilium Apical Crab gill APICAL membrane cuticle Mammalian Na+ 2Cl– Na+ K+ Apical Syn3 Bboadsyal kidney AJC Endo tubule lumen K+ AJC Golgi (Tight junction) Syn4 exocyst Na+ K+ N ATP Basal Na+ Cl– K+ Microtubules + Bmaesmoblartaenreal + + + + + BASAL ECM Figure1.Functionalandstructuralorganizationofpolarizedepithelia.(A)Functionalapical–basalpolarity. Physiological studies of transporting epithelia across the phyla (e.g., crab gill and mammalian kidney nephron)hasrevealedaremarkableconservationinthedistributionofionchannels(Clchannel,Kchannel) transporters (Na,K,2Cl transporter) and pumps (Na/K-ATPase) between the apical and basolateral plasma membranedomains.Thepolarizeddistributionoftheseproteinsgeneratesanapical–basalsodiumgradient that is used to move other ions and solutes across the epithelium. (Redrawn and adapted from Cereijido et al. 2004.) (B) Structural apical–basal polarity. Polarized epithelial cells have a distinctive apical–basal polarity in the orientation of cell–cell and cell–extracellular matrix (ECM). Major structures of these cells are also organized in the apical–basal axis: The organization of plasma membrane domains (apical and basolateral), junctional complexes (APC, apical junctional complex), the centrosome (basal body), microtubulesandprimarycilium,andthesecretorypathway(Golgi).Fordetails,seetext. membrane occurs along microtubules (Jaulin solutes (Fig. 1A) (reviewed in Shin et al. etal.2007;Lafontetal.1994),which,compared 2006).Second,severalclassesofmembranepro- with migratory cells (see Fig. 2A), have an teinsbindtoacytoplasmicscaffoldcomplexof unusual organization in polarized epithelial ankyrin–spectrinonthebasolateralmembrane, cells (Bacallao et al. 1989) (Fig. 1B). Finally, including ion transporters and channels (re- the docking and fusion of vesicles with the viewedinBennettandHealy2008).Theseinter- correct membrane domain requires specific actions are important in regulating membrane vesicle tethering (exocyst) and SNARE com- protein trafficking, and retention in different plexes (Fig. 1B) (reviewed in Mellman and membrane domains (reviewed in Bennett and Nelson2008). Healy2008). Several mechanisms maintain the distri- butions of proteinstothe apical or basolateral EvolutionandDevelopmentalOriginsof membrane domain. First, the tight junction PolarizedEpithelia acts as a molecular fence at the boundary between the apical and basolateral membrane Epitheliaaroseatthetimeoftheemergenceof domains (apical junctional complex [AJC]) primitive metazoans in Precambrian times, (Fig. 1B) to prevent the free diffusion of pro- approximately 600 million years ago. The teins from one domain to the other, and a evolution of mesenchymal cells in bilaterians gate to the paracellular diffusion of ions and enabled a further diversification in the 2 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press RemodelingEpithelialCellOrganization A Front–rear polarity overview B Front–rear polarity signaling pathways Rac1/Cdc42 Extracellular cues RhoA Actin assembly Leading edge Actin Scribble Actomyosin assembly contraction + end MT Cdc42 Uropod Centrosome orientation Scribble/DLG PAR complex Exocyst Integrin N aPKC Rac1 PAR3/6 Golgi GSK3b aPKC Ptdlns(3,4)P Integrin Exocytosis 2 TIAM-1 Numb Ptdlns(3,4,5)P 3 bPIX1/GT1 GSK3 b Rear Front Scribble LGL Integrin endocytosis APC DLG MT/centrosome polarity Figure 2. Functional and structural organization of migratory mesenchymal cells. (A) Front–rear polarity overview.Migratorycellshaveadistinctiveorganizationbetweenthefrontofthecell(leadingedge)andrear (uropod). Rho family GTPase activities have different functions in inducing actin polymerization at the leadingedge(Cdc42,Rac1),andactomyosincontractionattherear(RhoA).Thecentrosome,microtubules, andthesecretorypathway(Golgi)areorientedtowardthefrontofthecell.Endocyticandexocyticpathways are also oriented in the rear–front orientation, which allows internalization of integrins from the rear, and exocytosis and endocytosis of integrins in the front, all of which are required for cell migration. Phosphatidylinositides have a polarized distribution in the front–rear polarity. Polarity protein complexes are localized to the front of the cell (Scribble/DLG and PAR/aPKC). (B) Front–rear polarity signaling pathways.Polarityproteincomplexes(blue)areupstreamanddownstreamofRhosmallGTPases(Rac1and Cdc42)andtheirdownstreameffectors(yellow)andend-pointeffects(white).Fordetails,seetext. distribution and organization of epithelial front–rear polarity designed for directional structures(Baumetal.2008).Unlikeepithelial migration, to an epithelium with an apical– cells, mesenchymal cells show weak cell–cell basal polarity designed for vectorial ion and adhesion and are motile, allowing them to solutetransportiscomplex.Signalingpathways migrate to different sites in the body cavity that initiate this mesenchymal-to-epithelial where they convert to epithelial cells and con- transition (MET) involve soluble growth tributetotheformationofsecondaryepithelia. factors and their receptors, and downstream This provided additional complexity in com- signaling pathways(Baum etal.2008;Dressler partmentalizationinmetazoansthatleadtothe 2006), and changes in patterns of gene formation of physiologically different tissues expression(BoyleanddeCaestecker2006;van andorgans(MagieandMartindale2008). derFlierandClevers2008).However,remodel- The process of formation of polarized ing from front–rear to apical–basal polarity epithelia during development is initiated by also involves the reorganization of generic the coalescence of migratory (mesenchymal structures and cellular processes common to and epithelial) cells into cell aggregates that allcelltypes,includingthecytoskeleton,endo- undergo epithelial differentiation. The cellular cytic and exocytic vesicle trafficking pathways, transformation from migratory cells with a and mechanisms for localizing and retaining CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 3 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press W.J.Nelson membrane proteins to different plasma of intracellular pathways required for mem- membrane domains. Here, I focus on master brane protrusions in axonal growth cones regulators and signaling pathways that control (Arimura and Kaibuchi 2005), migrating front–rearpolarityofmigratory mesenchymal neutrophils (Stephens et al. 2008), and other cells, establishing the basic design of the cells(Ridleyetal.2003). developmental precursors to epithelia. I then discuss how pathways and regulators common Front–RearPolarityofRhoGTPases to both mesenchymal and epithelial cells are reused and adapted to regulate the symmetry Thegenerationoffront–rearpolarity ismedi- breaking processes that lead to the conversion ated by the localized activation of members of betweenfront–rearandapical–basalpolarity. the Rho family of small GTPases (Li et al. 2008; reviewed in Iden and Collard 2008). In general, Cdc42 and Rac1 are activated at the FRONT–REARPOLARITYIN frontofthecell,whichresultsintherapidand MIGRATORYCELLS dynamic assemblyof actin filaments mediated Migratory mesenchymal cells show front–rear by the Arp2/3 complex and formins (Pollard polarityrequiredforpersistent,directionalcell 2007), and the capture (stabilization) and migration (Fig. 2A) (reviewed in Ridley et al. polarized orientation of microtubules by 2003). Many different external cues initiate mDia (Palazzo et al. 2001) and microtubule front–rear polarity, including growth factors plus-end binding proteins (Akhmanova et al. and the extracellular matrix. Conversion of 2001; Wen et al. 2004) (reviewed in Li et al. those cues into directional migration requires 2008)(Fig.2A).Theselocalizedchangesinthe global changes in cell organization by protein actin and microtubule cytoskeletons generate complexesandsignaling pathwaysthatcontrol membrane protrusions, dynamic assembly thecytoskeletonandproteintrafficking. and disassembly of integrin-based contacts with the extracellular matrix, and forward movement of the leading edge (Li et al. 2008; Front–RearPolarityofPhosphatidylinositides Ridley et al. 2003). RhoA, on the other hand, A central feature of polarized migrating cells, isactivatedattherearofthecellandpromotes best studied in neutrophils and Dictyostelium, the assembly and activation of contractile is the front–rear polarity of different phos- actomyosin networks that are necessary for phatidylinositides in the plasma membrane detachmentoftherearofthecellfromtheextra- (Funamoto et al. 2002; Iijima and Devreotes cellular matrix (Fig. 2A) (Ridley et al. 2003). 2002; Wang et al. 2002). Generally, phos- Local activation of these small GTPases affects phatidylinositide-3,4,5-triphosphate (PtdIns cellorganizationgloballybymaintaininglocal- (3,4,5)P )isenrichedintheplasmamembrane ized sites of actin polymerization (front) and 3 at the front of the cell, whereas phos- contractions (rear). Inhibition of local Rac1/ phatidylinositide-3,4-bisphosphate (PtdIns Cdc42 or RhoA activity, or disruption of (3,4)P )isenrichedeverywhereelse,including the polarized organization of the actin and 2 the rear (Fig. 2A). The different distributions microtubule cytoskeletons results in a global of phosphatidylinositides was thought to be a loss of directional migration by neutrophils consequence of the spatial activation of phos- (Xuetal.2003). phoinositide3-kinase(PI3-kinase)atthefront of the cell, and phosphatase and tensin RolesofPolarityComplexesinFront–Rear homolog (PTEN) elsewhere. Although this FunctionsofRhoGTPaseandCytoskeleton picture has become more complex (Stephens et al. 2008), the front–rear distribution of Polarity complexes regulate the cytoskeleton PtdIns(3,4,5)P and PtdIns(3,4)P are impor- either upstream or downstream of Rho family 3 2 tantingeneratingasymmetry intheactivation GTPases (Fig. 2B) (reviewed in Iden and 4 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press RemodelingEpithelialCellOrganization Collard2008).Polarityproteinswereoriginally maintainingactiveCdc42atthefront,including identified in epithelia as protein complexes PI3-kinase,whichconcentratesPtdIns(3,4,5)P 3 involvedinregulatingapical–basalpolarity,but atthefront (RaftopoulouandHall2004),and theyarealsofound in migrating mesenchymal PAR4/LKB1 (Zhang et al. 2008). Interestingly, cells. They include three protein complexes, ectopicexpressionofPAR4/LKB1insingleepi- each defined by its core interacting proteins: thelial cellsresults in a dramatic globalpolari- the Scribble complex (Scribble, DLG, and zation of the cytoskeleton and the formation LGL), the PARtition (PAR) complex (PAR3/ of distinct plasma membrane domains in the PAR6/atypical protein kinase C [aPKC]) and absence of eithercell–cell orcell–extracellular PAR4/LKB1, and the Crumbs complex matrix adhesion (Baas et al. 2004). Thus, at (Crumbs, PALS1, and PATJ) (see Fig. 2B) (see least in the context of ectopic expression, McCaffrey and Macara 2009; Prehoda 2009). PAR4/LKB1 appears to be an example of a These proteins are generally classified as regulator of autonomous symmetry breaking. tumor suppressors (reviewed in Bilder 2004), PAR4/LKB1 substrates include another but how they control cell proliferation is serine/threonine kinase PAR1 and the family poorly understood (see the end of the article of ELKL-motif kinases (EMKs), also known forfurtherdiscussion).Nevertheless,itisclear as microtubule-affinity-regulating kinases thattheyplayessentialrolesincellorganization. (MARKs)(Illenbergeretal.1996).Avarietyof They are generally localized at the front of studies in fibroblasts, epithelial cells, and migrating cells (Fig. 2B), although Scribble Drosophila indicate that PAR1 and MARKs and DLG have also been found at the rear of regulate microtubule remodeling and organi- migrating T cells (Ludford-Menting et al. zation,andthedeliveryoftransportvesiclesto 2005).Littleisknownaboutplasmamembrane the plasma membrane (Cohen et al. 2004a; binding sites for Scribble, or other Polarity Cohenetal.2004b;Elbertetal.2005). complexesatthefront (orrear)ofcells. aPKC, a component of the PAR3/PAR6 Several mechanisms involving Polarity Polarity complex, is a downstream effector of complexes locally activate Cdc42 and Rac1 at activated Cdc42 (Fig. 2B), although it may be the leading edge plasma membrane (Fig. 2B). localizedtothefrontofthecellindependently Scribble, in a complex with bPIX (PAK- of Cdc42 by PATJ (Shin et al. 2007), a com- interacting exchange factor)—a guanine ponentoftheCrumbsPolaritycomplex.aPKC exchange factor for Cdc42/Rac1—and GIT1 has a number of substrates critical for the (G-protein coupled receptor interacting polarization of migrating cells (Fig. 2B). One protein 1) (Audebert et al. 2004), controls substrate is T-cell-lymphoma invasion and Cdc42 activation and localization (Osmani metastasis1 (TIAM1) (Nishimura et al. 2005), et al. 2006). Knockdown of Scribble levels in a GEF that activates Rac1 (Pegtel et al. 2007). mammalian tissue culture cells also causes a Another substrate is glycogen synthase decrease in activation of Rac1, indicating that kinase-3b(GSK3b).GSK3bisinactivatedupon the Scribble complex regulates Rac1 activity aPKC phosphorylation, one result of which is directly or indirectly (Zhan et al. 2008). that nonphosphorylated APC, normally a Additional mechanisms regulate Cdc42 and target of active GSK3b, bindsto and stabilizes Rac1 activation at the leading edge (reviewed microtubules at the plasma membrane in Arimura and Kaibuchi 2005), including (Zumbrunn et al. 2001). Interestingly, DLG, a integrin engagement with the extracellular component of the Scribble Polarity complex, matrix (Etienne-Manneville and Hall 2001), binds APC, thereby localizing DLG to the Rap1, another Ras family GTPase (Bos 2005), front of migrating cells (Etienne-Manneville which activates integrins and Cdc42 et al. 2005) (Fig. 2B). Finally, orientation of (Takahashi et al. 2008), and Rac1 (Gerard microtubules in the front–rear axis affectsthe et al. 2007) at the front of migrating cells. orientation of the centrosome, also called the Several feedback loops may be involved in microtubule organization center (Fig. 2A), CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 5 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press W.J.Nelson which is critical for maintaining overall cell substrate accessibility) or location may fine polarity and directional migration (Etienne- tunecellpolarizationandmigration. MannevilleandHall2003). Several protein complexes that control vesicle delivery to the plasma membrane are localized to the front of migrating cells (Fig. 2B). The complexof Scribble,bPIX, and Front–RearPolarizationofEndocyticand GIT1locallyregulatesCaþþ-dependentexocy- ExocyticMembraneTraffickingPathways tosis at synapses (Audebert et al. 2004), and Membrane protein distributions in migratory thedistributionofthiscomplextothefrontof cellsareorganizedinthefront–rearorientation the cell (Fig. 2B) could play a similar role to by the exocytic and endocytic pathways promote local transport and vesicle fusion (Fig. 2A). Local exocytosis of proteins occurs with the leading edge. Another protein in the atthefrontofmigrationscells(fordiscussion, Scribble Polarity complex, LGL, may also play see Bretscher 2008). It is unclear, however, if aroleinvesiclefusionattheplasmamembrane. newly synthesized proteins are also targeted BothmammalianLGL(Muschetal.2002)and specifically to the front of migrating cells. theyeasthomologSro7/77(Lehmanetal.1999) Although specific sorting of membrane pro- bindt-SNAREs,anddeletionofSro7/77inyeast teinsintheexocyticpathwaytoapicalandbaso- (Lehman et al. 1999) or LGL in neuronal cells lateralmembranedomainsisgenerallythought (Klezovitchetal.2004)resultsininhibitionof tobeaspecializationofepithelialcellspolarized someproteindeliverytotheplasmamembrane. in the apical–basal axis (Fig. 1B), fibroblastic The Exocyst complex, which is thought to cells appear to have a similar capacity tether transport vesiclesto sites of fusionwith (Yoshimori et al. 1996). Further studies are theplasmamembrane(Wuetal.2008),isalso required, however, to determine whether localized to the front of migratory cells proteinsortingintheTGNandseparatedeliv- (Fig.2B)(SpiczkaandYeaman2008;Zuoetal. ery of different classes of proteins to different 2006). The exocyst interacts with a number of membranedomainsisimportantforestablish- proteins that could localize it to the leading ing or maintaining front–rear polarity in edge,includingpaxillin(astructuralandsignal- responsetoanextracellularcue. ing proteinassociatedwithintegrinfocaladhe- The redistribution of membrane proteins sions), the bPIX-GIT1 complex (Spiczka and after delivery to the plasma membrane occurs Yeaman 2008), and Apr1 (a protein in the via the endocytic pathway. Integrins are an Arp2/3complex)(Zuoetal.2006).Importantly, important class of proteins that are redistrib- knockdown of exocyst proteins results in uted from the rear to the front of the cell by decreased delivery of integrins to the front of the endocytic pathway (Hopkins et al. 1994; the cell and a decreased rate of cell migration Lawson and Maxfield 1995) (Fig. 2A). The (Spiczka and Yeaman 2008; Zuo et al. 2006), endocytic adaptor protein Numb (Salcini furthersupportingtheroleofpolarizedtraffick- et al. 1997), another substrate for aPKC ingofproteinstothefrontofmigratorycells. (Nishimura and Kaibuchi 2007), is involved In summary, regulation of front–rear (Fig. 2B). In its nonphosphorylated state, polarity in migratory cells requires localized Numb binds to and induces the endocytosis activation of different Rho family small of integrins, and promotes cell migration GTPases at the front (Cdc42, Rac1) and rear aPKC phosphorylation of Numb inhibits (Rho) of the cell that results in the polarized Numb binding to integrins, and reduces cell orientation and assembly of the actin and migration (Nishimura and Kaibuchi 2007). It microtubulecytoskeletons.Polaritycomplexes, is important to recall that aPKC phos- particularly the Scribble complex and com- phorylation of other substrates also promotes ponents of the PAR complex, play multiple cell migration (see the previous discussion), roles in controlling the local distribution and indicating that control of aPKC activity (or activation of Rac1 and Cdc42 at the front of 6 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press RemodelingEpithelialCellOrganization thecell,downstreamregulationofcytoskeleton space mediated by polarized distributions of organizationandassembly,andlocalregulation ion channels and pumps between the apical oftheendocyticandterminalexocyticmachin- (e.g., CFTR) and basolateral membrane ery that are required for remodeling of mem- (e.g., Na/K-ATPase) (Ferrari et al. 2008; braneproteindistributions. Houghton et al. 2003; Jaffe et al. 2008). Coupledwiththelossofcell–celladhesionon the forming apical membrane (see #2 above), APICAL–BASALPOLARITYIN vectorial pumping of fluid would help to fill EPITHELIALCELLS the luminal space; and (4) Repulsion of Thetransitionfrommigratorycellstotheestab- E-cadherin cell–cell adhesion (e.g., during lishment of a polarized simple epithelium formation of the heart tube in the Drosophila requirestheaggregationofcellsthroughspecific embryo) (Santiago-Martinez et al. 2008). In cell–cell interactions, followed by epithelial this case, inhibition of E-cadherin-mediated differentiation. In general, the adhesive sur- cell–cell adhesion by Slit and Robo pathways faces,formedbyinteractionsbetweencellsand inducesformationofaluminalspace. withtheextracellularmatrix,formthebasolat- Cell adhesion to the extracellular matrix eral plasma membrane domain. Characteristi- (ECM) is critical for signaling the formation cally, the apical plasma membrane forms on of an apical membrane and luminal space the“nonadhesive”surface.Inafewexceptional (reviewed in Bryant and Mostov 2008). In its cases,however,anonadhesivesurfaceispresent simplest role, ECM adhesion enables cells to immediately:Forexample, theopensurfaceof distinguish an adhesive surface (attached to epithelial cell monolayers grown in tissue the ECM) and a nonadhesive surface. For culture, the outside surface of the preimplan- example, single mammary epithelial cells tationmammalianembryo,orsyncytialblasto- attached to an ECM (i.e., in the absence of dermofDrosophila.Theformationofanapical cell–cell adhesion) secrete b-casein from the surfacewithincellaggregatesismorecomplex. apical surface specifically (Streuli et al. 1995), and RNA envelope viruses, which normally bud from the apical (Influenza virus) and TheFirstOvertEvidenceofApical–Basal basolateral membrane (Vesicular Stomatitis Polarity—Orientationofthe virus, VSV) of polarizedmonolayers of MDCK Apical/LuminalDomain cells,butbudfromdifferentsitesontheplasma Withinanaggregateofcells,aluminalnonad- membrane of single MDCK cells attached hesive surface is not provided and, therefore, to a substratum (Rodriguez-Boulan and hastobeformeddenovo.Severalmechanisms Pendergast1980). appear to generate a nonadhesive surface and The specialized role of the ECM in the de a lumenwithin an aggregate of cells (reviewed novoformationofthelumen/apicalmembrane inBryantandMostov2008):(1)Selectiveapo- is important within cell aggregates such as ptosis of cells in the center of the aggregate three-dimensional MDCK epithelial cysts (Mailleux et al. 2008) removes cells, leaving (reviewed in Bryant and Mostov 2008). behindaluminalspace;(2)Insertionofapical Although details of the mechanisms involved proteins from intracellular stores into the are not fully understood, it appears that the cell–cell contact, coupled with exclusion of initial step is Rac1-dependent adhesion of E-cadherin and other basolateral proteins integrinstotheECMproteinlaminin(O’Brien from that site (Ferrari et al. 2008; Jaffe et al. et al. 2001) (Fig. 3). Subsequently, the asym- 2008; Ojakian et al. 1997). In this case, the metric distribution of PtdIns(3,4,5)P to the 3 lackofcell–celladhesionproteinswouldallow basolateral membrane and PtdIns(3,4)P to 2 formation of a nonadhesive, luminal surface the apical membrane initiates the localization on cells containing apical membrane proteins; of Cdc42 by annexin II (Martin-Belmonte (3) Vectorial fluid secretion into the luminal et al. 2007), and the PAR complex to the CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 7 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press W.J.Nelson Endocytosis PALS1 Primary cilium Crumbs Rich1 Cdc42 AMOT Plasma membrane identity PATJ PAR Apical Crumbs WASP Crumbs3 membrane Crumbs PALS1 Arp2/3 PAR3 Dynamin Ptdlns(3,4)P 2 E-cadherin PAR3/6 Cdc42 Rac1 aPKC APC Rho Exocytosis Exocyst Basolateral Scribble Cargo tSNARE Golgi Dynein membrane DLG ScribbleLGL 5)P3 mRNA Apoptosis ? Hippo 3,4, crusmdtbs bPIX/GIT1 ns( PAR3 Myc Warts dl max Pt Rac1 APC Rac1 DIAP1-apoptosis Transcription miR-200 DLG + + + Integrin JNK-apoptosis E-cadherin Laminin Crumbs Snail TGFb Extracellular cues LGL/PATJ ZEB HGF Laminin5 Figure3. Functionaland structuralorganization of polarizedepithelialcells.Center:Phosphatidylinositides have a distinctive apical–basal polarity; PtdIns(3,4)P is localized in the apical membrane, and 2 PtdIns(3,4,5)P is localized in the basolateral membrane. Signals from the extracellular matrix (laminin) 3 through integrins and Rac1 activity orient cells, and are required for formation of the apical/luminal domain. Microtubules, which are polarized in the apical–basal axis, are anchored at the basal and lateral membranes(AJC)byAPCandotherproteincomplexes;microtubule/dynein-dependentdeliveryofmRNAs totheapicalregionisrequiredforproperlocalizationofCrumbs,Sdt (PALS1),andPAR3.Modules:Polarity protein complexes regulate several pathways critical for the establishment and maintenance of apical–basal polarity.Generally,expressionofE-cadherin,Polarityproteincomplexes,andECMproteinsarerequiredto establish and maintain apical–basal polarity (epithelial program). Extracellular cues, including growth factors/cytokines (e.g., TGF-b or HGF) and the transcriptional repressors Snail and ZEB1 down-regulate expressionofthisepithelialprogramcausingthelossofepithelialdifferentiationandcell–celladhesion,and resulting in a front–rear polarization and cell migration (the transcriptional module). Plasma membrane module involves mutually antagonistic regulation of the Crumbs (apical domain) and Scribble (basolateral domain)complexes,andthePARcomplex.TheParcomplexalsolocallyregulatesRac1andRhoattheAJC (see text for details). Components of the Crumbs (Crumbs3) and PAR complexes are localized to the primary cilium (the primary cilium module) and regulate global cell polarity. The Crumbs complex (the endocytosis module) and Scribble complex (the exocytosis module) control membrane protein organization andstabilityattheAJC(seetextfordetails).Finally,theScribblecomplexappearstoplayaroleinregulating apoptosis(theapoptosismodule). apicalregionofthecell(seethefollowing).Itis theapicaldomain.Localizationofthesedifferent unclear how PtdIns(3,4,5)P and PtdIns(3,4)P phosphatidylinositidestotheapicalandbasolat- 3 2 arelocallysynthesizedandlocalizedtodifferent eral membranes is important in apical–basal membrane domains. One mechanism may polarityasectopicadditionofeitherphosphati- involve localization of PTEN, which converts dylinositide to the “wrong” plasma membrane PtdIns(3,4,5)P to PtdIns(3,4)P , to the PAR domain results in reversal of the apical–basal 3 2 complexattheAJC(vonSteinetal.2005).This polarity of membrane proteins (Martin- could prevent PtdIns(3,4,5)P accumulation in Belmonteetal.2007). 3 8 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press RemodelingEpithelialCellOrganization Apical–BasalPolarizationofEndocyticand a template for binding the basal network of ExocyticMembraneTraffickingPathways microtubules (Reilein and Nelson 2005), and is associated with microtubules and the adhe- As the cell generates apical–basal polarity, the rens junction in some cell types (Hamada exocytic and endocytic pathways establish a and Bienz 2002) (Fig. 3). Microtubules may complexinterrelationshipthatregulatescorrect also attach indirectly to the cadherin–catenin sorting of newly synthesized proteins to and complex (adherens junction) through inter- between the apical and basolateral membrane actions with the dynactin complex (Lien et al. domains. 2008; Ligon and Holzbaur 2007), and A major sorting site for newly synthesized p120catenin and kinesin 1 (Chen et al. 2003). proteins in the exocytic pathway is the TGN A population of microtubules is also localized (Fig. 1B). Two pathways have been identified to the adherens junction through their minus that sort apical proteins by clustering them endsbyNezhaandPLEKHA7thatbindtothe into a microdomain of the TGN from which cadherin–catenincomplex(Mengetal.2008). apical transport vesicles form (reviewed in Docking and fusion of vesicles with the SchuckandSimons2004):clusteringbyglyco- correctmembranedomainrequiresspecificves- lipidraftsenrichedinsphingolipidsandcholes- icletetheringandSNAREcomplexes(Fig.1B). terol (Paladino et al. 2007), or by association The exocyst vesicle-tethering complex is lo- with galectin-3 oligomers (Delacour et al. calized to the apex of the lateral membrane 2005). Sorting in the basolateral pathway domainandspecifiesbasolateralvesicledelivery involves recognition of diverse cytoplasmic there(Grindstaffetal.1998).However,therole sortingsignalsbycytosolicfactors,whichcluster of the exocyst in vesicle trafficking in apical– theseproteinsintoaTGNmicro-domainsepa- basalpolarizedcellsmaybemoremultifaceted. ratefromthatcontainingapicalproteins.Many The exocyst has also been localized to apical of these basolateral signals are either tyrosine- endosomes where it regulates transcytosis of ordileucine-basedandarerecognizedbycyto- membraneproteinsbetweenthebasolateraland solic adaptor proteins (AP) and clathrin apicalmembranes(Oztanetal.2007),andatthe (reviewed in Folsch 2008; Mellman and apically localized primary cilium (Overgaard Nelson2008).APsandclathrinarealsoinvolved et al. 2009). In both cases, the exocyst likely in sorting proteins in the endocytic pathway acts as a vesicle-tethering complex, similar to (Edeling et al. 2006), and several studies have itsfunctionattheplasmamembrane. showedtheintersectionofthebasolateralexo- Different t-SNAREs are localized to the cytic and endocytic pathways in basolateral apical (syntaxin 3) and basolateral (syntaxin proteinsorting(Gravottaetal.2007)andtrans- 4) membranes (Low et al. 1996) (Fig. 3) and cytosisofproteinsbetweendifferentmembrane specifythedeliveryofcognatetransportvesicles domains(Casanovaetal.1990). withthecorrectmembranedomain.Thisdiffer- Some of the vesicletrafficking betweenthe entiallocalizationisrequiredforcorrectvesicle TGN and plasma membrane, and transcytosis deliveryasmislocalizationof syntaxin 3tothe between membrane domains occurs along basolateral membrane causes apical proteins microtubules (Jaulin et al. 2007; Lafont et al. tobemistargetedtothebasolateralmembrane 1994).Microtubulesareorganizedintobundles (Sharmaetal.2006). aligned in the apical–basal axis of the cell, with plus ends at the basal membrane and Apical–BasalOrganizationandFunctionof minus ends in the apical cytoplasm (Fig. 1B) PolarityProteins (Bacallao et al. 1989). How microtubules are maintained in this apical–basal organization Adistinctivefeatureofpolarizedepitheliaisthe is poorly understood. Adenomatous polyposis spatial distribution of intercellular junctional coli (APC), a microtubule binding protein complexes and Polarity protein complexes associated with the plasma membrane, forms (Crumbs,PAR,andScribble).Invertebrateand CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513 9 Downloaded from http://cshperspectives.cshlp.org/ on March 14, 2023 - Published by Cold Spring Harbor Laboratory Press W.J.Nelson invertebrate epithelial cells, the adherensjunc- 2005) and Stardust (Sdt, the Drosophila tionandthetightjunctionarelocalizedtothe homolog of mammalian PALS1) (Fig. 3) apexof the lateral membrane (the AJC) at the (Horne-Badovinac and Bilder 2008). Mecha- boundary between the apical and basolateral nisms involved in localization of the Scribble plasma membrane domains. In invertebrates, complex to the lateral membrane below the the functional homolog of the tight junction, AJCareunknown. the septate junction, is localized on the basal sideoftheadherensjunction. DownstreamEffectorsofPolarityProteinsin Polarityproteinshavedistinctdistributions Apical–BasalPolarity attheAJC(Fig.3;theplasmamembraneidentity module).TheCrumbscomplexislocatedtothe The different distributions of Polarity protein apical side of the AJC (Tanentzapf and Tepass complexesaroundtheAJCarecriticaltomain- 2003), and at the primary cilium (Fan et al. tainingtheidentityoftheapicalandbasolateral 2004); the PAR complex is localized close to membrane domains (Fig.3; plasmamembrane the AJC (Bilder et al. 2003; Izumi et al. 1998) identitymodule).GeneticstudiesinDrosophila and at the primary cilium (Sfakianos et al. showed that the Crumbs complex is required 2007); and the Scribble complex is localized to regulate the formation of the apical mem- on the lateral membrane below the AJC brane, whereas the Scribble complex regulates (Bilderetal.2003;TanentzapfandTepass2003). the basolateral membrane; loss-of-function Several mechanisms regulate the different mutations in the Crumbs complexor Scribble distributions of these Polarity protein com- complex result in defects in apical–basal plexes. In mammalian cells, the PAR complex polaritybecauseofalossoftheapicalandbaso- binds through PAR3 to two cell–cell adhe- lateral membrane domain, respectively (Bilder sion proteins, junction-associated molecule-A et al. 2003; Tanentzapf and Tepass 2003). (JAM-A) (Ebnet et al. 2003) and nectin Importantly,lossofeither Crumbs orScribble (Takekuni et al. 2003), that colocalize with signaling can be compensated by decreased E-cadherinintheAJC.PAR4/LKB1alsoclosely expressionofScribbleorCrumbs,respectively, colocalizes with E-cadherin (Sebbagh et al. demonstrating that functions of these com- 2009),whichmaylocallyregulateitsactivation plexes are mutually antagonistic (Bilder et al. of PAR1 and MARKs, and thereby the organi- 2003;TanentzapfandTepass2003). zationofmicrotubulesandthedeliveryofves- Despite strong genetic evidence for the icles to the plasma membrane (Cohen et al. importance of these Polarity complexes in 2004a;Cohenetal.2004b;Elbertetal.2005). apical–basal polarity of epithelial cells, their In vitro studies indicate that binding be- functions remain poorly understood. This is tween different PDZ domain-containing pro- in contrast to roles for the PAR complex, par- teins in the PAR complex (PAR3 and PAR6) ticularly aPKC, and some proteins in the andCrumbscomplex(PALS1andPATJ)could Scribble complex in front–rear polarity in be involved in positioning the Crumbs migrating cells (localization and activation of complex close to the PAR complex in the Rho family small GTPases, orientation of the region of the AJC (Fig. 3) (Lemmers et al. actin and microtubule cytoskeleton, and 2004; Roh and Margolis 2003). Other studies vesicle trafficking) (see Fig. 2). Are any of in Drosophila have shown that restriction of these functions important for apical–basal Crumbs to the apical domain of epithelial polarityinepithelialcells? cells also requires dynein-dependent basal-to- RhofamilyGTPasesplayanumberofroles apical transport of Crumbs mRNA along in polarized epithelial cells (Fig. 3; plasma microtubules and localized translation in the membrane identity module). At the adherens apical cytoplasm (Li et al. 2008). A similar junction, the activities of Rac and Rho antag- mechanism maybeimportantin apical locali- onize each other as Rac stabilizes junctions, zation of PAR3/bazooka (Harris and Peifer whereas Rho induces actomyosin contraction 10 CitethisarticleasColdSpringHarbPerspectBiol2009;1:a000513