Mechanisms for de novo biogenesis of an apical membrane compartment in groups of simple epithelial cells surrounded by extracellular matrix

1997 ◽  
Vol 110 (22) ◽  
pp. 2781-2794 ◽  
Author(s):  
G.K. Ojakian ◽  
W.J. Nelson ◽  
K.A. Beck
Keyword(s):  
Epithelial Cells ◽  
Cell Surface ◽  
Golgi Complex ◽  
De Novo ◽  
Apical Membrane ◽  
Free Cell ◽  
Cell Contacts ◽  
Lateral Membrane ◽  
Cell Cell

In open monolayers of epithelial cells grown in vitro, the apical membrane domain forms on the free cell surface that faces the culture medium. However, in vivo, the apical lumenal compartment arises within groups of cells that do not have a free cell surface. We designed in vitro culture conditions, using small colonies of MDCK cells overlaid with collagen, in which formation of the apical membrane must occur de novo by remodeling existing membrane domains that are contacted by other cells or extracellular matrix. Within 12 hours of collagen overlay, the apical membrane glycoprotein gp135 is removed from the free cell surface, while lateral membrane proteins (e.g. Na+,K+-ATPase) remain at sites of cell-cell contacts. Subsequently, lumenal structures, containing gp135 and the apically secreted protein gp81, formed within these cell-cell contacts. Na+,K+-ATPase, adherens junction (E-cadherin, alpha- and beta-catenins) and tight junction (ZO-1) proteins were localized on the lateral membrane adjacent to, but excluded from the gp135-positive lumenal compartment. Therefore, each lumen represents a newly formed apical compartment on the lateral membrane. The Golgi complex (alpha-mannosidase II and Golgi beta-spectrin), centrosomes (gamma-tubulin) and microtubules reorient to a cytoplasmic position adjacent to the newly-forming apical lumenal compartments. Significantly, addition of colchicine, nocodazole or brefeldin A inhibits apical lumen formation. These results demonstrate that simple epithelial cells form an apical lumenal compartment de novo through initial intermixing, and then sorting of apical and basal-lateral membrane proteins at sites of cell-cell contacts. In addition, apical lumen formation requires an intact microtubule network, microtubule-dependent reorientation of the Golgi complex and secretory apparatus, and fully functional protein delivery from the Golgi complex to the forming apical cell surface.

Determinants of apical membrane formation and distribution in multicellular epithelial MDCK cysts

1994 ◽  
Vol 267 (2) ◽  
pp. C473-C481 ◽  
Author(s):  
A. Z. Wang ◽  
J. C. Wang ◽  
G. K. Ojakian ◽  
W. J. Nelson
Keyword(s):  
Membrane Proteins ◽  
Cell Surface ◽  
De Novo ◽  
Apical Membrane ◽  
Three Dimensional ◽  
Collagen Gel ◽  
Free Cell ◽  
Surface Polarity ◽  
Marker Proteins ◽  
Spinner Culture

Madin-Darby canine kidney epithelial cells form three-dimensional cysts in spinner culture with a defined cell surface polarity. Transfer of cysts from spinner culture to a collagen gel matrix results in rapid loss of apical membrane proteins from the outside surface of the cyst, degradation of extracellular matrix (ECM) from the cyst lumen, and de novo formation of the apical membrane at the luminal surface. Degradation of endogenous ECM was inhibited with 1,10-phenanthroline, an inhibitor of metalloproteinases, resulting in cysts in which cells are surrounded by either cell-cell or cell-substratum contacts. The consequence of the lack of a free cell surface on the formation of a new apical membrane domain in these cysts was analyzed. Changes in cell surface polarity were followed with antibodies to marker proteins of the apical or basolateral membranes. In the absence of a free cell surface, the apical membrane formed de novo by accumulation and fusion of presorted vesicles containing apical membrane proteins; the coalescence of these vesicles results in the formation of a central lumen. These results provide novel insights into the generation of membrane domains and formation of a lumen in complex, three-dimensional epithelial structures in development.

scholarly journals Sec6/8 Complex Is Recruited to Cell–Cell Contacts and Specifies Transport Vesicle Delivery to the Basal-Lateral Membrane in Epithelial Cells

Cell ◽  
1998 ◽  
Vol 93 (5) ◽  
pp. 731-740 ◽  
Author(s):  
Kent K Grindstaff ◽  
Charles Yeaman ◽  
Niroshana Anandasabapathy ◽  
Shu-Chan Hsu ◽  
Enrique Rodriguez-Boulan ◽  
...  
Keyword(s):  
Epithelial Cells ◽  
Cell Contacts ◽  
Lateral Membrane ◽  
Transport Vesicle ◽  
Cell Cell

scholarly journals Biogenesis of Polarized Epithelial Cells During Kidney Development In Situ: Roles of E-Cadherin–mediated Cell–Cell Adhesion and Membrane Cytoskeleton Organization

1998 ◽  
Vol 9 (11) ◽  
pp. 3161-3177 ◽  
Author(s):  
Peter A. Piepenhagen ◽  
W. James Nelson
Keyword(s):  
Cell Adhesion ◽  
Epithelial Cells ◽  
Kidney Development ◽  
Lateral Membrane ◽  
Membrane Cytoskeleton ◽  
Triton X ◽  
E Cadherin ◽  
Cell Cell

Organization of proteins into structurally and functionally distinct plasma membrane domains is an essential characteristic of polarized epithelial cells. Based on studies with cultured kidney cells, we have hypothesized that a mechanism for restricting Na/K-ATPase to the basal-lateral membrane involves E-cadherin–mediated cell–cell adhesion and integration of Na/K-ATPase into the Triton X-100–insoluble ankyrin- and spectrin-based membrane cytoskeleton. In this study, we examined the relevance of these in vitro observations to the generation of epithelial cell polarity in vivo during mouse kidney development. Using differential detergent extraction, immunoblotting, and immunofluorescence histochemistry, we demonstrate the following. First, expression of the 220-kDa splice variant of ankyrin-3 correlates with the development of resistance to Triton X-100 extraction for Na/K-ATPase, E-cadherin, and catenins and precedes maximal accumulation of Na/K-ATPase. Second, expression of the 190-kDa slice variant of ankyrin-3 correlates with maximal accumulation of Na/K-ATPase. Third, Na/K-ATPase, ankyrin-3, and fodrin specifically colocalize at the basal-lateral plasma membrane of all epithelial cells in which they are expressed and during all stages of nephrogenesis. Fourth, the relative immunofluorescence staining intensities of Na/K-ATPase, ankyrin-3, and fodrin become more similar during development until they are essentially identical in adult kidney. Thus, renal epithelial cells in vivo regulate the accumulation of E-cadherin–mediated adherens junctions, the membrane cytoskeleton, and Na/K-ATPase through sequential protein expression and assembly on the basal-lateral membrane. These results are consistent with a mechanism in which generation and maintenance of polarized distributions of these proteins in vivo and in vitro involve cell–cell adhesion, assembly of the membrane cytoskeleton complex, and concomitant integration and retention of Na/K-ATPase in this complex.

scholarly journals Targeting of the SF/HGF receptor to the basolateral domain of polarized epithelial cells.

1994 ◽  
Vol 125 (2) ◽  
pp. 313-320 ◽  
Author(s):  
T Crepaldi ◽  
A L Pollack ◽  
M Prat ◽  
A Zborek ◽  
K Mostov ◽  
...  
Keyword(s):  
Epithelial Cells ◽  
Cell Surface ◽  
Mdck Cells ◽  
Cell Contact ◽  
Apical Surface ◽  
Surface Distribution ◽  
Polarized Epithelial Cells ◽  
Cell Cell

Scatter Factor, also known as Hepatocyte Growth Factor (SF/HGF), has pleiotropic functions including direct control of cell-cell and cell-substrate adhesion in epithelia. The subcellular localization of the SF/HGF receptor is controversial. In this work, the cell surface distribution of the SF/HGF receptor was studied in vivo in epithelial tissues and in vitro in polarized MDCK monolayers. A panel of monoclonal antibodies against the beta chain of the SF/HGF receptor stained the basolateral but not the apical surface of epithelia lining the lumen of human organs. Radiolabeled or fluorescent-tagged anti-receptor antibodies selectively bound the basolateral cell surface of MDCK cells, which form a polarized monolayer sealed by intercellular junctions, when grown on polycarbonate filters in a two-chamber culture system. The receptor was concentrated around the cell-cell contact zone, showing a distribution pattern overlapping with that of the cell adhesion molecule E-cadherin. The basolateral localization of the SF/HGF receptor was confirmed by immunoprecipitation after domain selective cell surface biotinylation. When cells were fully polarized the SF/HGF receptor became resistant to non-ionic detergents, indicating interaction with insoluble component(s). In pulse-chase labeling and surface biotinylation experiments, the newly synthesized receptor was found exclusively at the basolateral surface. We conclude that the SF/HGF receptor is selectively exposed at the basolateral plasma membrane domain of polarized epithelial cells and is targeted after synthesis to that surface by direct delivery from the trans-Golgi network.

scholarly journals Remodeling the cell surface distribution of membrane proteins during the development of epithelial cell polarity.

1992 ◽  
Vol 116 (4) ◽  
pp. 889-899 ◽  
Author(s):  
D A Wollner ◽  
K A Krzeminski ◽  
W J Nelson
Keyword(s):  
Epithelial Cell ◽  
Membrane Proteins ◽  
Cell Surface ◽  
Mdck Cells ◽  
Apical Cell ◽  
Cell Contact ◽  
Surface Polarity ◽  
Lateral Membrane ◽  
E Cadherin ◽  
Cell Cell

The development of polarized epithelial cells from unpolarized precursor cells follows induction of cell-cell contacts and requires resorting of proteins into different membrane domains. We show that in MDCK cells the distributions of two membrane proteins, Dg-1 and E-cadherin, become restricted to the basal-lateral membrane domain within 8 h of cell-cell contact. During this time, however, 60-80% of newly synthesized Dg-1 and E-cadherin is delivered directly to the forming apical membrane and then rapidly removed, while the remainder is delivered to the basal-lateral membrane and has a longer residence time. Direct delivery of greater than 95% of these proteins from the Golgi complex to the basal-lateral membrane occurs greater than 48 h later. In contrast, we show that two apical proteins are efficiently delivered and restricted to the apical cell surface within 2 h after cell-cell contact. These results provide insight into mechanisms involved in the development of epithelial cell surface polarity, and the establishment of protein sorting pathways in polarized cells.

scholarly journals Salmonella typhimurium attachment to human intestinal epithelial monolayers: transcellular signalling to subepithelial neutrophils.

1993 ◽  
Vol 123 (4) ◽  
pp. 895-907 ◽  
Author(s):  
B A McCormick ◽  
S P Colgan ◽  
C Delp-Archer ◽  
S I Miller ◽  
J L Madara
Keyword(s):  
Epithelial Cells ◽  
Salmonella Typhimurium ◽  
Apical Membrane ◽  
Coli Strain ◽  
Formyl Peptide Receptor ◽  
Human Neutrophils ◽  
Classical Pathway ◽  
Intestinal Epithelial ◽  
Formyl Peptide

In human intestinal disease induced by Salmonella typhimurium, transepithelial migration of neutrophils (PMN) rapidly follows attachment of the bacteria to the epithelial apical membrane. In this report, we model those interactions in vitro, using polarized monolayers of the human intestinal epithelial cell, T84, isolated human PMN, and S. typhimurium. We show that Salmonella attachment to T84 cell apical membranes did not alter monolayer integrity as assessed by transepithelial resistance and measurements of ion transport. However, when human neutrophils were subsequently placed on the basolateral surface of monolayers apically colonized by Salmonella, physiologically directed transepithelial PMN migration ensued. In contrast, attachment of a non-pathogenic Escherichia coli strain to the apical membrane of epithelial cells at comparable densities failed to stimulate a directed PMN transepithelial migration. Use of the n-formyl-peptide receptor antagonist N-t-BOC-1-methionyl-1-leucyl-1- phenylalanine (tBOC-MLP) indicated that the Salmonella-induced PMN transepithelial migration response was not attributable to the classical pathway by which bacteria induce directed migration of PMN. Moreover, the PMN transmigration response required Salmonella adhesion to the epithelial apical membrane and subsequent reciprocal protein synthesis in both bacteria and epithelial cells. Among the events stimulated by this interaction was the epithelial synthesis and polarized release of the potent PMN chemotactic peptide interleukin-8 (IL-8). However, IL-8 neutralization, transfer, and induction experiments indicated that this cytokine was not responsible for the elicited PMN transmigration. These data indicate that a novel transcellular pathway exists in which subepithelial PMN respond to lumenal pathogens across a functionally intact epithelium. Based on the known unique characteristics of the intestinal mucosa, we speculate that IL-8 may act in concert with an as yet unidentified transcellular chemotactic factor(s) (TCF) which directs PMN migration across the intestinal epithelium.

Developmental aspects of secondary palate formation

Development ◽  
1976 ◽  
Vol 36 (2) ◽  
pp. 225-245
Author(s):  
Robert M. Greene ◽  
Robert M. Pratt
Keyword(s):  
Extracellular Matrix ◽  
Cell Death ◽  
Epithelial Cells ◽  
Cell Surface ◽  
Hydrolytic Enzymes ◽  
Cellular Adhesion ◽  
Control Mechanisms ◽  
Adhesive Interaction ◽  
Secondary Palate

Research on development of the secondary palate has, in the past, dealt primarily with morphological aspects of shelf elevation and fusion. The many factors thought to be involved in palatal elevation, such as fetal neuromuscular activity and growth of the cranial base and mandible, as well as production of extracellular matrix and contractile elements in the palate, are mostly based on gross, light microscopic, morphometric or histochemical observations. Recently, more biochemical procedures have been utilized to describe palatal shelf elevation. Although these studies strongly suggest that palatal extracellular matrix plays a major role in shelf movement, interpretation of these data remains difficult owing to the complexity of tissue interactions involved in craniofacial development. Shelf elevation does not appear to involve a single motive factor, but rather a coordinated interaction of all of the abovementioned developmental events. Further analysis of mechanisms of shelf elevation requires development of new, and refinement of existing, in vitro procedures. A system that enables one to examine shelf elevation in vitro would allow more meaningful analysis of the relative importance of the various components in shelf movement. Much more is known about fusion of the palatal shelves, owing in large part to in vitro studies. Fusion of the apposing shelves, both in vivo and in vitro, is dependent upon adhesion and cell death of the midline epithelial cells. Adhesion between apposing epithelial surfaces appears to involve epithelial cell surface macromolecules. Further analysis of palatal epithelial adhesion should be directed towards characterization of those cell surface components responsible for this adhesive interaction. Midline epithelial cells cease DNA synthesis 24–36 h before shelf elevation and contact, become active in the synthesis of cell surface glycoproteins, and subsequently manifest morphological signs of necrosis. Death of the midline epithelial cells is thought to involve a programmed, lysosomal-mediated autolysis. Information regarding the appearance, distribution and quantitation of epithelial hydrolytic enzymes is needed. The control mechanisms which regulate adhesiveness and cell death in the palatal epithelium are not fully understood. Although palatal epithelial-mesenchymal recombination experiments have demonstrated a close relationship between the underlying mesenchyme and the differentiating epithelium, the molecular mechanism of interaction remains unclear. Recently cyclic nucleotides have been implicated as possible mediators of palatal epithelial differentiation. The developing secondary palate therefore offers a system whereby one can probe a variety of developmental phenomena. Cellular adhesion, programmed cell death and epithelial- mesenchymal interactions are all amenable to both morphological as well as bio- chemical analysis. Although research in the field of secondary palate development has been extensive, there still remain many provocative questions relating to normal development of this structure.

scholarly journals A molecular mechanism directly linking E-cadherin adhesion to initiation of epithelial cell surface polarity

2007 ◽  
Vol 178 (2) ◽  
pp. 323-335 ◽  
Author(s):  
Lene N. Nejsum ◽  
W. James Nelson
Keyword(s):  
Cell Adhesion ◽  
Epithelial Cell ◽  
Cell Surface ◽  
Basolateral Membrane ◽  
Surface Polarity ◽  
Cell Contacts ◽  
Protein Receptors ◽  
Epithelial Cell Surface ◽  
E Cadherin ◽  
Cell Cell

Mechanisms involved in maintaining plasma membrane domains in fully polarized epithelial cells are known, but when and how directed protein sorting and trafficking occur to initiate cell surface polarity are not. We tested whether establishment of the basolateral membrane domain and E-cadherin–mediated epithelial cell–cell adhesion are mechanistically linked. We show that the basolateral membrane aquaporin (AQP)-3, but not the equivalent apical membrane AQP5, is delivered in post-Golgi structures directly to forming cell–cell contacts where it co-accumulates precisely with E-cadherin. Functional disruption of individual components of a putative lateral targeting patch (e.g., microtubules, the exocyst, and soluble N-ethylmaleimide–sensitive factor attachment protein receptors) did not inhibit cell–cell adhesion or colocalization of the other components with E-cadherin, but each blocked AQP3 delivery to forming cell–cell contacts. Thus, components of the lateral targeting patch localize independently of each other to cell–cell contacts but collectively function as a holocomplex to specify basolateral vesicle delivery to nascent cell–cell contacts and immediately initiate cell surface polarity.

Contributions of extracellular and intracellular domains of full length and chimeric cadherin molecules to junction assembly in epithelial cells

1998 ◽  
Vol 111 (9) ◽  
pp. 1305-1318 ◽  
Author(s):  
S.M. Norvell ◽  
K.J. Green
Keyword(s):  
Epithelial Cells ◽  
Cell Surface ◽  
Extracellular Domain ◽  
Full Length ◽  
Intracellular Domain ◽  
Epithelial Junctions ◽  
Intracellular Domains ◽  
E Cadherin ◽  
Cell Cell

The integrity of cell-cell junctions in epithelial cells depends on functional interactions of both extracellular and intracellular domains of cadherins with other junction proteins. To examine the roles of the different domains of E-cadherin and desmoglein in epithelial junctions, we stably expressed full length desmoglein 1 and chimeras of E-cadherin and desmoglein 1 in A431 epithelial cells. Full length desmoglein 1 was able to incorporate into or disrupt endogenous desmosomes depending on expression level. Each of the chimeric cadherin molecules exhibited distinct localization patterns at the cell surface. A chimera of the desmoglein 1 extracellular domain and the E-cadherin intracellular domain was distributed diffusely at the cell surface while the reverse chimera, comprising the E-cadherin extracellular domain and the desmoglein 1 intracellular domain, localized in large, sometimes contiguous patches at cell-cell interfaces. Nevertheless, both constructs disrupted desmosome assembly. Expression of constructs containing the desmoglein 1 cytoplasmic domain resulted in approximately a 3-fold decrease in E-cadherin bound to plakoglobin and a 5- to 10-fold reduction in the steady-state levels of the endogenous desmosomal cadherins, desmoglein 2 and desmocollin 2, possibly contributing to the dominant negative effect of the desmoglein 1 tail. In addition, biochemical analysis of protein complexes in the stable lines revealed novel in vivo protein interactions. Complexes containing beta-catenin and desmoglein 1 were identified in cells expressing constructs containing the desmoglein 1 tail. Furthermore, interactions were identified between endogenous E-cadherin and the chimera containing the E-cadherin extracellular domain and the desmoglein 1 intracellular domain providing in vivo evidence for previously predicted lateral interactions of E-cadherin extracellular domains.

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