An Apical-Type Trafficking Pathway Is Present in Cultured Oligodendrocytes but the Sphingolipid-enriched Myelin Membrane Is the Target of a Basolateral-Type Pathway

Myelin sheets originate from distinct areas at the oligodendrocyte (OLG) plasma membrane and, as opposed to the latter, myelin membranes are relatively enriched in glycosphingolipids and cholesterol. The OLG plasma membrane can therefore be considered to consist of different membrane domains, as in polarized cells; the myelin sheet is reminiscent of an apical membrane domain and the OLG plasma membrane resembles the basolateral membrane. To reveal the potentially polarized membrane nature of OLG, the trafficking and sorting of two typical markers for apical and basolateral membranes, the viral proteins influenza virus–hemagglutinin (HA) and vesicular stomatitis virus–G protein (VSVG), respectively, were examined. We demonstrate that in OLG, HA and VSVG are differently sorted, which presumably occurs upon their trafficking through the Golgi. HA can be recovered in a Triton X-100-insoluble fraction, indicating an apical raft type of trafficking, whereas VSVG was only present in a Triton X-100-soluble fraction, consistent with its basolateral sorting. Hence, both an apical and a basolateral sorting mechanism appear to operate in OLG. Surprisingly, however, VSVG was found within the myelin sheets surrounding the cells, whereas HA was excluded from this domain. Therefore, despite its raft-like transport, HA does not reach a membrane that shows features typical of an apical membrane. This finding indicates either the uniqueness of the myelin membrane or the requirement of additional regulatory factors, absent in OLG, for apical delivery. These remarkable results emphasize that polarity and regulation of membrane transport in cultured OLG display features that are quite different from those in polarized cells.

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The Major Myelin-Resident Protein PLP Is Transported to Myelin Membranes via a Transcytotic Mechanism: Involvement of Sulfatide

Molecular and Cellular Biology ◽

10.1128/mcb.00848-14 ◽

2014 ◽

Vol 35 (1) ◽

pp. 288-302 ◽

Cited By ~ 17

Author(s):

Wia Baron ◽

Hande Ozgen ◽

Bert Klunder ◽

Jenny C. de Jonge ◽

Anita Nomden ◽

...

Keyword(s):

Plasma Membrane ◽

Cell Body ◽

Proteolipid Protein ◽

Membrane Microdomains ◽

Apical Surface ◽

Membrane Domains ◽

Myelin Membrane ◽

Conformational Alteration ◽

Syntaxin 3 ◽

Triton X

Myelin membranes are sheet-like extensions of oligodendrocytes that can be considered membrane domains distinct from the cell's plasma membrane. Consistent with the polarized nature of oligodendrocytes, we demonstrate that transcytotic transport of the major myelin-resident protein proteolipid protein (PLP) is a key element in the mechanism of myelin assembly. Upon biosynthesis, PLP traffics to myelin membranes via syntaxin 3-mediated docking at the apical-surface-like cell body plasma membrane, which is followed by subsequent internalization and transport to the basolateral-surface-like myelin sheet. Pulse-chase experiments, in conjunction with surface biotinylation and organelle fractionation, reveal that following biosynthesis, PLP is transported to the cell body surface in Triton X-100 (TX-100)-resistant microdomains. At the plasma membrane, PLP transiently resides within these microdomains and its lateral dissipation is followed by segregation into 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS)-resistant domains, internalization, and subsequent transport toward the myelin membrane. Sulfatide triggers PLP's reallocation from TX-100- into CHAPS-resistant membrane domains, while inhibition of sulfatide biosynthesis inhibits transcytotic PLP transport. Taking these findings together, we propose a model in which PLP transport to the myelin membrane proceeds via a transcytotic mechanism mediated by sulfatide and characterized by a conformational alteration and dynamic, i.e., transient, partitioning of PLP into distinct membrane microdomains involved in biosynthetic and transcytotic transport.

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Apiconuclear Organization of Microtubules Does Not Specify Protein Delivery from the Trans-Golgi Network to Different Membrane Domains in Polarized Epithelial Cells

Molecular Biology of the Cell ◽

10.1091/mbc.9.3.685 ◽

1998 ◽

Vol 9 (3) ◽

pp. 685-699 ◽

Cited By ~ 56

Author(s):

Kent K. Grindstaff ◽

Robert L. Bacallao ◽

W. James Nelson

Keyword(s):

Plasma Membrane ◽

Epithelial Cells ◽

Golgi Complex ◽

Apical Membrane ◽

Basolateral Membrane ◽

Membrane Domains ◽

Trans Golgi Network ◽

G Cells ◽

Polarized Epithelial Cells ◽

Golgi Network

In nonpolarized epithelial cells, microtubules originate from a broad perinuclear region coincident with the distribution of the Golgi complex and extend outward to the cell periphery (perinuclear [PN] organization). During development of epithelial cell polarity, microtubules reorganize to form long cortical filaments parallel to the lateral membrane, a meshwork of randomly oriented short filaments beneath the apical membrane, and short filaments at the base of the cell; the Golgi becomes localized above the nucleus in the subapical membrane cytoplasm (apiconuclear [AN] organization). The AN-type organization of microtubules is thought to be specialized in polarized epithelial cells to facilitate vesicle trafficking between the trans-Golgi Network (TGN) and the plasma membrane. We describe two clones of MDCK cells, which have different microtubule distributions: clone II/G cells, which gradually reorganize a PN-type distribution of microtubules and the Golgi complex to an AN-type during development of polarity, and clone II/J cells which maintain a PN-type organization. Both cell clones, however, exhibit identical steady-state polarity of apical and basolateral proteins. During development of cell surface polarity, both clones rapidly establish direct targeting pathways for newly synthesized gp80 and gp135/170, and E-cadherin between the TGN and apical and basolateral membrane, respectively; this occurs before development of the AN-type microtubule/Golgi organization in clone II/G cells. Exposure of both clone II/G and II/J cells to low temperature and nocodazole disrupts >99% of microtubules, resulting in: 1) 25–50% decrease in delivery of newly synthesized gp135/170 and E-cadherin to the apical and basolateral membrane, respectively, in both clone II/G and II/J cells, but with little or no missorting to the opposite membrane domain during all stages of polarity development; 2) ∼40% decrease in delivery of newly synthesized gp80 to the apical membrane with significant missorting to the basolateral membrane in newly established cultures of clone II/G and II/J cells; and 3) variable and nonspecific delivery of newly synthesized gp80 to both membrane domains in fully polarized cultures. These results define several classes of proteins that differ in their dependence on intact microtubules for efficient and specific targeting between the Golgi and plasma membrane domains.

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Cholesterol Is Required for Surface Transport of Influenza Virus Hemagglutinin

The Journal of Cell Biology ◽

10.1083/jcb.140.6.1357 ◽

1998 ◽

Vol 140 (6) ◽

pp. 1357-1367 ◽

Cited By ~ 392

Author(s):

Patrick Keller ◽

Kai Simons

Keyword(s):

Influenza Virus ◽

Membrane Proteins ◽

Basolateral Membrane ◽

Surface Transport ◽

Influenza Virus Hemagglutinin ◽

Vesicular Stomatitis ◽

Apical Sorting ◽

Triton X ◽

Level Of Living ◽

First Time

Transport from the TGN to the basolateral surface involves a rab/N-ethylmaleimide–sensitive fusion protein (NSF)/soluble NSF attachment protein (SNAP)/SNAP receptor (SNARE) mechanism. Apical transport instead is thought to be mediated by detergent-insoluble sphingolipid–cholesterol rafts. By reducing the cholesterol level of living cells by 60–70% with lovastatin and methyl-β-cyclodextrin, we show that the TGN-to-surface transport of the apical marker protein influenza virus hemagglutinin was slowed down, whereas the transport of the basolateral marker vesicular stomatitis virus glycoprotein as well as the ER-to-Golgi transport of both membrane proteins was not affected. Reduction of transport of hemagglutinin was accompanied by increased solubility in the detergent Triton X-100 and by significant missorting of hemagglutinin to the basolateral membrane. In addition, depletion of cellular cholesterol by lovastatin and methyl-β-cyclodextrin led to missorting of the apical secretory glycoprotein gp-80, suggesting that gp-80 uses a raft-dependent mechanism for apical sorting. Our data provide for the first time direct evidence for the functional significance of cholesterol in the sorting of apical membrane proteins as well as of apically secreted glycoproteins.

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Gp135/podocalyxin and NHERF-2 participate in the formation of a preapical domain during polarization of MDCK cells

The Journal of Cell Biology ◽

10.1083/jcb.200407072 ◽

2005 ◽

Vol 168 (2) ◽

pp. 303-313 ◽

Cited By ~ 121

Author(s):

Doris Meder ◽

Anna Shevchenko ◽

Kai Simons ◽

Joachim Füllekrug

Keyword(s):

Free Surface ◽

Apical Membrane ◽

Mdck Cells ◽

Single Cells ◽

Basolateral Membrane ◽

Pdz Domain ◽

Binding Motif ◽

Membrane Domains ◽

Regulatory Factor ◽

Pdz Protein

Epithelial polarization involves the segregation of apical and basolateral membrane domains, which are stabilized and maintained by tight junctions and membrane traffic. We report that unlike most apical and basolateral proteins in MDCK cells, which separate only after junctions have formed, the apical marker gp135 signifies an early level of polarized membrane organization established already in single cells. We identified gp135 as the dog orthologue of podocalyxin. With a series of domain mutants we show that the COOH-terminal PSD-95/Dlg/ZO-1 (PDZ)–binding motif is targeting podocalyxin to the free surface of single cells as well as to a subdomain of the terminally polarized apical membrane. This special localization of podocalyxin is shared by the cytoplasmic PDZ-protein Na+/H+ exchanger regulatory factor (NHERF)-2. Depleting podocalyxin by RNA interference caused defects in epithelial polarization. Together, our data suggest that podocalyxin and NHERF-2 function in epithelial polarization by contributing to an early apical scaffold based on PDZ domain-mediated interactions.

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Sorting of Marburg Virus Surface Protein and Virus Release Take Place at Opposite Surfaces of Infected Polarized Epithelial Cells

Journal of Virology ◽

10.1128/jvi.75.3.1274-1283.2001 ◽

2001 ◽

Vol 75 (3) ◽

pp. 1274-1283 ◽

Cited By ~ 36

Author(s):

Christian Sänger ◽

Elke Mühlberger ◽

Elena Ryabchikova ◽

Larissa Kolesnikova ◽

Hans-Dieter Klenk ◽

...

Keyword(s):

Epithelial Cells ◽

Apical Membrane ◽

Basolateral Membrane ◽

Surface Protein ◽

Hemorrhagic Fever ◽

Marburg Virus ◽

Virus Surface ◽

Mdckii Cells ◽

Vesicular Stomatitis ◽

Polarized Epithelial Cells

ABSTRACT Marburg virus, a filovirus, causes severe hemorrhagic fever with hitherto poorly understood molecular pathogenesis. We have investigated here the vectorial transport of the surface protein GP of Marburg virus in polarized epithelial cells. To this end, we established an MDCKII cell line that was able to express GP permanently (MDCK-GP). The functional integrity of GP expressed in these cells was analyzed using vesicular stomatitis virus pseudotypes. Further experiments revealed that GP is transported in MDCK-GP cells mainly to the apical membrane and is released exclusively into the culture medium facing the apical membrane. When MDCKII cells were infected with Marburg virus, the majority of GP was also transported to the apical membrane, suggesting that the protein contains an autonomous apical transport signal. Release of infectious progeny virions, however, took place exclusively at the basolateral membrane of the cells. Thus, vectorial budding of Marburg virus is presumably determined by factors other than the surface protein.

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Essential function of Drosophila Sec6 in apical exocytosis of epithelial photoreceptor cells

The Journal of Cell Biology ◽

10.1083/jcb.200410081 ◽

2005 ◽

Vol 169 (4) ◽

pp. 635-646 ◽

Cited By ~ 79

Author(s):

Slobodan Beronja ◽

Patrick Laprise ◽

Ophelia Papoulas ◽

Milena Pellikka ◽

John Sisson ◽

...

Keyword(s):

Plasma Membrane ◽

Protein Transport ◽

Basolateral Membrane ◽

Photoreceptor Cells ◽

Secretory Vesicles ◽

Membrane Domains ◽

Animal Cells ◽

Light Sensing ◽

Membrane Growth ◽

Essential Function

Polarized exocytosis plays a major role in development and cell differentiation but the mechanisms that target exocytosis to specific membrane domains in animal cells are still poorly understood. We characterized Drosophila Sec6, a component of the exocyst complex that is believed to tether secretory vesicles to specific plasma membrane sites. sec6 mutations cause cell lethality and disrupt plasma membrane growth. In developing photoreceptor cells (PRCs), Sec6 but not Sec5 or Sec8 shows accumulation at adherens junctions. In late PRCs, Sec6, Sec5, and Sec8 colocalize at the rhabdomere, the light sensing subdomain of the apical membrane. PRCs with reduced Sec6 function accumulate secretory vesicles and fail to transport proteins to the rhabdomere, but show normal localization of proteins to the apical stalk membrane and the basolateral membrane. Furthermore, we show that Rab11 forms a complex with Sec5 and that Sec5 interacts with Sec6 suggesting that the exocyst is a Rab11 effector that facilitates protein transport to the apical rhabdomere in Drosophila PRCs.

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Cytoskeleton-dependent Membrane Domain Segregation during Neutrophil Polarization

Molecular Biology of the Cell ◽

10.1091/mbc.12.11.3550 ◽

2001 ◽

Vol 12 (11) ◽

pp. 3550-3562 ◽

Cited By ~ 86

Author(s):

Stéphanie Seveau ◽

Robert J. Eddy ◽

Frederick R. Maxfield ◽

Lynda M. Pierini

Keyword(s):

Plasma Membrane ◽

Myosin Light Chain ◽

Transmembrane Proteins ◽

Cell Polarization ◽

Membrane Domains ◽

Membrane Domain ◽

Actin Remodeling ◽

Cytoskeletal Rearrangements ◽

Triton X ◽

Detergent Resistant Membrane

On treatment with chemoattractant, the neutrophil plasma membrane becomes organized into detergent-resistant membrane domains (DRMs), the distribution of which is intimately correlated with cell polarization. Plasma membrane at the front of polarized cells is susceptible to extraction by cold Triton X-100, whereas membrane at the rear is resistant to extraction. After cold Triton X-100 extraction, DRM components, including the transmembrane proteins CD44 and CD43, the GPI-linked CD16, and the lipid analog, DiIC16, are retained within uropods and cell bodies. Furthermore, CD44 and CD43 interact concomitantly with DRMs and with the F-actin cytoskeleton, suggesting a mechanism for the formation and stabilization of DRMs. By tracking the distribution of DRMs during polarization, we demonstrate that DRMs progress from a uniform distribution in unstimulated cells to small, discrete patches immediately after activation. Within 1 min, DRMs form a large cap comprising the cell body and uropod. This process is dependent on myosin in that an inhibitor of myosin light chain kinase can arrest DRM reorganization and cell polarization. Colabeling DRMs and F-actin revealed a correlation between DRM distribution and F-actin remodeling, suggesting that plasma membrane organization may orient signaling events that control cytoskeletal rearrangements and, consequently, cell polarity.

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Brefeldin A rapidly disrupts plasma membrane polarity by blocking polar sorting in common endosomes of MDCK cells

Journal of Cell Science ◽

10.1242/jcs.114.18.3309 ◽

2001 ◽

Vol 114 (18) ◽

pp. 3309-3321 ◽

Cited By ~ 1

Author(s):

Exing Wang ◽

Janice G. Pennington ◽

James R. Goldenring ◽

Walter Hunziker ◽

Kenneth W. Dunn

Keyword(s):

Plasma Membrane ◽

Mdck Cells ◽

Basolateral Membrane ◽

Brefeldin A ◽

Apical Plasma Membrane ◽

Transferrin Receptors ◽

Recycling Endosome ◽

Polarized Cells ◽

Endocytic Sorting ◽

On Line

Recent studies showing thorough intermixing of apical and basolateral endosomes have demonstrated that endocytic sorting is critical to maintaining the plasma membrane polarity of epithelial cells. Our studies of living, polarized cells show that disrupting endocytosis with brefeldin-A rapidly destroys the polarity of transferrin receptors in MDCK cells while having no effect on tight junctions. Brefeldin-A treatment induces tubulation of endosomes, but the sequential compartments and transport steps of the transcytotic pathway remain intact. Transferrin is sorted from LDL, but is then missorted from common endosomes to the apical recycling endosome, as identified by its nearly neutral pH, and association with GFP chimeras of Rabs 11a and 25. From the apical recycling endosome, transferrin is then directed to the apical plasma membrane. These data are consistent with a model in which polarized sorting of basolateral membrane proteins occurs via a brefeldin-A-sensitive process of segregation into basolateral recycling vesicles. Although disruption of polar sorting correlates with dissociation of γ-adaptin from endosomes, γ-adaptin does not appear to be specifically involved in sorting into recycling vesicles, as we find it associated with the transcytotic pathway, and particularly to the post-sorting transcytotic apical recycling endosome. Movies available on-line

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Steps in the morphogenesis of a polarized epithelium. II. Disassembly and assembly of plasma membrane domains during reversal of epithelial cell polarity in multicellular epithelial (MDCK) cysts

Journal of Cell Science ◽

10.1242/jcs.95.1.153 ◽

1990 ◽

Vol 95 (1) ◽

pp. 153-165

Author(s):

A.Z. Wang ◽

G.K. Ojakian ◽

W.J. Nelson

Keyword(s):

Plasma Membrane ◽

Suspension Culture ◽

Cell Polarity ◽

Collagen Gel ◽

Preceding Paper ◽

Fundamental Aspect ◽

Membrane Domains ◽

Polarized Cells ◽

Plasma Membrane Domains ◽

Polarized Epithelium

A fundamental aspect in the morphogenesis of a polarized epithelium is the formation of structurally and functionally distinct apical and basal-lateral domains of the plasma membrane. The formation of these membrane domains involves the accumulation of domain-specific proteins and removal of incorrectly localized proteins. The mechanisms involved in these processes are not well understood. We have approached this problem by detailed analysis of the distribution and fate of proteins specific for different membrane domains during reversal of epithelial polarity. In the preceding paper we showed that MDCK cells form multicellular cysts comprising a closed monolayer of polarized cells. The orientation of cell polarity depends upon whether cysts are formed in suspension culture or in a collagen gel. Here, we show that, when fully developed cysts formed in suspension culture are placed in a collagen gel, polarity is rapidly reversed without cell dissociation. We show that during the process of polarity reversal, plasma membrane domains are disassembled by uptake of proteins into cytoplasmic vesicles, followed by protein degradation that probably occurs in lysosomes. The disassembly and assembly of the apical and the basal-lateral membrane domains occur in a sequential order with different kinetics. Our results provide further insights into the establishment of protein specificity of plasma membrane domains in polarized cells.

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Impact of Hybrid and Complex N-Glycans on Cell Surface Targeting of the Endogenous Chloride CotransporterSlc12a2

International Journal of Cell Biology ◽

10.1155/2015/505294 ◽

2015 ◽

Vol 2015 ◽

pp. 1-20 ◽

Cited By ~ 5

Author(s):

Richa Singh ◽

Mohammed Mashari Almutairi ◽

Romario Pacheco-Andrade ◽

Mohamed Y. Mahmoud Almiahuob ◽

Mauricio Di Fulvio

Keyword(s):

Plasma Membrane ◽

Cell Surface ◽

Basolateral Membrane ◽

Transport Function ◽

Ion Regulation ◽

Hybrid Type ◽

Membrane Complex ◽

Polarized Cells ◽

Intracellular Compartments ◽

High Mannose

The Na+K+2Cl−cotransporter-1 (Slc12a2, NKCC1) is widely distributed and involved in cell volume/ion regulation. Functional NKCC1 locates in the plasma membrane of all cells studied, particularly in the basolateral membrane of most polarized cells. Although the mechanisms involved in plasma membrane sorting of NKCC1 are poorly understood, it is assumed that N-glycosylation is necessary. Here, we characterize expression, N-glycosylation, and distribution of NKCC1 in COS7 cells. We show that ~25% of NKCC1 is complex N-glycosylated whereas the rest of it corresponds to core/high-mannose and hybrid-type N-glycosylated forms. Further, ~10% of NKCC1 reaches the plasma membrane, mostly as core/high-mannose type, whereas ~90% of NKCC1 is distributed in defined intracellular compartments. In addition, inhibition of the first step of N-glycan biosynthesis with tunicamycin decreases total and plasma membrane located NKCC1 resulting in almost undetectable cotransport function. Moreover, inhibition of N-glycan maturation with swainsonine or kifunensine increased core/hybrid-type NKCC1 expression but eliminated plasma membrane complex N-glycosylated NKCC1 and transport function. Together, these results suggest that (i) NKCC1 is delivered to the plasma membrane of COS7 cells independently of its N-glycan nature, (ii) most of NKCC1 in the plasma membrane is core/hybrid-type N-glycosylated, and (iii) the minimal proportion of complex N-glycosylated NKCC1 is functionally active.

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