The Tetraspan Molecule CD151, a Novel Constituent of Hemidesmosomes, A(基础医学)

The Tetraspan Molecule CD151, a Novel Constituent of Hemidesmosomes, A

http://www.100md.com 《细胞学杂志》

     a Division of Cell Biology, The Netherlands Cancer Institute, Plesmanlaan 121, 1066 CX Amsterdam, The Netherlands

    b Division of Biophysics, The Netherlands Cancer Institute, Plesmanlaan 121, 1066 CX Amsterdam, The Netherlands

    Correspondence to: Arnoud Sonnenberg, The Netherlands Cancer Institute, Division of Cell Biology, Plesmanlaan 121, 1066 CX Amsterdam, The Netherlands. Tel:(31) 20-5121942 Fax:(31) 20-5121944 E-mail:asonn@nki.nl.

    Abstract

    CD151 is a cell surface protein that belongs to the tetraspan superfamily. It associates with other tetraspan molecules and certain integrins to form large complexes at the cell surface. CD151 is expressed by a variety of epithelia and mesenchymal cells. We demonstrate here that in human skin CD151 is codistributed with 3?1 and 6?4 at the basolateral surface of basal keratinocytes. Immunoelectron microscopy showed that CD151 is concentrated in hemidesmosomes. By immunoprecipitation from transfected K562 cells, we established that CD151 associates with 3?1 and 6?4. In ?4-deficient pyloric atresia associated with junctional epidermolysis bullosa (PA-JEB) keratinocytes, CD151 and 3?1 are clustered together at the basal cell surface in association with patches of laminin-5. Focal adhesions are present at the periphery of these clusters, connected with actin filaments, and they contain both CD151 and 3?1. Transient transfection studies of PA-JEB cells with ?4 revealed that the integrin 6?4 becomes incorporated into the 3?1-CD151 clusters where it induces the formation of hemidesmosomes. As a result, the amount of 3?1 in the clusters diminishes and the protein becomes restricted to the peripheral focal adhesions. Furthermore, CD151 becomes predominantly associated with 6?4 in hemidesmosomes, whereas its codistribution with 3?1 in focal adhesions becomes partial. The localization of 6?4 in the pre-hemidesmosomal clusters is accompanied by a strong upregulation of CD151, which is at least partly due to increased cell surface expression. Using ?4 chimeras containing the extracellular and transmembrane domain of the IL-2 receptor and the cytoplasmic domain of ?4, we found that for recruitment of CD151 into hemidesmosomes, the ?4 subunit must be associated with 6, confirming that integrins associate with tetraspans via their subunits. CD151 is the only tetraspan identified in hemidesmosomal structures. Others, such as CD9 and CD81, remain diffusely distributed at the cell surface.

    In conclusion, we show that CD151 is a major component of (pre)-hemidesmosomal structures and that its recruitment into hemidesmosomes is regulated by the integrin 6?4. We suggest that CD151 plays a role in the formation and stability of hemidesmosomes by providing a framework for the spatial organization of the different hemidesmosomal components.

    Key Words: integrin 64, tetraspan CD151, hemidesmosome, focal adhesion, cross-talk

    Introduction

    CD151 has recently been characterized as a member of the tetraspan superfamily. This growing family comprises >20 highly conserved molecules, which intersect the plasma membrane four times (Wright and Tomlinson 1994 ; Maecker et al. 1997 ; Hemler 1998 ). Like other tetraspan molecules, CD151 contains one small and one large extracellular loop with short cytoplasmic carboxy- and amino-terminal domains. The large extracellular loop is thought to be involved in the binding to other molecules, such as integrins. Tetraspans probably bind to the subunit of the heterodimeric integrins (Imai et al., 1995; Mannion et al. 1996 ; Lagaudriere-Gesbert et al. 1997 ; Yauch et al. 1998 ).

    CD151 has been implicated in a wide variety of cell biological processes, including cell adhesion (Hasegawa et al. 1998 ; Fitter et al. 1999 ), cell motility (Yanez-Mo et al. 1998 ; Yauch et al. 1998 ; Sincock et al. 1999 ; Sugiura and Berditchevski 1999 ; Berditchevski and Odintsova 1999 ), and the transport of integrins via vesicles (Sincock et al. 1999 ). Furthermore, because of an association with phosphatidylinositol-4-kinase, a role of CD151 in signal transduction and a link to the cytoskeleton has been suggested (Berditchevski et al. 1997 ; Yauch et al. 1998 ; Sugiura and Berditchevski 1999 ; Berditchevski and Odintsova 1999 ).

    CD151 is expressed by a variety of epithelial and mesenchymal cells, including hematopoietic cells and myocytes. In the skin, it is expressed in the basal keratinocytes (Sincock et al. 1997 ). In addition to CD151 these keratinocytes express the tetraspans CD9, CD63, CD81, and CD82, and the integrins 2?1, 3?1, and 6?4 (Watt and Hertle 1994 ; Okochi et al. 1997 ). Both 3?1 and 6?4 are laminin-binding integrins, with a preference for laminin-5, the primary adhesive ligand present in the normal basal lamina of the adult skin (Carter et al. 1991 ; Rouselle et al. 1991 ).

    Hemidesmosomes are specialized junctional complexes that function as cell attachment sites for binding to basement membranes, by linking intermediate filaments to the extracellular matrix (Jones et al. 1998 ; Borradori and Sonnenberg 1999 ). The integrin 6?4 is a major component of hemidesmosomes and it plays an essential role in their formation. In fact, patients who suffer from junctional epidermolysis bullosa associated with pyloric atresia (PA-JEB)1, due to mutations in the gene for 6 or ?4, have rudimentary hemidesmosomes (Vidal et al. 1995 ; Ruzzi et al. 1997 ), while in 6- and ?4-null mutant mice, these complexes are not formed at all (Dowling et al. 1996 ; Georges-Labouesse et al. 1996 ; van der Neut et al. 1996 ). Based on the hemidesmosomal components present, two subtypes of hemidesmosomes are distinguished: type II hemidesmosomes consist of 6?4 and plectin (Uematsu et al. 1994 ), while type I additionally contain BP180 and BP230 (bullous pemphigoid antigen 180 and 230, respectively). Type II hemidesmosomes are found in cylindrical epithelia, e.g., those lining the digestive tract (Fontao et al. 1997 ). Type I is the classical hemidesmosome, present in basal keratinocytes of multilayered squamous epithelium or urothelium (Borradori and Sonnenberg 1999 ; Nievers et al. 1999 ). Hemidesmosomes are defined at the ultrastructural level as electron dense structures, resembling half a desmosome. In certain epithelial cell cultures stained with antibodies against hemidesmosomal components, the typical Swiss cheese– or cauliflower-like pattern represents an equivalent structure (Riddelle et al. 1991 ). Focal adhesions are sites at the plasma membrane where integrins are clustered and associated with the actin cytoskeleton (Jockusch et al. 1995 ; Burridge et al. 1997 ). At these sites various cytoskeleton-associated and signaling molecules are also concentrated. Since plectin is found in both focal adhesions and hemidesmosomes, a functional link between these structures has been suggested (Sanchez-Aparicio et al. 1997 ; Nievers et al. 1998 ; Geerts et al. 1999 ). Contradictory results have been reported about the presence of tetraspans and particularly CD151 in focal adhesions (Nakamura et al. 1995 ; Berditchevski et al. 1997 ; Indig et al. 1997 ; Berditchevski and Odintsova 1999 ).

    In this study, we focus on the role of CD151 in hemidesmosome formation and the cross talk between focal adhesions and hemidesmosomes. We show that CD151 is an as yet unrecognized novel component of hemidesmosomes. In ?4-deficient keratinocyte cultures, CD151 is colocalized with 3?1 in pre-hemidesmosomal structures together with laminin-5. Upon transfection with ?4, the surface expression of CD151 is enhanced and the protein becomes recruited into hemidesmosomes. This process only occurs when the 6 subunit is associated with ?4, indicating that CD151 is probably bound to this subunit. These results provide new information on the function of CD151, the interaction of tetraspans with integrins in general and the process of hemidesmosome assembly.

    Materials and Methods

    Cell Lines

    The human erythroleukemic cell line K562 was maintained in RPMI-1640 supplemented with 10% heat-inactivated fetal calf serum (GIBCO BRL), 100 U/ml penicillin and 100 U/ml streptomycin. K562 cells stably expressing 3?1 and 6?4 were established as described previously (Delwel et al. 1993 ; Niessen et al. 1994 ). Immortalized keratinocytes derived from a PA-JEB patient were isolated as published elsewhere (Schaapveld et al. 1998 ). Keratinocytes were grown in keratinocyte serum-free medium (SFM; GIBCO BRL), supplemented with 50 μg/ml bovine pituitary extract, 5 ng/ml epidermal growth factor, 100 U/ml penicillin, and 100 μg/ml streptomycin. All cells were grown at 37°C in a humidified, 5% CO2 atmosphere.

    Antibodies

    Mouse mAbs J8H against the extracellular domain of the human 6 integrin subunit and 29A3 against the cytoplasmic domain of the human 3A subunit have been described previously (Hogervorst et al. 1993 ; de Melker et al. 1997 ). The mouse mAb J143, recognizing an extracellular epitope on the human 3 integrin subunit (Kantor et al. 1987 ), was from the American Type Culture Collection. Rat mAb B1E5 against the human 5 extracellular domain (Hall et al. 1990 ) was a kind gift from Dr. C.H. Damsky (University of California San Francisco, San Francisco, CA) and the mouse mAbs 4.3E1 (Hessle et al. 1984 ) and 450-11A (Kennel et al. 1990 ) against the extracellular and cytoplasmic domains of human ?4 were donated by Drs. E. Engvall (The Burnham Institute, La Jolla, CA) and S.J. Kennel (Oak Ridge National Laboratory, Oak Ridge, TN). Rabbit sera against the cytoplasmic domains of the human 6A and ?4 integrin subunits were prepared as described (Delwel et al. 1993 ; Niessen et al. 1994 ). The anti-6 polyclonal antibody, A33, was raised in rabbits by immunizing with a GST-fused recombinant protein of the extracellular domain of 6 (amino acids 1–576). The rabbit polyclonal antibodies against the cytoplasmic domains of 3A (DiPersio et al. 1995 ), 5 (Defilippi et al. 1991 ) and ?1A were gifts from Drs. M. DiPersio (Albany Medical College, Albany, NY), G. Tarone (Università di Torino, Italy) and U. Mayer (Max-Planck-Institut für Biochemie, Martinsried, Germany), respectively.

    The mouse mAbs 121 and 815 directed against plectin (Okumura et al. 1999 ) and BP230 (Nishizawa et al. 1993 ) were generously provided by Dr. K. Owaribe (Nagoya University, Nagoya, Japan) and the rabbit sera against vinculin (Geiger 1979 ) and the carboxy-terminal domain of BP230 (Tanaka et al. 1990 ) were gifts form Drs. B. Geiger (The Weizmann Institute of Science, Rehovat, Israel) and J.R. Stanley (University of Pennsylvania, Philadelphia, PA). The anti-vinculin mAb VII-F9 was purchased from Sigma. Drs. P. Rouselle (Institut de Biologie et Chimie des Protéines, Lyon, France) and R.E. Burgeson (Harvard Medical School, Boston, MA) kindly provided the polyclonal laminin-5 antibody (Marinkovich et al. 1992 ) and the mAb BM165 against the 3 chain of laminin-5 (Rouselle et al. 1991 ).

    The mouse mAb P48, also known as 11B1.G4, was clustered as CD151 in the VI International Leukocyte Typing Workshop (Ashman et al. 1997 ; Sincock et al. 1997 ). The mouse mAb 8C3 (CD151) was kindly provided by Dr. K. Sekiguchi (Osaka University, Osaka, Japan) and the mouse mAb Sfa-1 (CD151, Hasegawa et al. 1996 ) by Dr. H. Hasegawa (Ehime University, Ehime, Japan). The mouse mAbs MEM62 (CD9, Horejsi and Vlcek 1991 ), MEM53 (CD53; Angelisova et al. 1994 ), M38 (CD81, Imai and Yoshie 1993 ) and C33 (CD82, Imai and Yoshie 1993 ), were generously provided with by Dr. V. Hoejí (Institute of Molecular Genetics, Prague, Czech Republic). Dr. F. Berditchevski (The University of Birmingham UK) kindly supplied the mouse mAb 6H1 (CD63, Berditchevski et al. 1995 ). Actin was stained by phalloidin labeled with TRITC (Sigma). The sheep anti–mouse and donkey anti–rabbit horseradish peroxidase–coupled secondary antibodies, and Texas red–conjugated donkey anti–rabbit antibody were purchased from Amersham Pharmacia Biotech. FITC-conjugated goat anti–mouse was obtained from Rockland.

    Analysis of Integrin and Tetraspan Surface Expression

    The surface expression of integrin subunits and tetraspan molecules on PA-JEB and ?4-transduced PA-JEB/?4 cells was assessed by flow cytometry. 5 x 105 cells were preincubated for 30 min with PBS containing 2% BSA, followed by incubation with the primary antibody for 1 h. The cells were washed three times and then incubated with goat anti–mouse IgG coupled to FITC fluorescein for another hour. After a further three washes, cells were resuspended and analyzed with a FACScan? flow cytometer (Becton Dickinson).

    Transient Transfection

    The cDNAs encoding full-length ?4A and IL2R/?4, which consists of the extracellular and transmembrane domain of the IL-2 receptor and the cytoplasmic domain of the integrin ?4 subunit, were subcloned into the pRc/CMV expression vector (Niessen et al. 1997 ; Nievers et al. 1998 ). PA-JEB keratinocytes were seeded onto coverslips 1–2 d before use. Cells were transfected using a cationic lipid-based DNA delivery protocol, Lipofectin Reagent? from Life Technologies. After a 16-h incubation period, the lipofectin reagent was replaced with keratinocyte-SFM medium for 12 h and then subsequently replaced with HAMF12/DMEM 1:3 for an additional 24 h, after which gene expression was assessed.

    Stable Cellular Transduction

    The full-length ?4A cDNA was released from pUC18-?4A (Niessen et al. 1997 ) by digesting with EcoRI and the resulting fragment was ligated into the retroviral LZRS-IRES-zeo expression vector, a modified LZRS retroviral vector conferring resistance to zeocin (Kinsella and Nolan 1996 ; van Leeuwen et al. 1997 ) to give the LZRS-IRES-zeo-?4A vector. This construct was then introduced into the Phoenix packaging cells (Kinsella and Nolan 1996 ) by the calcium phosphate precipitation method and virus containing supernatant was collected. PA-JEB cells were infected with the recombinant virus by the DOTAP method (Boehringer). After incubation for 6–8 h at 37°C, infected cells were selected with 0.2 mg/ml zeocin (Invitrogen). Cells expressing 6?4 at their surface were isolated by FACS?, expanded, and analyzed.

    Immunofluorescence

    Cells were seeded onto glass coverslips, cultured overnight, and then fixed with 1% (wt/vol) paraformaldehyde in PBS for 5 min at room temperature. Subsequently, cells were permeabilized in 0.3% (vol/vol) Triton X-100 in PBS for 5 min at room temperature and blocked for 30 min in 2% (wt/vol) BSA in PBS. Coverslips were inverted onto parafilm containing 25-μl drops of primary antibodies, diluted in PBS containing 2% BSA, and incubated for 60 min at room temperature. After washing twice with PBS, the coverslips were incubated a further 45 min at room temperature in the presence of goat anti–mouse-FITC or donkey anti–rabbit Texas red, diluted 1:100 and 1:400, respectively. To localize F-actin filaments, cells were incubated with TRITC-labeled phalloidin for 45 min. After washing twice with PBS, coverslips were mounted onto slides using Vectashield (Vector Laboratories Inc.) and viewed under a Leica TCS NT confocal laser-scanning microscope, equipped with an Ar/Kr laser (Leica).

    Immunoprecipitation and Western Blotting

    Wild-type and transfected K562 cells, stably expressing 3?1 or 6?4, were lysed in 1% (wt/vol) CHAPS (Sigma) buffer (5 mM MgCl2, 150 mM NaCl, and 25 mM Hepes, pH 7.5) containing proteinase inhibitors (1 mM phenylmethylsulfonylfluoride, 10 μg/ml soybean trypsin inhibitor, and 10 μg/ml leupeptin). Alternatively, cells were lysed in 1% (vol/vol) NP-40 (Fluka) buffer (50 mM Tris-HCl, 150 mM NaCl, and 1 mM EDTA). Lysates were incubated for 1 h at 4°C with Gamma Bind-G Sepharose beads (Amersham Pharmacia Biotech), previously incubated overnight at 4°C with the precipitating antibodies. The beads carrying the immune complexes were washed three times with lysis buffer and twice with PBS. The immune complexes were eluted by addition of sample buffer, heated at 95 or 65°C, and separated by SDS-PAGE on 6 or 12% gels under reducing (2% ?-mercaptoethanol) or nonreducing conditions. After electrophoresis, gels were electrophoretically transferred to a PVDF membrane (Immobilon-P; Bedford). The blots were stained with Coomassie blue to indicate the markers, destained (45% methanol and 5% acidic acid in demineralized water), and blocked for 30 min at 37°C with 2% dry milk in TBST-buffer (10 mM Tris, pH 7.5, 150 mM NaCl, and 0.3% Tween-20). Subsequently, blots were incubated with primary antibodies in 0.2% dry milk in TBST for 90 min at room temperature. Primary antibodies were mAb 450-11A (1:500 dilution), 8C3 (1:5,000), pAb A33 (1:500), 29A3 (neat supernatant), and B1E5 (neat supernatant). After three washes with TBST with 0.2% dry milk, blots were incubated an additional hour at room temperature with horseradish peroxidase–conjugated sheep anti–mouse IgG or donkey anti–rabbit IgG, diluted 1:5,000 in 0.2% dry milk in TBST. The blots were again washed three times with TBST and the bound antibodies were detected by enhanced chemiluminescence as described by the manufacturer (ECL; Amersham Pharmacia Biotech).

    Immunoelectron Microscopy

    Biopsies of human skin were fixed with 1% paraformaldehyde in 0.1 M phosphate buffer (pH 7.2) for 2 h and then processed for ultrathin cryosectioning as previously described (Calafat et al. 1997 ). 45-nm cryosections were cut at -125°C using diamond knives (Drukker Cuijk) in an Utracryomicrotome (Leica) and transferred with a mixture of sucrose and methyl cellulose onto formvar-coated copper grids (Liou et al. 1996 ). The grids were placed on 35-mm petri dishes containing 2% gelatin. For immunolabeling, the sections were incubated with mAb P48 (dilution 1:100) for 45 min, followed by a 45-min incubation with rabbit anti–mouse IgG (dilution 1:10) and the incubated with 10-nm colloidal gold–labeled protein-A for 30 min. After washing, the cryosections were embedded in a mixture of methyl cellulose and uranyl acetate and examined with a Philips CM 10 electron microscope. For controls, the primary antibody was replaced by a nonrelevant mouse mAb.

    Results

    Identification of CD151 as a Novel Constituent of Hemidesmosomes

    Immunohistochemical staining of frozen sections of the skin revealed that the laminin-binding integrins 6?4 (Fig 1A and Fig B) and 3?1 (Fig 1 C) are present at the basal and basolateral surfaces of the basal keratinocytes, respectively. In addition, the 3?1 integrin is present in some suprabasal cells. The combined staining patterns of 3?1 and 6?4 are very similar to that of CD151 (Fig 1 D). We next determined the exact distribution of CD151 in basal keratinocytes by immunoelectron microscopy. The results show that CD151 is concentrated in electron-dense hemidesmosomes (Fig 2B and Fig C). The protein was also detected along the lateral membranes, but not in desmosomes (Fig 2 A). The ultrastructural location of CD151 is consistent with the results of the immunoperoxidase staining and suggests that CD151 is codistributed with 6?4 in hemidesmosomes. An association between CD151 and 3?1 is suggested by their similar patterns of staining in other parts of the cell.

    Figure 1. Codistribution of laminin-binding integrins and CD151 in the skin. Frozen sections of human skin are stained by immunoperoxidase reaction with (A) anti-6 (J8H), (B) anti-?4 (4.3E1), (C) anti-3 (J143), and (D) CD151 (P48). Anti-6 and ?4 produce strong staining of the basal region of basal keratinocytes, while anti-3 reacts with basal and lateral surfaces of the basal cells and some suprabasal cells. The distribution of CD151 overlaps with that of both 3?1 and 6?4. Bar, 100 μm.

    Figure 2. Localization of CD151 in hemidesmosomes. Ultrathin sections of human skin were labeled with P48 (CD151), followed by incubation with second antibodies and gold-conjugated protein A. In A an area of the basal epidermal cell layer is shown where two opposed cells meet. The lateral membranes of these cells show clear staining for CD151. Desmosomes were not stained. In B and C it is shown that CD151 is preferentially localized in hemidesmosomes (curved arrows). IF, intermediate filaments; DM, desmosome; BM, basement membrane; c, collagen. Bars, 200 nm.

    Coprecipitation of CD151 with 3?1 and 6?4

    Initial attempts using keratinocytes to show that CD151 forms a complex with 6?4 all failed because 6?4, when present in hemidesmosomes, could not be extracted with a buffer containing 1% CHAPS. We therefore used K562 cells instead, which stably express the integrin 6?4, but do not contain hemidesmosomes. Control K562 cells, which only express 5?1, and K562 cells transfected with 3 were also included in the analyses. Cells were lysed in 1% CHAPS and integrins were immunoprecipitated with integrin subunit-specific antibodies. The presence of CD151 in the precipitates was assessed by immunoblotting with specific antibodies (Fig 3). Protein bands corresponding to CD151 could be detected in the immunoprecipitates containing 3?1 and 6?4, but not in those that contain 5?1. When cells were lysed in 1% NP-40, CD151 was only detected in the immunoprecipitates containing 3?1 (not shown).

    Figure 3. CD151 is associated with 3?1 and 6?4 in transfected K562 cells. Lysates of wild-type (wt) K562 and of 3A- and 6?4-transfected K562 cells, stably expressing 3?1 or 6?4, respectively, were immunoprecipitated with anti-integrin antibodies. Immunoprecipitates were analyzed by Western blotting using anti-integrin subunit antibodies to monitor the amount of integrins immunoprecipitated (upper half, reduced gel) and using CD151 to detect possible association with integrin subunits (lower half, nonreduced gel). Antibodies used for immunoprecipitation were polyclonal antibodies against 3 and 5, and the mAbs J8H and 4.3E1 against 6 and ?4, respectively. For the detection of integrin subunits on blots, polyclonal antibodies against 6 (A33) and the mAbs 29A3, B1E5, and 450-11A and 8C3 against 3, 5, ?4, and CD151 were used. The anti-5 (B1E5) and 6 (A33) subunit antibodies are directed against extracellular domains and proteins bands stained with these antibodies correspond to the unprocessed and heavy chains of the corresponding subunits. The antibody 29A3 is directed against the cytoplasmic domain of the 3A subunit and on blot it reacts with the light chain of 3 (L) and the unprocessed 3 precursor (). CD151 is coprecipitated with anti-3 from K562 cells expressing 3?1 and with anti-6 and anti-?4 from K562 cells expressing 6?4. No coprecipitation is seen with anti-5 from K562 cells.

    Localization of CD151 in Pre-Hemidesmosomal and Hemidesmosomal Structures in Cultured Keratinocytes

    Cultured keratinocytes were used to further investigate the localization of CD151 and its possible role in hemidesmosome formation. Previously, we have shown that in PA-JEB keratinocytes, which lack ?4, no hemidesmosomes are formed (Schaapveld et al. 1998 ). However, hemidesmosome formation is induced by transfection with ?4, a process that can occur in both a ligand-dependent and -independent manner, the latter requiring the ?4 cytoplasmic domain and the presence of plectin (Schaapveld et al. 1998 ; Nievers et al. 2000 ).

    Staining of untransfected PA-JEB cells showed complete colocalization of CD151 and 3?1 in clusters at the basal surface of the cell (Fig 4, A–C). The ligand for 3?1, laminin-5, was concentrated beneath these basal clusters (Fig 4, D–F). Only CD151 is colocalized with 3. The other tetraspans CD9 and CD81 are diffusely distributed over the plasma membrane, while the distribution pattern of CD63 is granular in the cytoplasm (data not shown). The laminin-5 patches, which were left in the tracks of migrated cells, do not contain 3?1 or 6?4.

    Figure 4. Colocalization of 3?1 and 6?4 with CD151 on patches of laminin-5. PA-JEB (A–F) and 6?4-expressing PA-JEB/?4 cells (G–L) were processed for double immunofluorescence confocal microscopy using mAb CD151 (A and G) or mAb BM165 against laminin-5 (D and J), together with polyclonal antibodies against 3 (B and E) or ?4 (H and K). Composite images (C, F, I, and L) were generated by superimposition of the green and red signals, with areas of overlap appearing as yellow. The distribution patterns of 3?1 and CD151 in PA-JEB cells and of 6?4 and CD151 in PA-JEB/?4 cells completely overlap. The integrins 3?1 and 6?4, both receptors for laminin-5, are associated with patches of laminin-5 that are deposited by the cells at sites of cell-substrate contact. Cells that had migrated have left patches of laminin-5 that do not contain 3 or ?4. Bar, 10 μm.

    In PA-JEB/?4 cells, 6?4 was found to be concentrated in hemidesmosome-like structures at sites of cell–substrate contact. These hemidesmosomal structures appear to be much larger than the clusters formed by 3?1 in the untransfected PA-JEB cells, but, like the 3?1 clusters, they contain CD151 and are associated with laminin-5 (Fig 4, G–L).

    In transient transfection experiments, which enabled us to visualize expression of the different components in transfected and untransfected cells in a single confocal high power field, it could be demonstrated that 6?4 becomes localized at sites, where the 3?1-CD151 clusters are present (Fig 5). Thus, the formation of these clusters seems to precede the formation of mature hemidesmosomes, which requires expression of 6?4. Therefore, we refer to the 3?1-CD151 clusters as pre-hemidesmosomal structures. It is also shown that the amount of CD151 in the clusters increased after expression of ?4 (Fig 5, A–C and D–F). In contrast, that of 3 seems to become reduced, compared with that in pre-hemidesmosomal structures in untransfected cells (Fig 5, G–I, see also Fig 8). The increased reaction with anti-CD151 was not due to cross-reactivity of the antibody with epitopes unrelated to CD151, since two other antibodies against CD151, 8C3 and Sfa-1, gave similar results. Tetraspans, other than CD151, are absent from hemidesmosomes, as shown for CD81 (Fig 5, J–L).

    Figure 5. Expression of 6?4 induces recruitment of CD151 into hemidesmosomal structures. PA-JEB cells were transiently transfected with ?4, fixed, and double-labeled with mAbs CD151 (A, D, and G) or CD81 (J) and polyclonal antibodies against 6 (B), ?4 (E and K), or 3 (H). Merged images are shown in the right panels (C, F, I, and L). Sections are focused at the cell–substrate interface. Upon transfection, expression of ?4 results in the formation of hemidesmosome-like structures in which 6?4 is concentrated and codistributed with CD151. These hemidesmosomal structures are formed at sites where complexes of 3?1 and CD151 are also present. Some of the hemidesmosomal structures lack 3?1, while in others the amount of 3?1 is reduced; they may represent intermediate steps in the maturation of hemidesmosomes. Mature hemidesmosomes do not contain 3?1 (see also Fig 8). Bar, 10 μm.

    Figure 6. Expression of 6?4 results in an increase in the surface levels of CD151. Flow cytometry was used to analyze the surface expression of ?4 (4.3E1) and different tetraspan molecules CD9 (MEM62), CD53 (MEM53), CD63 (6H1), CD81 (M38), and CD151 (P48) on PA-JEB (dotted lines) and PA-JEB/?4 cells (interrupted lines). Negative control (solid lines) staining with secondary FITC-conjugated anti–mouse IgG is shown for comparison. The expression of ?4 on the surface of PA-JEB cells (PA-JEB/?4) was selectively accompanied by an increase in the surface levels of CD151; the levels of CD9 and CD81 remain unaltered. Both PA-JEB and PA-JEB/?4 cells are negative for CD53 and CD63.

    Figure 7. CD151 is localized in type I and II hemidesmosomes. 6?4-expressing PA-JEB/?4 cells were fixed and double-labeled with mAb 4.3E1 against ?4 (A), mAb 815 against BP230 (B), mAb 121 against plectin (C) or mAb CD151 (F), and polyclonal antibodies against 3 (A, B, C and F). Cells were also double-labeled with mAb CD151 (D, E) and polyclonal antibodies against ?4 (D) or BP230 (E). Only dual-labeled images are shown. In cells that express both type I and II hemidesmosomes, the areas containing CD151 are larger than that containing BP230 (E), whereas those containing CD151 and ?4 are identical (D). Focal adhesions that surround the hemidesmosomal structures contain 3?1 (A–C). CD151 is partially codistributed with 3?1 (F). Bar, 5 μm.

    Figure 8. CD151 is not recruited by IL-2R/?4. PA-JEB cells were transiently transfected with IL-2R/?4 chimera, fixed, and double-labeled with mAbs 4.3E1 against ?4 (B), CD151 (D), or CD9 (G) and polyclonal antibodies against 3 (A) or ?4 (E and H). Merged images are shown in the right panels (C, F, and I). Expression of the IL2R/?4 chimera induces the formation of hemidesmosomal structures, but not the recruitment of CD151 into these structures. The IL2R/?4 also fails to recruit CD9 which is diffusely distributed over the plasma membrane. Bars, 10 μm.

    Recently, Yauch et al. 1998 have shown that CD151 expression is upregulated after transfection of K562 cells with 3. Similarly, we observed that CD151 surface expression increased by 35% when PA-JEB keratinocytes are transfected with ?4 (Fig 6). Thus, the clustering of CD151 in hemidesmosomes may result from the recruitment of intracellular pools of CD151, although additional redistribution of surface CD151 is not excluded.

    Localization of CD151 in Type I and Type II Hemidesmosomes

    Based on their components, hemidesmosomes can be divided into two types, type I and II hemidesmosomes. Type II hemidesmosomes, which contain 6?4 and plectin, are considered to be precursors of the classical type I hemidesmosomes, which in addition contain BP180 and BP230 (Nievers et al. 1999 ). We investigated whether CD151 is expressed in both types. In PA-JEB/?4 cells that stably express the integrin 6?4, type II hemidesmosomes are more abundant than type I hemidesmosomes and in some cells only type II hemidesmosomes are present. As shown in Fig 7 D, in PA-JEB/?4 cells, the staining pattern of hemidesmosomes for CD151 and 6?4 is very similar. This is also true in those cells that only contain type II hemidesmosomes. Similar results were obtained when we compared the distribution of CD151 with that of plectin (not shown). In contrast, CD151 is more widely distributed than BP230 (Fig 7 E). Together, these data show that CD151 is a component of both types of hemidesmosomes. The 3 subunit is expressed at the periphery of the hemidesmosomes and is not colocalized with 6?4, BP230, or plectin (Fig 7, A–C). Importantly, while in untransfected PA-JEB cells, the expression pattern of 3 completely overlaps with that of CD151 (Fig 4), in PA-JEB/?4 cells that stably express the integrin 6?4, the integrin 3?1 and CD151 are only partially colocalized in the vicinity of hemidesmosomes (Fig 7 F, see also A) and in some cells are not colocalized at all. This suggests that when ?4 is expressed in the hemidesmosomal structures the 3?1-CD151 complexes are replaced by 6?4-CD151.

    The ?4 Cytoplasmic Domain Does Not Support the Recruitment of CD151 into Hemidesmosomes

    The integrin and ? subunits associate noncovalently via their extracellular domains. Using an IL-2R/?4 chimera, which consists of the extracellular and transmembrane domains of the IL-2 receptor and the ?4 integrin cytoplasmic domain, we have shown that dimerization of ?4 with 6 is not required for hemidesmosome formation (Nievers et al. 1998 ). Because the extracellular domain of the IL-2 receptor is unable to bind laminin-5, the process is entirely driven by the cytoplasmic domain of ?4.

    It is generally assumed that integrins are associated with tetraspans by their subunit. To determine whether association of ?4 with the 6 subunit is necessary for the recruitment of CD151 into hemidesmosomes, PA-JEB cells were transfected with the IL-2R/?4 chimera (Fig 8). In transfected cells, colocalization of the IL-2R/?4 construct is seen with laminin-5 (not shown), 3 (Fig 8, A–C), and CD151 (Fig 8, D–F). However, the redistribution of CD151 to the hemidesmosomes, as seen in cells transfected with full-length ?4, did not occur (compare results in Fig 5). This demonstrates that for the recruitment of CD151 into hemidesmosomes, heterodimerization of the ?4 subunit with the 6 subunit is required. Furthermore, these data indicate that CD151 clustering is not essential for the formation of hemidesmosomes.

    Localization of 3?1-CD151 in Focal Adhesions Is Affected by the Expression of 6?4

    Previously, we have shown that hemidesmosomes are surrounded by focal adhesions (Schaapveld et al. 1998 ). Focal adhesions are specialized sites at the plasma membrane where integrins are clustered and connected to the actin cytoskeleton. Fig 9 shows the compartmentalization of, and the close link between hemidesmosomal structures and focal adhesions, as well as the components shared between them. In both untransfected PA-JEB cells and cells transfected with ?4, actin filaments are shown to terminate in focal adhesions containing 3?1 and vinculin (Fig 9C and Fig F). Focal adhesions are also present at the cell periphery, but these lack 3?1 and CD151. As expected, because of the near perfect colocalization of CD151 and 3 in PA-JEB cells (Fig 4), CD151 is a component of the focal adhesions that surround the pre-hemidesmosomal structures. However, in ?4-transfected PA-JEB cells, CD151 was mainly restricted to the hemidesmosomal structures and was only partially colocalized with vinculin in the surrounding focal adhesions. This suggests that when hemidesmosomes are formed upon transfection with ?4, the distribution of CD151 over hemidesmosomes and focal adhesions changes.

    Figure 9. Differential localization of CD151 and vinculin in PA-JEB compared with PA-JEB/?4 cells. Cells were fixed and double-labeled with mAb CD151 and polyclonal antibodies against vinculin (A and D), or with polyclonal antibodies against 3, and a mAb against vinculin (B and E) or to detect F-actin with TRITC-conjugated phalloidin (C and F). Only composite images (A–F), generated by superimposition of the green and red signals are shown. In PA-JEB cells, CD151 is codistributed with 3 in focal adhesions surrounding the pre-hemidesmosomal clusters, whereas in 6?4-expressing PA-JEB/?4 cells, the codistribution with 3 is only partial. In both PA-JEB and PA-JEB/?4 cells, the 3?1 is localized in focal adhesions together with vinculin and F-actin. Note that the focal adhesions at the cell periphery do not contain CD151 and 3. Bars: (A, B, D, and E) 10 μm; (F and C) 10 μm.

    Discussion

    In Vivo and In Vitro Association between CD151 and the Laminin-binding Integrins: CD151 Is Identified as a Component of Hemidesmosomes

    An overlap in the expression patterns of CD151 and 5?1 in human tissues has previously been described (Sincock et al. 1997 ). The integrin 5?1, which is a receptor for fibronectin, is expressed by a variety of cells, such as endothelial and hematopoietic cells. In addition, immunohistochemical data indicated that the expression patterns of CD151 and the laminin-binding integrins 3?1, 6?1, and 7?1 also overlaps (Sincock et al. 1997 ). In this study, we analyzed the expression of CD151 in skin and show that CD151 is coexpressed with 3?1 and 6?4 at the basolateral surface of the basal keratinocytes. Furthermore, immunoprecipitation experiments using transfected K562 cells indicated that CD151 forms complexes with the 3?1 or 6?4 laminin-binding integrins, confirming previous findings (Yauch et al. 1998 ; Serru et al. 1999 ; Sincock et al. 1999 ). However, in contrast to earlier studies (Hasegawa et al. 1998 ; Fitter et al. 1999 ; Sincock et al. 1999 ), we could not confirm coimmunoprecipitation of CD151 with 5?1 from lysates of these cells. Finally, in line with the observation that CD151 is colocalized and associates with 6?4, the presence of CD151 in hemidesmosomes was demonstrated by immunoelectron microscopy.

    CD151 and Sequential Stages in the Formation of Hemidesmosomes

    The integrin 6?4, a receptor for laminin-5, is a major component of hemidesmosomes and crucial for initiating their formation since it forms a scaffold for the binding of the other hemidesmosomal components (Borradori et al. 1997 ; Rezniczek et al. 1998 ; Schaapveld et al. 1998 ; Geerts et al. 1999 ; Hopkinson and Jones 2000 ). The formation of type II hemidesmosomes, containing 6?4 and plectin, precedes the formation of type I hemidesmosomes that additionally contain BP230 and BP180. Type II hemidesmosomes are also considered to be immature hemidesmosomes, present in the early phase of wound healing and in the more dynamic kinds of epithelia. In contrast, type I hemidesmosomes are formed in the stabilizing phase of wound healing and in more stress-resistant epithelia (Uematsu et al. 1994 ; Goldfinger et al. 1999 ).

    By comparing ?4-deficient PA-JEB cells with such cells transfected with ?4, the localization of CD151 could be studied before and after hemidesmosomes were formed. Our data demonstrate that hemidesmosomes are formed in defined, consecutive stages. At first, laminin-5 is deposited, followed by the recruitment of 3?1 and CD151 in what may be called pre-hemidesmosomal structures. At this stage, there is relatively little CD151 present. After ?4 transfection in PA-JEB cells, hemidesmosomes are formed. The integrin 6?4 binds to the deposited laminin-5, and this is followed by the recruitment of plectin (Schaapveld et al. 1998 ). Ultimately, BP180 and BP230 become associated with the 6?4-plectin complexes (Borradori et al. 1998 ; Hopkinson and Jones 2000 ).

    The localization of 6?4 in the pre-hemidesmosomal structures is associated with an increase in the amount of CD151 and a loss of 3?1 from these structures. In addition to the clustering of CD151 in hemidesmosome-like structures, we found that the levels of CD151 at the cell surface are increased in PA-JEB/?4 cells, that stably express the integrin 6?4. It has been suggested that CD151 has a role in endocytosis and subsequent recycling of ?1 integrins to the cell surface because of their similar intracellular localization in endosomal structures (Sincock et al. 1999 ). Recycling of the integrin 6?4 from the plasma membrane to internal pools and back to the plasma membrane has also been observed (Bretscher 1992 ; Gaietta et al. 1994 ). Based on this knowledge and the data presented, it is tempting to speculate that CD151 is involved in the internalization of 6?4 into the cells and the sorting of it to hemidesmosomes in keratinocytes. Binding of 6?4 to an immobilized ligand may prevent the integrin from becoming internalized, thus resulting in an increased expression at the cell surface.

    The mechanism responsible for the loss of 3?1 from hemidesmosomal structures is not known, but it might be explained by a higher affinity of 6?4 for laminin-5, thus preventing 3?1 from interacting with it. Both 3?1 and 6?4 bind to the same domain of their ligand (Delwel and Sonnenberg 1997 ; Aumailley and Rouselle 1999 ). Alternatively, by inside-out signaling, the activity of 3?1 might be downregulated so that the protein can no longer interact with laminin-5. The affinities of 3?1 and 6?4 for laminin-5 might also become different as a result from proteolytic processing of the 3 or 2 chain of the laminin-5 molecule (Giannelli et al. 1997 ; Goldfinger et al. 1998 , Goldfinger et al. 1999 ). It has been suggested that unprocessed laminin-5 is the primary ligand for 3?1, while 6?4 may preferentially interact with proteolytically processed laminin-5 (Burgeson and Christiano 1997 ).

    Since complex formation between tetraspans is well established and since their expression patterns broadly overlap, they may compensate for each other if one of them is lacking (Berditchevski et al. 1996 ; Yanez-Mo et al. 1998 ; Fitter et al. 1999 ). The localization of CD151 in pre-hemidesmosomal structures and its recruitment into hemidesmosomes in PA-JEB cells after transfection with ?4, however, appears to be selective as the tetraspans CD9, CD63, and CD81, which are also expressed by keratinocytes, were not detected in these structures. The distinct distribution of CD151 suggests that at least one of its functions is different from those of the other tetraspans.

    The 6 Chain Is Critical for the Recruitment of CD151 into Hemidesmosomes

    Based on experimental data, it is generally assumed that integrins bind directly or indirectly to tetraspans by the extracellular domain of their -subunit (Mannion et al. 1996 ; Yauch et al. 1998 ). This assumption is supported by our finding that the IL-2R/?4 chimera cannot recruit CD151 into hemidesmosomes. The mechanism by which this chimera becomes localized into the pre-hemidesmosomal structures is not clear. We consider a direct binding of the IL2R/?4 chimera to CD151 unlikely, because CD151 contains only three small intracellular domains. Previous studies have indicated that binding to plectin is required for the localization of the IL2R/?4 chimera at the basal side of PA-JEB keratinocytes (Nievers et al. 2000 ). However, it is unlikely that plectin by itself can mediate the localization of the chimera into the 3?1/CD151 clusters, because the protein is not concentrated at these sites (Schaapveld et al. 1998 ). Perhaps, plectin facilitates the interaction of ?4 with an as yet unidentified component in the 3?1-CD151 clusters and thus contributes to the localization of the chimera at these sites.

    The finding that the IL2R/?4 chimera is directed to pre-hemidesmosomal structures without clustering of CD151, whereas it remains capable of recruiting BP180 and BP230 (Nievers et al. 1998 ), suggests that CD151 is not essential for the formation of hemidesmosomes. However, it is important to mention that although the chimera becomes localized in pre-hemidesmosomal structures, these never seem to reach the size of the hemidesmosomal clusters as seen in the PA-JEB/?4 cells that stably express the integrin 6?4 (see Fig 4). Thus, CD151 might have a role in stabilizing the hemidesmosomal structures and in this way in determining their size. However, definition of the exact role of CD151 in hemidesmosome formation awaits further analysis.

    The Role of CD151 in the Spatial Organization of Hemidesmosomes and the Surrounding Focal Adhesions

    Apart from their spatial proximity, a link between hemidesmosomes and focal adhesions has previously been suggested, since they share plectin (Sanchez-Aparicio et al. 1997 ; Nievers et al. 1998 ; Geerts et al. 1999 ). In this paper, we provide evidence that CD151 is another component shared by these structures. This protein, however, is not an essential component of focal adhesions, and its expression seems to be affected by 6?4. Only in ?4-deficient PA-JEB keratinocytes did CD151 appear to be a resident protein of focal adhesions, while in ?4-transfected PA-JEB cells, its distribution seems to be dynamically regulated, varying between cells and even between focal adhesions in the same cell. The absence of CD151 in focal adhesions in PA-JEB/?4 cells appeared not to affect the localization of 3?1 because this integrin is colocalized with vinculin in focal adhesions before and after ?4 transfection. An explanation for the shift in the distribution of CD151 from focal adhesions to hemidesmosomes after ?4 transfection could be that the protein binds more strongly to 6?4 than to 3?1. However, biochemical studies do not support this conclusion because complexes of 6?4 and CD151 could not be detected in cells that have been lysed in 1% NP-40, whereas under these conditions CD151 remains complexed with 3?1. CD151 cannot only associate with the integrin 3?1 but also with 6?1 (Yauch et al. 1998 ; Serru et al. 1999 ; our own unpublished results). We established previously that expression of 6?1 is upregulated and localized to focal adhesions in ?4-deficient PA-JEB cells (Schaapveld et al. 1998 ). Thus, it is possible that downregulation of 6?1 after ?4 is expressed contributes to the loss of CD151 from focal adhesions. However, as a result of prolonged culturing, the PA-JEB keratinocytes had lost most of their surface 6?1 and then synthesized more 5?1. At this stage, therefore, the effect of 6?1 on the localization of CD151 can only be limited.

    A complete physical separation of focal adhesions and hemidesmosomes may take place after the removal of CD151 and 3?1 from these structures, respectively. Subsequently, the hemidesmosomal structures may mature and then contain BP180 and BP230. The actin cytoskeleton that is concentrically located around hemidesmosomes and associated with the focal adhesions may act as a physical barrier for hemidesmosomal components, thereby confining them to and thus maintaining hemidesmosomes.

    Although the presence of 3?1 in the pre-hemidesmosomal structures suggests an important role for this integrin in the formation of hemidesmosomes, results with knockout mice revealed that hemidesmosome formation can occur in the absence of 3?1 (DiPersio et al. 1997 ). It is possible that in the absence of 3?1 other integrins form complexes with CD151 which, when clustered at the cell basis, can serve as nucleation sites for hemidesmosome assembly by 6?4. However, there is little support for this explanation, since CD151 seems to interact specifically with laminin-binding integrins. A more likely explanation for the presence of hemidesmosomes in the 3-null mice is that for the formation of hemidesmosomes, initial 3?1-mediated clustering of CD151 is not required, but that it only facilitates the subsequent recruitment of CD151/6?4 into hemidesmosomal structures. In that case, hemidesmosomes can still be formed in the absence of 3?1, but the kinetics of their assembly might be different from that in wild-type mice. Alternatively, the structure and stability of hemidesmosomes may, in fact, be compromised in the 3-null mice in a way that it is not yet evident at the ultrastructural level when the mice die at birth.

    The focal adhesions found at the cell periphery neither contain 3?1 nor CD151. These focal adhesions are probably assembled on fibronectin and vitronectin derived from serum. The integrins that interact with these adhesive ligands are 5?1 and v?3 and both may be involved in the initial adhesion and spreading of the cells. The absence of CD151 as well as of 3?1 in these peripheral focal adhesions is consistent with the finding that this tetraspan preferentially associates with the laminin-binding integrins 3?1 and 6?4 and provides further support for its role in hemidesmosome assembly and stability.

    In summary, we demonstrate that CD151 is a newly detected hemidesmosomal component. We show that CD151 plays a role in the sequence of events, which take place in hemidesmosome assembly. An additional role for CD151 in the cross-talk with the surrounding focal adhesions is suggested.

    References

    Angelisová, P., Hilgert, I., Hejí, V. 1994. Association of four antigens of the tetraspans family (CD37, CD53, TAPA- 1, and R2/C33) with MHC class II glycoproteins. Immunogenetics. 39:249-256.

    Ashman, L.K., S. Fitter, P.M. Sincock, L.Y. Nguyen, and A.C. Cambareri. 1997. CD151 (PETA-3) workshop summary report. Leukocyte Typing VI. White Cell Differentiation Antigens. T. Kishimoto, H. Kikutani, A.E.G.Kr. von dem Borne, S.M. Goyert, D.Y. Mason, M. Miyasaka, L. Moretta, K. Okumura, S. Shaw, T.A. Springer, K. Sugamura, and H. Zola, editors. Garland Publishing Inc. 681–683.

    Aumailley, M., Rouselle, P. 1999. Laminins of the dermo-epidermal junction. Matrix Biol. 18:19-28.

    Berditchevski, F., Bazzoni, G., Hemler, M.E. 1995. Specific association of CD63 with the VLA-3 and VLA-6 integrins. J. Biol. Chem. 270:17784-17790.

    Berditchevski, F., Zutter, M.M., Hemler, M.E. 1996. Characterization of novel complexes on the cell surface between integrins and proteins with 4 transmembrane domains (TM4 proteins). Mol. Biol. Cell. 7:193-207.

    Berditchevski, F., Tolias, K.F., Wong, K., Carpenter, C.L., Hemler, M.E. 1997. A novel link between integrins, transmembrane-4 superfamily proteins (CD63 and CD81), and phosphatidylinositol 4-kinase. J. Biol. Chem. 272:2595-2598.

    Berditchevski, F., Odintsova, E. 1999. Characterization of integrin-tetraspanin adhesion complexes: role of tetraspanins in integrin signaling. J. Cell Biol. 146:477-492.

    Borradori, L., Koch, P.J., Niessen, C.M., Erkeland, S., van Leusden, M.R., Sonnenberg, A. 1997. The localization of bullous pemphigoid antigen 180 (BP180) in hemidesmosomes is mediated by its cytoplasmic domain and seems to be regulated by the ?4 integrin subunit. J. Cell Biol 136:1333-1347.

    Borradori, L., Chavanas, S., Schaapveld, R.Q.J., Gagnoux-Palacios, L., Calafat, J., Meneguzzi, G., Sonnenberg, A. 1998. Role of the bullous pemphigoid antigen (BP180) in the assembly of hemidesmosomes and cell adhesion. Reexpression of BP180 in generalized atrophic benign epidermolysis bullosa. Exp. Cell Res. 239:463-476.

    Borradori, L., Sonnenberg, A. 1999. Structure and function of hemidesmosomes: more than simple adhesion complexes. J. Invest. Dermatol. 112:411-418.

    Bretscher, M.S. 1992. Circulating integrins: 5?1, 6?4 and Mac-1, but not 3?1, 4?1 or LFA-1. EMBO (Eur. Mol. Biol. Organ.) J. 11:405-410.

    Burgeson, R.E., Christiano, A.M. 1997. The dermal-epidermal junction. Curr. Opin. Cell Biol. 9:651-658.

    Burridge, K., Chrzanowska-Wodnicka, M., Zhong, C. 1997. Focal adhesion assembly. Trends Cell Biol. 7:342-347.

    Carter, W.G., Ryan, M., Gahr, P.J. 1991. Epiligrin, a new cell adhesion ligand for integrin 3?1 in epithelial basement membranes. Cell. 65:599-610.

    Calafat, J., Janssen, H., Stahle-Backdahl, M., Zuurbier, A.E., Knol, E.F., Egesten, A. 1997. Human monocytes and neutrophils store transforming growth factor-alpha in a subpopulation of cytoplasmic granules. Blood. 90:1255-1266.

    Defilippi, P., van Hinsbergh, A., Bertolotto, A., Rossino, P., Silengo, L., Tarone, G. 1991. Differential distribution and modulation of expression of 1?1 on human endothelial cells. J. Cell Biol. 114:855-863.

    Delwel, G.O., Hogervorst, F., Kuikman, I., Paulsson, M., Timpl, R., Sonnenberg, A. 1993. Expression and function of the cytoplasmic variants of the integrin 6 subunit in transfected K562 cells. Activation-dependent adhesion and interaction with isoforms of laminin. J. Biol. Chem. 268:25865-25875.

    Delwel, G.O., Sonnenberg, A. 1997. Laminin isoforms and their receptors. In Horton M.A., ed. Adhesion Receptors as Therapeutic Targets. Boca Raton, FL, CRC Press, 9-36.

    de Melker, A.A., Sterk, L.M.Th., Delwel, G.O., Fles, D.L.A., Daams, H., Weening, J.J., Sonnenberg, A. 1997. The A and B variants of the 3 integrin subunit: tissue distribution and functional characterization. Lab. Invest 76:547-563.

    DiPersio, C.M., Shah, S., Hynes, R.O. 1995. 3A?1 integrin localizes to focal contacts in response to diverse extracellular matrix proteins. J. Cell Sci. 106:2321-2336.

    DiPersio, C.M., Hodivala-Dile, K.M., Jaenisch, R., Kreidberg, J.A., Hynes, R.O. 1997. 3?1 integrin is required for normal development of the epidermal basement membrane. J. Cell Biol. 137:729-742.

    Dowling, J., Yu, Q.-C., Fuchs, E. 1996. ?4 integrin is required for hemidesmosome formation, cell adhesion and cell survival. J. Cell Biol 134:559-572.

    Fitter, S., Sincock, P.M., Jolliffe, C.N., Ashman, L.K. 1999. Transmembrane 4 superfamily protein CD151 (PETA-3) associates with 3?1 and IIb?3 integrins in haemopoietic cell lines and modulates cell-cell adhesion. Biochem. J. 338:61-70.

    Fontao, L., Dirrig, S., Owaribe, K., Kedinger, M., Launay, J.F. 1997. Polarized expression of HD1: relationship with the cytoskeleton in cultured human colonic carcinoma cells. Exp. Cell Res 231:319-327.

    Gaietta, G., Redelmeier, T.E., Jackson, M.R., Tamura, R.N., Quaranta, V. 1994. Quantitative measurement of 6?1 and 6?4 integrin internalization under cross-linking conditions: a possible role for a6 cytoplasmic domains. J. Cell Sci. 107:3339-3349.

    Geerts, D., Fontao, L., Nievers, M.G., Schaapveld, R.Q.J., Purkis, P.E., Wheeler, G.N., Lane, E.B., Leigh, I.M., Sonnenberg, A. 1999. Binding of integrin 6?4 to plectin prevents plectin association with F-actin but does not interfere with intermediate filament binding. J. Cell Biol. 147:417-434.

    Geiger, B. 1979. A 130K protein from chicken gizzard: its localization at the termini of microfilament bundles in cultured chicken cells. Cell. 18:193-205.

    Georges-Labouesse, E., Messadeq, N., Yehia, G., Cadalbert, L., Dierich, A., LeMeur, M. 1996. Absence of the 6 integrin leads to epidermolysis bullosa and neonatal death in mice. Nat. Genet 13:370-373.

    Giannelli, G., Falk-Marzillier, J., Schiraldi, O., Stetler-Stevenson, W.G., Quaranta, V. 1997. Induction of cell migration by matrix metalloprotease-2 cleavage of laminin-5. Science. 277:225-228.

    Goldfinger, L., Stack, M.S., Jones, J.C.R. 1998. Processing of laminin-5 and its functional consequences: role of plasmin and tissue-type plasminogen activator. J. Cell Biol. 141:255-266.

    Goldfinger, L.E., Hopkinson, S.B., deHart, G.W., Collawn, S., Couchman, J.R., Jones, J.C. 1999. The 3 laminin subunit, 6?4 and 3?1 integrin coordinately regulate wound healing in cultured epithelial cells and in the skin. J. Cell Sci. 12:2615-2629.

    Hall, D.E., Reichardt, L.F., Crowley, E., Holley, B., Moezzi, H., Sonnenberg, A., Damsky, C.H. 1990. The 1?1 and 6?1 integrin heterodimers mediate cell attachment to distinct sites on laminin. J. Cell Biol. 110:2175-2184.

    Hasegawa, H., Utsunomiya, T., Kishimoto, K., Yanagisawa, K., Fujita, S. 1996. SFA-1, a novel cellular gene induced by human T-cell leukemia virus type 1, is a member of the transmembrane 4 superfamily. J. Virol 70:3258-3263.

    Hasegawa, H., Nomura, T., Kishimoto, K., Yanagisawa, K., Fujita, S. 1998. SFA-1/PETA-3 (CD151), a member of the transmembrane 4 superfamily, associates preferentially with 5?1 integrin and regulates adhesion of human T cell leukemia virus type 1-infected T cells to fibronectin. J. Immunol. 161:3087-3095.

    Hemler, M.E. 1998. Integrin associated proteins. Curr. Opin. Cell Biol. 5:578-585.

    Hessle, H., Sakai, L.Y., Hollister, D.W., Burgeson, R.E., Engvall, E. 1984. Basement membrane diversity detected by monoclonal antibodies. Differentiation. 26:49-54.

    Hogervorst, F., Kuikman, I., Noteboom, E., Sonnenberg, A. 1993. The role of phosphorylation in activation of the 6A?1 laminin receptor. J. Biol. Chem. 268:18427-18430.

    Hopkinson, S.B., Jones, J.C.R. 2000. The N terminus of the transmembrane protein BP180 interacts with the N-terminal domain of BP230, thereby mediating keratin cytoskeleton anchorage to the cell surface at the site of the hemidesmosome. Mol. Biol. Cell. 11:277-286.

    Hoejí, V., Vlek, C. 1991. Novel structurally distinct family of leucocyte surface glycoproteins including CD9, CD37, CD53 and CD63. FEBS Lett. 288:1-4.

    Imai, T., Yoshie, O. 1993. C33 antigen and M38 antigen recognized by monoclonal antibodies inhibitory to syncytium formation in human T cell leukemia virus 1 are both members of the transmembrane 4 superfamily and associate with each other and with CD4 or CD8 in T cells. J. Immunol 151:6470-6481.

    Indig, F.E., Diaz-Gonzalez, F., Ginsberg, M.H. 1997. Analysis of the tetraspanin CD9-integrin IIb?3 (GPIIb-IIIa) complex in platelet membranes and transfected cells. Biochem. J. 327:291-298.

    Jockusch, B.M., Bubeck, P., Giehl, K., Kroemker, M., Moschner, J., Rothkegel, M., Rüdiger, M., Schluter, K., Stanke, G., Winkler, J. 1995. The molecular architecture of focal adhesions. Annu. Rev. Cell Dev. Biol 11:379-416.

    Jones, J.C.R., Hopkinson, S.B., Goldfinger, L.E. 1998. Structure and assembly of hemidesmosomes. Bioessays. 20:488-494.

    Kantor, R.R.S., Mattes, M.J., Lloyd, K.O., Old, L.J., Albino, A.P. 1987. Biochemical analysis of two cell surface glycoprotein complexes, very common antigen 1 and very common antigen 2. J. Biol. Chem 262:15158-15165.

    Kennel, S.J., Epler, R.G., Lankford, T.K., Foote, L.J., Dickas, V., Canamucio, M., Cavalierie, R., Cosimelli, M., Venturo, I., Falcioni, R. 1990. Second generation monoclonal antibodies to the human integrin 6?4. Hybridoma. 9:243-255.

    Kinsella, T.M., Nolan, G.P. 1996. Episomal vectors rapidly and stably produce high-titer recombinant retrovirus. Hum. Gen. Ther. 7:1405-1413.

    Lagaudrière-Gesbert, C., Le Naour, F., Lebel-Binay, S., Billard, M., Lemichez, E., Boquet, P., Boucheix, C., Conjeaud, H., Rubinstein, E. 1997. Functional analysis of four tetraspans, CD9, CD53, CD81, and CD82, suggests a common role in costimulation, cell adhesion, and migration: only CD9 upregulates HB-EGF activity. Cell Immunol. 182:105-112.

    Liou, W., Geuze, H.J., Slot, J.W. 1996. Improving structural integrity of cryosections for immunogold labeling. Histochem. Cell Biol. 106:41-58.

    Maecker, H.T., Todd, S.C., Levy, S. 1997. The tetraspanin superfamily: molecular facilitators. FASEB J. 11:428-442.

    Mannion, B.A., Berditchevski, F., Kraeft, S.K., Chen, L.B., Hemler, M.E. 1996. Transmembrane-4 superfamily proteins CD81 (TAPA-1), CD82, CD63, and CD53 specifically associated with integrin 4?1 (CD49d/CD29). J. Immunol. 157:2039-2047.

    Marinkovich, M.P., Lundstrum, G.P., Burgeson, R.E. 1992. The anchorage filament protein kalinin is synthesized and secreted as a high molecular weight precursor. J. Biol. Chem 119:695-703.

    Nakamura, K., Iwamoto, R.I., Mekada, E. 1995. Membrane-anchored heparin-binding EGF-like growth factor (HB-EGF) and diphtheria toxin receptor-associated protein (DRAP27)/CD9 form a complex with integrin 3?1 at cell-cell contact sites. J. Cell Biol. 129:1691-1705.

    Niessen, C.M., Hogervorst, F., Jaspars, L.H., de Melker, A.A., Delwel, G.O., Hulsman, E.H.M., Kuikman, I., Sonnenberg, A. 1994. The 6?4 integrin is a receptor for both laminin and kalinin. Exp. Cell Res 211:360-367.

    Niessen, C.M., Hulsman, E.H.M., Rots, E.S., Sánchez-Aparicio, P., Sonnenberg, A. 1997. Integrin 6?4 forms a complex with the cytoskeletal protein HD1 and induces its redistribution in transfected COS-7 cells. Mol. Biol. Cell. 8:555-566.

    Nievers, M.G., Schaapveld, R.Q.J., Oomen, L.C.J.M., Fontao, L., Geerts, D., Sonnenberg, A. 1998. Ligand-independent role of the ?4 integrin subunit in the formation of hemidesmosomes. J. Cell Sci. 111:1659-1672.

    Nievers, M.G., Schaapveld, R.Q.J., Sonnenberg, A. 1999. Biology and function of hemidesmosomes. Matrix Biol. 18:5-17.

    Nievers, M.G., Kuikman, I., Geerts, D., Sonnenberg, A. 2000. Formation of hemidesmosome-like structures in the absence of ligand binding by the 6?4 integrin requires binding of HD1/plectin to the cytoplasmic domain of the ?4 integrin subunit. J. Cell Sci. 113:963-973.

    Nishizawa, Y., Uematsu, J., Owaribe, K. 1993. HD4, a 180 kDa bullous pemphigoid antigen, is a major glycoprotein of the hemidesmosome. J. Biochem 113:493-501.

    Okochi, H., Kato, M., Nashiro, K., Yoshie, O., Miyazono, K., Furue, M. 1997. Expression of tetra-spans transmembrane family (CD9, CD37, CD53, CD63, CD81, CD82) in normal and neoplastic human keratinocytes: an association of CD9 with 3?1 integrin. Brit. J. Dermatol. 136:857-863.

    Okumura, M., Uematsu, J., Hirako, Y., Nishizawa, Y., Shimizu, H., Kido, N., Owaribe, K. 1999. Identification of the hemidesmosomal 500 kDa protein (HD1) as plectin. J. Biochem. 126:1144-1150.

    Rezniczek, G.A., de Pereda, J.M., Reipert, S., Wiche, G. 1998. Linking integrin 6?4-based cell adhesion to the intermediate filament cytoskeleton: direct interaction between the ?4 subunit and plectin at multiple molecular sites. J. Cell Biol. 141:209-225.

    Riddelle, K.S., Green, K.J., Jones, J.C.R. 1991. Formation of hemidesmosomes in vitro by a transformed rat bladder cell line. J. Cell Biol. 112:159-168.

    Rouselle, P., Lundstrum, G.P., Keene, D.R., Burgeson, R.E. 1991. Kalinin: an epithelium-specific basement membrane adhesion molecule that is a component of anchoring filaments. J. Cell Biol. 114:567-576.

    Ruzzi, L., Gagnoux-Palacios, L., Pinola, M., Belli, S., Meneguzzi, G., D'Alessio, M., Zambruno, G. 1997. A homozygous mutation in the integrin 6 gene in junctional epidermolysis bullosa with pyloric atresia. J. Clin. Invest. 99:2826-2831.

    Sánchez-Aparicio, P., Martínez de Velasco, A.M., Niessen, C.M., Borradori, L., Kuikman, I., Hulsman, E.H., F?ssler, R., Owaribe, K., Sonnenberg, A. 1997. The subcellular distribution of the high molecular mass protein, HD1, is determined by the cytoplasmic domain of the integrin ?4 subunit. J. Cell Sci. 110:169-178.

    Schaapveld, R.Q.J., Borradori, L., Geerts, D., van Leusden, M.R., Kuikman, I., Nievers, M.G., Niessen, C.M., Steenbergen, R.D., Snijders, P.J., Sonnenberg, A. 1998. Hemidesmosome formation is initiated by the ?4 integrin subunit, requires complex formation of ?4 and HD1/plectin, and involves a direct interaction between ?4 and the bullous pemphigoid antigen 180. J. Cell Biol. 142:271-284.

    Serru, V., Le Naour, F., Billard, M., Azorsa, D.O., Lanza, F., Boucheix, C., Rubinstein, E. 1999. Selective tetraspan-integrin complexes (CD81/4?1, CD151/3?1, CD151/6?1) under conditions disrupting tetraspan interactions. Biochem. J. 340:103-111.

    Sincock, P.M., Mayrhofer, G., Ashman, L.K. 1997. Localization of the transmembrane 4 superfamily (TM4SF) member PETA-3 (CD151) in normal human tissues: comparison with CD9, CD63, and 5?1 integrin. J. Histochem. Cytochem. 45:515-525.

    Sincock, P.M., Fitter, S., Parton, R.G., Berndt, M.C., Gamble, J.R., Ashman, L.K. 1999. PETA-3/CD151, a member of the transmembrane 4 superfamily, is localised to the plasma membrane and endocytic system of endothelial cells, associates with multiple integrins and modulates cell function. J. Cell Sci. 112:833-844.

    Sugiura, T., Berditchevski, F. 1999. Function of 3?1-tetraspanin protein complexes in tumor cell invasion. Evidence for the role of the complexes in production of matrix metalloproteinase 2 (MMP-2). J. Cell Biol. 146:1375-1389.

    Tanaka, T., Korman, N.J., Shimizu, H., Eady, R.A.J., Klaus-Kovtun, V., Cehrs, K., Stanley, J.R. 1990. Production of rabbit antibodies against carboxy-terminal epitopes encoded by bullous pemphigoid cDNA. J. Invest. Dermatol 94:617-623.

    Uematsu, J., Nishizawa, Y., Sonnenberg, A., Owaribe, K. 1994. Demonstration of type II hemidesmosomes in a mammary gland epithelial cell line, BMGE-H. J. Biochem 115:469-476.

    van der Neut, R., Krimpenfort, P., Calafat, J., Niessen, C.M., Sonnenberg, A. 1996. Epithelial detachment due to absence of hemidesmosomes in integrin ?4 null mice. Nat. Genet. 13:366-369.

    van Leeuwen, F.N., Kain, H.E., Kammen, R.A., Michiels, F., Kranenburg, O.W., Collard, J.G. 1997. The guanine nucleotide exchange factor Tiam1 affects neuronal morphology; opposing roles for the small GTPases Rac and Rho. J. Cell Biol. 139:797-807.

    Vidal, F., Aberdam, D., Miquel, C., Christiano, A.M., Pulkkinen, L., Uitto, J., Ortonne, J.-P., Meneguzzi, G. 1995. Integrin ?4 mutations associated with junctional epidermolysis bullosa with pyloric atresia. Nat. Genet 10:229-234.

    Watt, F.M., Hertle, M.D. 1994. Keratinocyte integrins. In Leigh I.M., Lane E.B., Watt F.M., eds. The Keratinocyte Handbook. Cambridge, Cambridge University Press, 153-164.

    Wright, M.D., Tomlinson, M.G. 1994. The ins and outs of the transmembrane 4 superfamily. Immunol. Today 15:588-594.

    Yá?ez-Mó, M., Alfranca, A., Cabanas, C., Marazuela, M., Tejedor, R., Ursa, M.A., Ashman, L.K., de Landazuri, M.O., Sanchez-Madrid, F. 1998. Regulation of endothelial cell motility by complexes of tetraspan molecules CD81/TAPA-1 and CD151/PETA-3 with 3?1 integrin localized at endothelial lateral junctions. J. Cell Biol. 141:791-804.

    Yauch, R.L., Berditchevski, F., Harler, M.B., Reichner, J., Hemler, M.E. 1998. Highly stoichiometric, stable, and specific association of integrin 3?1 with CD151 provides a major link to phosphatidylinositol 4- kinase, and may regulate cell migration. Mol. Biol. Cell. 9:2751-2765.(Lotus M.Th. Sterka, Cecile A.W. Geuijena)

http://www.100md.com/html/DirDu/2007/02/17/37/45/36.htm