The Short Arm of the Laminin {gamma}2 Chain Plays a Pivotal Role in the Incorporation of Laminin 5 into the Extracellular Matrix and in Cell Adhesion

Laurent Gagnoux-Palaciosa, Maryline Allegraa, Flavia Spiritoa, Olivier Pommereta, Christine Romeroa, Jean-paul Ortonneb, and Guerrino Meneguzzia
a Faculty of Medicine, U385 Institut National de la Santé et de la Recherche Médicale, Cedex 2, 06107 Nice, France
b Dermatology Service, L'Archet Hospital, Cedex 3, 06202 Nice, France

Correspondence to: Guerrino Meneguzzi, U385 INSERM, Faculté de Médecine, Cedex 2, 06107 Nice, France. Tel:(33) 493-37-77-78 Fax:(33) 493-81-14-04 E-mail:meneguzz{at}unice.fr.


  Abstract
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

Laminin 5 is a basement membrane component that actively promotes adhesion and migration of epithelial cells. Laminin 5 undergoes extracellular proteolysis of the {gamma}2 chain that removes the NH2-terminal short arm of the polypeptide and reduces the size of laminin 5 from 440 to 400 kD. The functional consequence of this event remains obscure, although lines of evidence indicate that cleavage of the {gamma}2 chain potently stimulated scattering and migration of keratinocytes and cancer cells. To define the biological role of the {gamma}2 chain short arm, we expressed mutated {gamma}2 cDNAs into immortalized {gamma}2-null keratinocytes. By immunofluorescence and immunohistochemical studies, cell detachment, and adhesion assays, we found that the {gamma}2 short arm drives deposition of laminin 5 into the extracellular matrix (ECM) and sustains cell adhesion. Our results demonstrate that the unprocessed 440-kD form of laminin 5 is a biologically active adhesion ligand, and that the {gamma}2 globular domain IV is involved in intermolecular interactions that mediate integration of laminin 5 in the ECM and cell attachment.

Key Words: keratinocyte, epithelial adhesion, cell migration, basement membrane, epidermolysis bullosa


  Introduction
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

The epithelial basement membranes consist of a complex network of extracellular matrix (ECM)1 molecules that mediate tissue integrity and homeostasis, and control morphogenesis as well as tissue repair and tumorigenesis. Laminins are multifunctional glycoproteins of the ECM that contribute to the architecture of the basement membranes and play a crucial role in cell adhesion, growth, migration, and differentiation (Colognato and Yurchenco 2000 ). These cross-shaped molecules consist of three subunits, classified as {alpha}, ß, and {gamma} chains on the basis of their primary structure deduced from sequence data. Laminin isoforms are expressed at various stages of development and in specific tissue locations in different species. In the human epidermis, basal keratinocytes express laminin 5 ({alpha}3ß3{gamma}2), laminin 6 ({alpha}3ß1{gamma}1), and laminin 10 ({alpha}5ß1{gamma}1) (Champliaud et al. 1996 ).

Laminin 5 is found in the basement membrane of stratified and transitional epithelia, prevalently associated with the extracellular anchoring filaments of the lamina lucida that connect the hemidesmosomes to the anchoring fibrils of the underlying stroma (Verrando et al. 1987 ; Rousselle et al. 1991 ; Masunaga et al. 1996 ). Laminin 5 is a specific substrate for adhesion in proliferating and migrating keratinocytes (Rousselle et al. 1991 ; Rousselle and Aumailley 1994 ). The biological relevance of laminin 5 in dermal–epidermal adhesion has been emphasized by the identification of genetic mutations affecting laminin 5 in patients with junctional epidermolysis bullosa (JEB), an inherited genodermatosis characterized by fragility of the skin and blistering in response to minor trauma (Aberdam et al. 1994a ; Pulkkinen et al. 1994 ). The adhesive role of laminin 5 was also confirmed by the detection of circulating autoantibodies against epitopes of laminin 5 in patients with acquired blistering skin disorders which are characterized by dermal–epidermal cleavage (Yancey et al. 1995 ; Lazarova et al. 1996 ). Laminin 5 has been reported to influence morphogenetic events (Baker et al. 1996 ; Stahl et al. 1997 ), to affect cell motility (Zhang and Kramer 1996 ; O'Toole et al. 1997 ), to enhance invasiveness in human cancers (Kikkawa et al. 1994 ; Pyke et al. 1994 , Pyke et al. 1995 ; Giannelli et al. 1997 ; Koshikawa et al. 1999 ), and to control cell growth (Ryan et al. 1999 ).

Current models propose that laminin 5 mediates epithelial cell adhesion via integrin {alpha}3ß1 in focal adhesions and integrin {alpha}6ß4 in hemidesmosomes (Carter et al. 1991 ; Sonnenberg et al. 1993 ; Mainiero et al. 1995 ; Baker et al. 1996 ; Goldfinger et al. 1998 ). It has been shown that the domain(s) interacting with the cell surface receptors reside within the COOH-terminal G domains of the protein (Baker et al. 1996 ; Mizushima et al. 1997 ; Hirosaki et al. 2000 ). Conversely, the precise contribution of the NH2 terminus of the three chains of laminin 5 to cell adhesion is not yet well understood. In laminins, in general, the NH2-terminal domains are thought to mediate polymerization into a network that stabilizes the basement membrane (Colognato and Yurchenco 2000 ). Compared with the other laminin isoforms, the short arms of the {alpha}3, ß3, and {gamma}2 chains are substantially truncated and do not conserve the domains known to direct integration of laminins into the basement membrane architecture (Cheng et al. 1997 ; Colognato and Yurchenco 2000 ). However, it has been proposed that the NH2 terminus of laminin 5 can interact with laminin 6 and 7, and also with the NC-1 domain of type VII collagen, the major component of anchoring fibrils (Marinkovich et al. 1992 ; Champliaud et al. 1996 ; Chen et al. 1997 ; Rousselle et al. 1997 ). On these bases, it has been suggested that monomeric laminin 5 molecules within the anchoring filaments bridge integrin {alpha}6ß4 to type VII collagen and provide the significant force that promotes cohesion of the dermis and epidermis, whereas laminin 5 complexed to laminins 6 and 7 interacts with integrin {alpha}3ß1 and contributes to assembly and stability of the basement membrane (DiPersio et al. 1997 ; Rousselle et al. 1997 ). Binding to type VII collagen NC-1 domain appears to occur within the ß3 or {gamma}2 short arms (Rousselle et al. 1997 ; Chen et al. 1999 ). Formation of the disulfide-bonded complex between laminin 5 and laminins 6 and 7 could involve the uncoupled cysteinyl residues harbored by the globular domain VI of the chain ß3 and the domain IIIa of the {alpha}3 chain (Gerecke et al. 1994 ; Amano et al. 2000 ). It has also been proposed that binding of the basement membrane component fibulin 2 through the globular domain IV of the {gamma}2 chain associates mouse laminin 5 to the matrix proteins (Utani et al. 1997 ). In laminin 5–null keratinocytes, the adhesion function of the protein is not complemented by other laminins (Vidal et al. 1995 ; Miquel et al. 1996 ).

In the ECM, laminin 5 is found in two most abundant forms of 440 and 400 kD. The 440-kD heterotrimer is generated by proteolytic cleavage of the {alpha}3 chain present in the 460-kD cell-associated form of laminin 5 (Marinkovich et al. 1992 ). Extracellular processing of the {alpha}3 that excises the COOH terminus at a cleavage site within the subdomain G4, and proteolytic cleavage within the EGF-like repeat 2 of domain IIIa, have also been reported (Champliaud et al. 1996 ; Goldfinger et al. 1998 ; Amano et al. 2000 ). The proteolytic processing of the {alpha}3 chain G domain is thought to modulate the interactions of laminin 5 with the integrin cell receptors and to govern cell anchorage and motility (Goldfinger et al. 1998 ).

Extracellular processing also removes the globular domain IV and the EGF-like rich domain V of the laminin {gamma}2 short arm. Excision of the 434 NH2-terminal amino acids shortens the {gamma}2 chain from 155 to 105 kD, and reduces the size of laminin 5 to 400 kD ({alpha}3, 165 kD; ß3, 140 kD; {gamma}2, 105 kD). Therefore, this processed 400-kD form of the laminin 5 lacks most of the {gamma}2 chain short arm, but leaves the ß3 short arm intact. The functional role of the {gamma}2 cleavage is unknown and the biological functions specific to each extracellular form of laminin 5 remain obscure.

Extracellular 440-kD laminin 5 has so far been considered a precursor form of the fully processed laminin 5. To define the functions of this molecule, and to identify the possible biological role of the {gamma}2 short arm excised by the proteolytic processing, we have transferred mutated laminin {gamma}2 cDNAs into immortalized {gamma}2-null keratinocytes. In this study, we report that the laminin {gamma}2 short arm is required for deposition of laminin 5 into the ECM, and we provide evidence that the unprocessed 440-kD form of laminin 5 sustains cell adhesion and inhibits cell migration.


  Materials and Methods
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References


cDNA Constructs
Mutated laminin {gamma}2 constructs were obtained by site-directed mutagenesis of a full length {gamma}2 cDNA cloned in the expression vector p{gamma}WT (Gagnoux-Palacios et al. 1996 ) in which the antigenic peptide sequence MASMTGGQQMG (T7-Tag) of T7 bacteriophage was inserted 3' to the coding sequence of the {gamma}2 cDNA (see Fig 1 B). The presence of the T7-Tag does not affect the laminin 5 function (data not show). To construct mutant p{gamma}NC, two {gamma}2 cDNA fragments of 1,308 and 476 bp (comprising nt 1–1293 and 1305–1767 of the laminin {gamma}2 cDNA, respectively; EMBL/GenBank/DDBJ accession no. X73920) were PCR amplified using plasmid p{gamma}WT as a template. The 1,308-bp cDNA fragment was amplified using primers A, left and B, right (Table 1). The reaction mixture (25 µl) contained 10 ng of the template, 400 nM of each primer, 20 mM Tris-HCl, pH 8.8, 2 mM MgSO4, 10 mM KCl, 10 mM (NH4)2SO4, 0.1% Triton X-100, 100 µg/ml nuclease-free BSA, 200 mM dNTP, and 2.5 U of Pfu DNA polymerase (Stratagene). For amplification of the 476-bp cDNA fragment, primers were: C, left, and D, right. The primary PCR products were mixed and used as templates for a secondary PCR program using primers A and D in a reaction mixture of 25 µl. The PCR products were electrophoresed on a 1% agarose gel, eluted, mixed together, cleaved with the restriction endonucleases BsmBI and EcoRI, and cloned into a BsmBI-EcoRI–digested p{gamma}WT vector. To generate p{gamma}C, a {gamma}2 cDNA with an internal deletion of 1,208 bp (nt 1302–94) was prepared by PCR amplification of two {gamma}2 cDNA fragments: a 107-bp {gamma}2 cDNA fragment (nt 1–93) using primer A, left, and E, right, and a 478-bp {gamma}2 cDNA fragment (nt 1,303–1,766) using primers F, left, and D, right. The amplification products were subjected to a secondary PCR amplification using primers A and D. The resulting cDNA products were cloned into a BsmBI-EcoRI–digested p{gamma}WT plasmid as described above. To obtain plasmid p{gamma}M, a 1,081-bp (nt 1–1065) and a 496-bp (nt 1286–1766) cDNA fragments were amplified using the primer pair A, left, and G, right and pair H, left and D, right, respectively. After a secondary PCR amplification using primers A and D, the resulting amplimers were cloned into plasmid p{gamma}WT as described above. To generate the mutant p{gamma}III, which bears an internal deletion of 101 bp, two {gamma}2 cDNA fragments of 1,159 and 536 bp were PCR amplified using the primers pair A, left and I, right, respectively, and primer pair J, left and D, right. After a secondary PCR amplification using primers A and D, the resulting amplimers were cloned into plasmid p{gamma}WT as described above. To construct p{gamma}V, which contains an internal deletion of 242 bp, p{gamma}WT was double digested with Bsu36I and BspEI (equals AccIII), blunted, and then religated. Plasmid p{gamma}F1 was generated using the QuikChangeTM site-directed mutagenesis kit (Stratagene) and primers K, left and L, right to substitute the amino acid residues SVHKI (residues 203–207) with five alanines. Plasmid p{gamma}F2 was generated from p{gamma}F1, using the QuikChangeTM kit and the oligonucleotide pair M, left and N, right to subsitute the peptidic sequence SAEYSVHKI (residues 199–207) with nine alanines. Plasmid p{gamma}GP was generated using the QuikChangeTM kit and primers O, left and P, right to delete the amino acid residues YS (residues 432–433) and substitute the amino acid residues GD (residues 434–435) with the amino acid residues GP. The conformational changes of the {gamma}2 chain introduced by the GP substitution were assessed using the programs Biopolymer (Molecular Simulations, Inc.) and Antheprot (http://www.ibcp.fr).




View larger version (38K):
[in this window]
[in a new window]
 
Figure 1. Schematic representation of laminin 5 and the {gamma}2 chain mutants used in this study. (A) The EGF-like repeats ({square}) and the globular domains ({circ}) of the {alpha}3, ß3, and {gamma}2 chains of laminin 5 are depicted. Full gray squares represent the extracellularly cleaved NH2-terminal domain of the {gamma}2 chain. (B) The different {gamma}2 mutant constructs were obtained by directed mutagenesis of the expression vector p{gamma}WT that contains a full-length laminin {gamma}2 cDNA carrying the antigenic sequence T7-Tag at the 3' end. Plasmid p{gamma}NC encodes a {gamma}2 chain bearing an internal deletion of the four amino acids (YSGD) that constitute the proteolytic cleavage site of the {gamma}2 chain short arm (Vailly et al. 1994 ). Plasmid p{gamma}GP encodes a {gamma}2 chain in which a glycine and a proline substitute the tetrapeptide YSGD. Plasmid p{gamma}C encodes a {gamma}2 chain truncated of the NH2-terminal domains that are excised in the extracellular processing of the laminin 5. Plasmid p{gamma}M encodes a {gamma}2 chain bearing an internal deletion of 73 amino acids within domains III and IV. Plasmid p{gamma}{Delta}V encodes a {gamma}2 chain with an internal amino acid deletion within the EGF-like repeats 2 and 3 of domain V. Plasmid p{gamma}{Delta}III corresponds to a {gamma}2 chain with an internal deletion (33 amino acids) of the first EGF-like repeat of domain III. Plasmids p{gamma}F1 and p{gamma}F2 encode {gamma}2 chains harboring a substitution of the amino acid sequence SVHKI into five alanines, and a substitution of the amino acid sequence SAEYSVHKI into nine alanines, respectively. Plasmid p{gamma}50 encodes for the 50-kD NH2-terminal cleaved polypeptide of the laminin 5 {gamma}2 chain. Plasmid pß60 encodes for the first 526 amino acids of the laminin 5 ß3 short arm chain. Secretion (Secr.) in the culture medium and deposition (Dep.) on the culture support of the mutant laminin 5 heterotrimers were investigated by Western blotting and immunofluorescence observations. Cell attachment (Adh.) was determined by detachment assays.


 
View this table:
[in this window]
[in a new window]
 
Table 1. Nucleotide Sequence of the Primers Used in Site-directed Mutagenesis of the Laminin {gamma}2 cDNA

To generate plasmid p{gamma}50, the 1,302-bp {gamma}2 cDNA fragment (nt 1–1302) coding for the NH2-terminal domains of the laminin {gamma}2 chain was subcloned into the BamH1-EcoRV sites of the expression vector pcDNA3, upstream the T7-Tag. To construct plasmid pß60 the 1,574-bp cDNA sequence encoding the NH2-terminal domains of the laminin ß3 chain (nt 1–1574; EMBL/GenBank/DDBJ accession no. L25541) was subcloned into pcDNA3 upstream the hemagglutinin (HA) Tag sequence (YPYDVPDYA).

The plasmids were amplified in Escherichia coli XL1blue (Stratagene), purified using a plasmid purification kit (QIAGEN), and analyzed by nucleotide sequencing using an ABI Prism 310 genetic analyzer.


Antibodies
mAbs used in the study were: K140, specific to laminin ß3 (Marinkovich et al. 1992 ); GB3, directed against native laminin 5 (Verrando et al. 1987 ); T7-Tag, specific to the peptide sequence (MASMTGGQQMG) of T7 bacteriophage (Novagen); and anti-HA (clone 12CA5), specific to the peptide sequence (YPYDVPDYA) of the influenza HA protein (Santa Cruz Biotechnology, Inc.).

Expression of laminin {gamma}2 chain was examined using polyclonal antibody (pAb) SE144 (Vailly et al. 1994 ). pAb SE1097 was raised against the fusion protein corresponding to the laminin {gamma}2 short arm. To prepare the fusion protein, the {gamma}2 cDNA fragment was excised from plasmid p{gamma}50 and subcloned into the EcoRI site of the procaryotic expression vector pGEX-5X-3 from Amersham Pharmacia Biotech. The purified GST fusion protein was used for rabbit immunization. pAb SE1097 was then purified by immunoaffinity chromatography against the corresponding fusion protein immobilized on nitrocellulose filters after SDS-PAGE. The second antibodies coupled to tetramethylrhodamine isothiocyanate or to fluoresceine isothiocyanate were obtained from Dako. Actin cytoskeleton was labeled using phalloidin Texas red (Molecular Probes, Inc.).


Cells and Organotypic Cell Cultures
The human keratinocytes cell lines HKSV and LSV5 were grown in a 3:1 mixture of DME and Ham's F-12 medium (Life Technologies and GIBCO BRL) containing FCS (10%), hydrocortisone (0.4 µg/ml), cholera toxin (0.1 nM), and EGF (10 ng/ml) (Miquel et al. 1996 ). Swiss mouse 3T3-J2 cells and the African monkey kidney cell line COS-7 were cultured in DME containing 10% calf serum. Secondary cultures of human keratinocytes HNKs were grown on irradiated feeder layers of mouse 3T3-J2 cells in DME/Ham's F12 medium as described above and supplemented with insulin (5 µg/ml), adenine (0.18 mM), triiodothyronine (2 nM), glutamine (4 mM), and penicillin-streptomycin (50 IU/ml) (Rheinwald and Green 1975 ).

To construct artificial epithelia, cultured keratinocytes (1.6 x 107 cells) were seeded in stainless steel rings (0.6 cm2), laid on acetate cellulose filters (Millipore), and maintained immersed in growth medium changed every other day. 4 d later, the medium in the rings was removed and the keratinocyte culture was brought at the air–liquid interface for 4 d to induce differentiation (Rosdy et al. 1993 ). The artificial epithelia were then included in OCT compound Tissue-Tek (Miles Laboratories) and immediately frozen in liquid nitrogen. Vertical 4-µm sections were used for indirect immunofluorescence studies.


DNA Transfections
For transient expression, subconfluent keratinocyte cultures were transfected using the polycationic lipid Dosper (1,3-Di-Oleoyloxy-2,6-[carboxy-spermyl]-propyl-amide) from Roche. In brief, before transfection the cell cultures were incubated at 37°C with medium deprived of serum and growth factors. DNA and Dosper were separately diluted in Hepes-buffered saline (20 mM Hepes, 150 mM NaCl, pH 7.4), then mixed at a final concentration of 0.2 and 0.1 µg/ml, respectively, and added dropwise to the cell layers. After 6 h at 37°C, cells were fed with medium containing serum and growth factors two times concentrated. Transfection efficiency and expression of the transfected genes was monitored 48 h later using indirect immunofluorescence assays.

To establish cell lines L{gamma}NC, L{gamma}C, L{gamma}GP, L{gamma}F1, and L{gamma}F2 using plasmids p{gamma}NC, p{gamma}C, p{gamma}GP, p{gamma}F1, and p{gamma}F2, respectively, calcium-phosphate transfection of LSV5 cells was performed using the MBSTM mammalian transfection kit (Stratagene). 1.5 x 105 cells were seeded in 100-mm petri dishes and incubated for 24 h at 37°C. 20 µg of plasmid DNA precipitated for 15 min at room temperature in BES buffer (50 mM N,N-Bis2hydroxyethyl-2-aminoethan sulfonic acid, 250 mM NaCl, 1.5 mM Na2HPO4, pH 6.95) containing 125 mM CaCl2 was added dropwise to the cell layers. The cell cultures were incubated for 3 h in DME supplemented with 5% modified bovine serum provided with the transfection kit, then rinsed and fed with DME/Ham's F12 medium. Selection for neoresistance to geneticin (400 µg/ml; Sigma-Aldrich) was started 48 h later.


Immunofluorescence Microscopy
Immunofluorescence analysis of subconfluent cell layers grown on glass coverslips and fixed in PBS, pH 7.4, containing 1 mM CaCl2, 1 mM MgCl2, and 3% formaldehyde were processed as reported (Gagnoux-Palacios et al. 1996 ). Semithin sections of frozen samples of organotypic cultures were fixed and analyzed as described (Rosdy et al. 1993 ). Cells monolayers and sections were analyzed using a ZEISS Axiophot microscope.


Immunoprecipitation and Immunoblotting Studies
Immunoblotting and immunoprecipitation analysis of the cell extracts and samples of culture medium were as already described (Gagnoux-Palacios et al. 1996 ). For Western analysis, the ECM was detached by scraping the plastic tissue culture dish in the presence of 2% SDS, 10% glycerol, 100 mM ß-mercaptoethanol, and 50 mM Tris-HCl, pH 6.8. The samples were boiled, electrophoresed in a 7.5% SDS-polyacrylamide gel, and blotted onto nylon filters. The antibody–antigen complex was revealed using the ECL Western blotting kit (Amersham Pharmacia Biotech).


Cell Detachment Assay
Cells (2 x 104/cm2) were seeded in tissue culture flasks and incubated for either 12 or 48 h at 37°C to reach 50 and 80% confluence, respectively. The monolayers were then treated with a solution of trypsin/EDTA (Versene and BioWhittaker) diluted 1:70 in PBS. The number of cells detached at increasing time of incubation was determined by collecting the supernatants and direct cell counting. Each experiment was repeated six times. A representative experiment is shown.


Quantification of Laminin 5 Deposited in the ECM by Cultured Keratinocytes
Laminin 5 deposition was quantified both on plastic cell culture substrate and on plastic coated with ECM components. To coat the plastic substrate, multiwell plates (96 wells; TPP) were incubated with solutions of collagen type I or IV, vitronectin, fibronectin, laminin 1, or ECM (all from Sigma-Aldrich) dissolved in PBS at a concentration of 10 µg/ml. 104 cells per well were seeded and incubated for either 12 or 48 h at 37°C in humidified atmosphere in the presence of 5% CO2. The cells were then washed twice in PBS and detached as devised by Delwel et al. 1993 . In brief, the cells were incubated overnight at 4°C in PBS containing 20 mM EDTA, leupeptin (10 µg/ml), aprotinin (10 µg/ml), phenylmethanesulfonyl fluoride (1 mM), and soybean trypsin inhibitor (10 µg/ml) and then dislodged by pipetting. The matrices were washed with PBS, incubated for 10 min with PBS-0.2% Triton X-100 to remove cell debris, and saturated for 1 h at room temperature in PBS-1% BSA. Each well was incubated for 2 h at room temperature in 50 µl PBS-1% BSA containing mAb GB3 (10 µg/ml). The plates were washed seven times with PBS and incubated for 1 h at room temperature with 50 µl of PBS-1% BSA containing 1 µg/ml of anti–mouse HRP mAb (Dako) per well. After extensive washing, 50 µl of a solution of 0-phenylenediaminedihydrochloride (Sigma-Aldrich) was added to each well for 10 min in the dark as devised by the supplier. Color yields were determined at 490 nm in an Elisa reader (Dynatech). Values were expressed as percentage of the values obtained with mutant L{gamma}NC cells.


Adhesion Assay
Multiwell plates containing the ECM secreted by the different mutant cell lines were prepared as described. Wells were saturated for 1 h at room temperature with a solution of 0.5% heat-denatured BSA. Wild-type HNKs (3 x 104 cells per well) were plated and fed with serum-deprived medium containing 0.25% heat-denatured BSA. After 1 h at 37°C, the medium and the cells in suspension were removed and the wells were washed with PBS. Adherent cells were fixed in 3.7% formaldehyde, stained with 0.5% crystal violet dissolved in 20% methanol, and washed three times in PBS. The dye was eluted with 50% ethanol/0.1 M sodium citrate, pH 4.2. Absorbance at 540 nm was determined using a microplated reader. Values were expressed as a percentage of the values obtained with mutant L{gamma}NC cells.


  Results
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

The functional role of the short arm domains of the laminin {gamma}2 chain was investigated by transfecting a series of mutant {gamma}2 cDNAs into keratinocyte cell line LSV5. Cell line LSV5 is derived from the keratinocytes of an H-JEB patient with a homozygous nonsense mutation (R95X) in the gene (LAMC2) coding for the laminin {gamma}2 chain (Miquel et al. 1996 ). LSV5 cells do not synthesize the laminin {gamma}2 chain, but express the full repertoire of the laminin chains found in HNKs, including the laminin {alpha}3 and ß3 chains (Miquel et al. 1996 ). Transfection of a wild-type {gamma}2 cDNA restores production of functional {alpha}3ß3{gamma}2 laminin 5 molecules (Gagnoux-Palacios et al. 1996 ). The complementary DNAs coding for mutant laminin {gamma}2 chains were generated by directed mutagenesis of the expression vector p{gamma}WT which encodes the full length {gamma}2 polypeptide (Gagnoux-Palacios et al. 1996 ). As depicted in Fig 1 B, the mutant cDNA p{gamma}NC expresses a recombinant {gamma}2 polypeptide with an internal deletion encompassing the four amino acids (YSGD) within domain III that constitute the proteolytic cleavage site of the {gamma}2 chain (Vailly et al. 1994 ; Amano et al. 2000 ). In mutant p{gamma}GP, the GlyPro residues substitute the YSGD cleavage site and introduce a structural modification from "sheet" to "coil" configuration of the {gamma}2 chain domain III. Mutants p{gamma}III and p{gamma}V carry a deletion affecting the egf-like repeat 1 of domain III and repeats 2 and 3 of domain V, respectively. To investigate the functional role of the laminin {gamma}2 chain short arm, we generated a cDNA clone encoding a polypeptide lacking the NH2-terminal domains IV and V that are excised in the extracellular processing of laminin 5 (plasmid p{gamma}C). Further, a polypeptide with an internal deletion encompassing the EGF-like repeat 1 of domain III and the COOH-terminal portion of domain IV (plasmid p{gamma}M) was also constructed. Plasmid p{gamma}M corresponds to a mutated {gamma}2 chain missing 73 amino acids of the polypeptide sequence detected in a patient suffering from JEB (Pulkkinen et al. 1994 ). The deletion was thought to interfere with the extracellular processing of the polypeptide (Amano et al. 2000 ).

The different mutant cDNAs were transiently transfected into actively growing LSV5 keratinocytes. Immunocytochemical analysis of the transfected cultures using pAb SE144 (not shown) and mAb GB3 indicated that all the mutant {gamma}2 polypeptides were actively synthesized and incorporated into laminin 5 heterotrimers (Fig 2). The ECM deposited on the culture support by cells L{gamma}WT, L{gamma}NC, L{gamma}{Delta}III, L{gamma}{Delta}V, and L{gamma}GP transfected with plasmids p{gamma}WT, p{gamma}NC, p{gamma}{Delta}III, p{gamma}{Delta}V, and p{gamma}GP was immunoreactive, whereas the ECM deposited by the cell cultures L{gamma}C and L{gamma}M transfected with plasmids p{gamma}C and p{gamma}M was not labeled. These results indicate that deletions within the globular domain IV of the {gamma}2 chain prevent secretion and/or deposition of laminin 5 into the ECM, but do not limit laminin 5 synthesis.




View larger version (95K):
[in this window]
[in a new window]
 
Figure 2. Immunofluorescence analysis of laminin 5 synthesis in LSV5 keratinocytes transiently transfected with plasmids encoding the mutant {gamma}2 chains. LSV5 untransfected (a and b) and transfected with p{gamma}WT (c and d), p{gamma}NC (e and f), p{gamma}C (g and h), p{gamma}GP (i and j), p{gamma}M (k and l), p{gamma}{Delta}III (m and n), and p{gamma}{Delta}V (o and p) were subjected to double immunofluorescence staining using mAb GB3 (a, c, e, g, i, k, m, and o) specific to native laminin 5 and phalloidin (b, d, f, h, j, l, n, and p) specific to the actin cytoskeleton. Laminin 5 expression is detected in the cytoplasm of all the transfected keratinocytes. With the exception of mutants p{gamma}C and p{gamma}M, all the {gamma}2 mutant cDNAs restore deposition of laminin 5 to the culture plastic support as attested by the extracellular staining (arrows). NT, not transfected. Bar, 20 µm.

To confirm the role of the globular domain of the {gamma}2 polypeptide in deposition of laminin 5 to the cell culture substratum, plasmids p{gamma}NC, p{gamma}GP, and p{gamma}C were stably transfected into LSV5 keratinocytes. Cell lines L{gamma}NC and L{gamma}GP were generated that are expected to secrete a mutated 440-kD form of laminin 5 with a full length {gamma}2 chain (155 kD), whereas cell line L{gamma}C is expected to produce a 400-kD molecule corresponding to laminin 5 with a processed {gamma}2 chain (105 kD). Consistent with the results obtained with transiently transfected LSV5 cells, immunocytochemical analysis of L{gamma}NC, L{gamma}GP, and L{gamma}C cells using pAb SE144 and mAb GB3 detected a strong cytoplasmic labeling in all cell lines. These experiments also confirmed that only the ECM laid down by L{gamma}NC and L{gamma}GP keratinocytes contains immunoreactive laminin 5 epitopes (not shown). These results indicate that presence of the {gamma}2 short arm is required for deposition of laminin 5 to the culture substratum, but do not rule out the possibility that laminin 5 harboring a {gamma}C recombinant chain is secreted into the media without being incorporated into ECM. Expression and secretion of the recombinant {gamma}NC, {gamma}GP, and {gamma}C polypeptides were examined by Western blot analysis of spent medium of L{gamma}NC, L{gamma}GP, and L{gamma}C cells. A unique 105-kD migration band was detected in the L{gamma}C medium using pAb SE144, whereas a specific 155-kD band was observed with L{gamma}NC and L{gamma}GP cells (Fig 3 A). The intensity of these bands was comparable and was estimated to be threefold weaker than the intensity of the corresponding bands detected in the medium conditioned by wild-type keratinocytes. Thus, although the {gamma}2 short arm is required for incorporation into the ECM, it is not needed for secretion of {gamma}2 chain.



View larger version (47K):
[in this window]
[in a new window]
 
Figure 3. Deposition to the culture substratum of mutant laminin 5 molecules is dependent on the nature of the {gamma}2 chain. (A) Western analysis of spent medium of cultured keratinocytes. 50 µg of proteins from spent medium collected from cultures of cell line HKSV (lane 1), LSV5 (lane 2), L{gamma}C (lane 3), L{gamma}NC (lane 4), and L{gamma}GP (lane 5) were fractionated by SDS-PAGE in a 7.5% polyacrylamide gel and transferred onto a nitrocellulose filter. The antigen–antibody complex was detected with the ECL kit (Amersham Pharmacia Biotech). Reaction with pAb SE144, specific to the COOH-terminal domains of the laminin {gamma}2 chain, identifies a 105-kD {gamma}2 polypeptide ({gamma}2') in L{gamma}C cells and a 155-kD band ({gamma}2) in L{gamma}NC and L{gamma}GP keratinocytes. These bands are absent in the parental LSV5 cells. Both bands are detected in the wild-type HKSV cells. The mass of the molecular markers is indicated in kD on the left of the gel. Exposure time was 5 min. (B) Immunoprecipitation analysis of radiolabeled medium (0.5 ml) conditioned by LSV5 (lanes 1 and 4), L{gamma}C (lanes 2 and 5), and L{gamma}NC (lanes 3 and 6) cells using mAb K140 specific to the laminin ß3 chain (lanes 1, 2, and 3) and mAb T7 directed against the T7-Tag (lanes 4, 5, and 6). The 155- and 105-kD {gamma}2 mutant proteins associate with the endogenous {alpha}3 (165 kD) and ß3 (140 kD) laminin 5 chains to yield the laminin 5 forms of 400 (lanes 2 and 5) and 440 kD (lanes 3 and 6). SDS-PAGE was performed in a 7.5% polyacrylamide gel. Exposure was 12 h on an x-ray film (Amersham Pharmacia Biotech). (C) Deposition of mutant laminin 5 by reconstructed epithelia. LSV5 (a), L{gamma}NC (b), L{gamma}C (c), and HKSV (d) keratinocytes were seeded on a cellulose acetate filter. At confluence the cultures were lifted at the air–medium interface and allowed to stratify for 4 d. Frozen sections were then reacted with mAb GB3. Immunoreactive laminin 5 is detected at the interface between the epithelia generated by L{gamma}NC and HKSV and the filter substratum. No immunoreactivity is detected with LSV5 and L{gamma}C cells. Bar, 50 µm.

Incorporation of the recombinant {gamma}2 polypeptides into extracellular laminin 5 molecules was further verified by immunoprecipitation of L{gamma}C and L{gamma}NC cell culture medium using the mAb K140 and the anti–T7-Tag mAb. As shown in Fig 3 B, comparable amounts of 400- and 440-kD laminin 5 molecules were immunoprecipitated from the L{gamma}NC and L{gamma}C cell medium, respectively, which attests to the assembly of the 105- and 155-kD recombinant {gamma}2 polypeptides into laminin 5. These data demonstrate that the absence of the {gamma}2 NH2-terminal domains does not hinder the intracellular processing of laminin 5 and its secretion into the culture medium. They also confirm that the tetrapeptide YSGD is the unique physiological cleavage site of the extracellular processing of the {gamma}2 chain.

Artificial epithelia constructed either with HNKs or LSV5 cells expressing a recombinant wild-type {gamma}2 chain have been shown previously to lay down laminin 5 at the interface between the basal cells and the cell culture support (Rosdy et al. 1993 ; Gagnoux-Palacios et al. 1996 ; Miquel et al. 1996 ). Because truncation of the {gamma}2 short arm appeared to prevent deposition of laminin 5 on monolayer submersed cultures, L{gamma}C and L{gamma}NC keratinocytes were grown to confluence on cellulose acetate filters and exposed to air to obtain stratification into multilayered epithelia. Immunofluorescence analysis of the artificial epithelia using mAb GB3 detected a strong reactivity in the case of L{gamma}NC and HKSV cells (Fig 3 C, b and d), and no reactivity with LSV5 and L{gamma}C keratinocytes (Fig 3 C, a and c). Therefore, these observations confirm that the 400-kD form of laminin 5 produced by L{gamma}C keratinocytes is not incorporated into the ECM, and underscore the importance of the {gamma}2 short arm plays in the deposition of laminin 5 at the epithelial–ECM interface.

Because our results suggested that the laminin {gamma}2 short arm is essential for the incorporation of laminin 5 into the ECM secreted by LSV keratinocytes, we verified whether human skin and the matrix secreted by wild-type keratinocytes contain the NH2-terminal {gamma}2 polypeptide generated by the extracellular processing of the 440-kD laminin 5. Specific antiserum pAb SE1097 was generated against recombinant fragment {gamma}50, which is cleaved from the short arm of the {gamma}2 chain (Fig 1 B). The antibody stained the human epidermal basement membrane in a strong linear fashion (Fig 4A and Fig B), comparable to the labeling observed with antibody SE144 (not shown). Samples of the ECM produced by cultures of wild-type keratinocytes were then collected from culture dishes and analyzed by immunoblotting using pAb SE144 and pAb SE1097. As shown in Fig 4 C, pAb SE144 recognized the 155- and 105-kD migration bands corresponding to the unprocessed and processed {gamma}2 polypeptide, respectively. pAb SE1097 identified the unprocessed 155-kD {gamma}2 chain and an additional fast-migrating band with the expected mass (50 kD) of the NH2-terminal domains, which are extracellularly excised from the {gamma}2 chain (Fig 4 D). The finding that only unprocessed {gamma}2 chain is found intracellularly and that the processed {gamma}2 chain and its cleavage fragment are found in the ECM indicate that the 440-kD laminin 5 molecules are proteolytically cleaved into the 400-kD form after incorporation into the ECM. This strengthens the idea that the {gamma}2 short arm plays a role in the integration of laminin 5 in the matrix.



View larger version (40K):
[in this window]
[in a new window]
 
Figure 4. Laminin {gamma}2 short arm drives deposition of laminin 5 to the ECM. Immunofluorescence analysis of control (A) and split skin (B) using pAb SE1097. The strong linear staining indicates that the 440-kD form of laminin 5 and/or the NH2-terminal cleaved {gamma}2 polypeptide are present in human basement membrane. Medium: 50 µg of ECM (lane 1), proteins of spent medium (lane 2), and total cellular extracts (lane 3) obtained from cultures of normal HNKs were analyzed by immunoblotting using pAb SE144 directed against the COOH-terminal domains of the laminin {gamma}2 chain (C), and pAb SE1097, specific to the NH2-terminal domains IV and V of the {gamma}2 short arm (D). The mass of molecular markers is indicated on the left of the gels. (C) In the ECM the migration positions of the laminin {gamma}2 polypeptides show the major presence of the cleaved form of the laminin 5 {gamma}2 chain in comparison to the noncleaved form. (D) Reaction with pAb SE1097 reveals the presence of the 50-kD product of proteolytic cleavage of the {gamma}2 chain in the matrix and in the spent medium. (E) Immunofluorescence analysis of HKSV keratinocytes expressing the recombinant short arms of the laminin chains {gamma}2 (p{gamma}50; a and b) and ß3 (pß60; c and d). Double immunofluorescence labeling performed using either mAb T7 (a) or mAb anti-HA (c) and phalloidin (b and d) demonstrates that the recombinant {gamma}2 short arm is deposited into the ECM (E), whereas the recombinant ß3 short arm is not detected in the ECM (G). Bars: (A) 50 µm; (E, d) 20 µm.

To verify this hypothesis, wild-type keratinocytes were transfected with the construct p{gamma}50 encoding the NH2-terminal domains IV and V of {gamma}2 carrying a T7-Tag peptide (Fig 1). Control cultures were transfected with an expression vector (pß60) that encodes the NH2-terminal domains III, V, and VI of the laminin ß3 chain tagged with the HA epitope (Fig 1). As shown by immunofluorescence microscopy, mAb T7-Tag reacted with the cytoplasm of the keratinocytes transfected with plasmid p{gamma}50 and labeled the ECM deposited by these cells (Fig 4 E, a and b). Conversely, the anti-HA mAb stained the cytoplasm of the keratinocytes expressing the recombinant cDNA pß60, but not the ECM they deposited (Fig 4 E, c and d). Similar results were obtained by transfection experiments performed using LSV5 cells (not shown). These observations suggest that the short arm of the laminin {gamma}2 chain carries domains essential to the incorporation of laminin 5 into the matrix.

It has been suggested that the globular domain IV of the mouse laminin {gamma}2 chain binds to the ECM protein fibulin 2 (Utani et al. 1997 ). However, residue Phe-202 of the {gamma}2 amino acid sequence, which is essential to the interaction, is not conserved in humans. In addition, we were unable to demonstrate interactions between human laminin 5 and fibulin 2 in our experimental conditions (data not shown). Intriguingly, the amino acid sequence of the NH2-terminal region of the {gamma}2 domain IV is highly conserved in mammals (Table 2), which may reflect a relevant physiological role of this portion of the polypeptide. Indeed, it was suggested that disruption of the fibulin 2 binding site could hamper the proteolytic processing of {gamma}2 (Utani et al. 1997 ). Therefore, we constructed plasmids p{gamma}F1 and p{gamma}F2 that encode {gamma}2 polypeptides in which the amino acid sequence SADFSVHKI (residues 199–207) homologous to the active site of the mouse fibulin 2 binding site was partially (p{gamma}F1) and totally (p{gamma}F2) substituted by alanine residues (Fig 1). LSV5 keratinocytes transfected with constructs p{gamma}F1 and p{gamma}F2 were examined by immunofluorescence analysis using mAb GB3. Expression of the mutant laminin 5 molecules resulted in a strong staining of the cytoplasm, and also of the ECM deposited onto the tissue culture support (Fig 5 A, a and c). Western blot analysis of medium collected from cultures of L{gamma}F2 keratinocytes using pAb SE144 detected hybridization bands corresponding to the uncleaved (155 kD) and the proteolytically cleaved (105 kD) p{gamma}F2 chain (Fig 5 B). According to these observations, immunofluorescence examination of frozen sections of artificial epithelia constructed using L{gamma}F1 and L{gamma}F2 keratinocytes detected a strong reactivity of the basement membrane zone to mAb GB3 (Fig 5 C, a and b). These results attest to the incorporation of the mutant laminin 5 molecules into the ECM deposited on the cell culture substrate and show that disruption of the region homologous to the putative fibulin 2 binding site of the mouse {gamma}2 short arm does not interfere with the processing and deposition of laminin 5 to the matrix.



View larger version (33K):
[in this window]
[in a new window]
 
Figure 5. Secretion and deposition on the ECM of mutants L{gamma}F1 and L{gamma}F2 laminin 5 molecules. (A) Immunofluorescence staining of LSV5 keratinocytes transiently transfected with plasmids p{gamma}F1 (a and b) and p{gamma}F2 (c and d). Double immunofluorescence labeling was performed using mAb GB3 (a and c), specific to native laminin 5 and phalloidin (b and d). (B) Western analysis of spent medium of L{gamma}F2 keratinocytes. 50 µg of proteins from spent medium collected from cultures of L{gamma}F2 (lane 1), LSV5 (lane 2), and HKSV (lane 3) were loaded on a 7.5% SDS-polyacrylamide gel, transferred onto nitrocellulose filter, and reacted with pAb SE144. The mass of molecular markers is indicated on the left of the gel. Exposure time was 5 min. (C) Immunofluorescence analysis of artificial epithelia generated using L{gamma}F1 (a) and L{gamma}F2 (b) keratinocytes. The substitution of the fibulin 2 binding site of the {gamma}2 short arm does not prevent deposition of the mutant laminin 5 to the epithelial–ECM interface. Bars, 50 µm.


 
View this table:
[in this window]
[in a new window]
 
Table 2. Alignment of the Laminin {gamma}2 cDNA Sequences Homologous to the Active Site of Fibulin 2 Binding in the Mouse

Reexpression of wild-type laminin 5 restores adhesion of LSV5 cells and H-JEB keratinocytes (Gagnoux-Palacios et al. 1996 ; Vailly et al. 1998 ). Because the 400-kD molecules of laminin 5 produced by L{gamma}C keratinocytes are not deposited into the ECM, L{gamma}C cells are expected to retain the poor adhesion capacity of the parental cell line LSV5. Indeed, epidermal sheets of stratified epithelium generated by confluent cultures of L{gamma}C, L{gamma}GP, and L{gamma}F1 keratinocytes spontaneously detached from the culture vessel. In contrast, when L{gamma}NC keratinocytes became confluent and stratified, the epidermal sheet firmly adhered to the plastic dish and detachment required enzymatic treatment (not shown). Therefore, attachment of L{gamma}C keratinocytes was quantified in detachment kinetic assays in the presence of trypsin/EDTA (Vailly et al. 1998 ). The attachment capacity of L{gamma}NC keratinocytes was also compared with that of wild-type keratinocytes. Cell suspensions were seeded on petri dishes to obtain exponentially growing cultures. 12 h after plating, the percentage of the adhering L{gamma}NC and L{gamma}C cells was similar to that of parental LSV5 cells (Fig 6 A). Although the number of L{gamma}NC and L{gamma}WT cells resistant to trypsinization increased 48 h after seeding (50% of L{gamma}NC cells were dislodged after 14 min), that of L{gamma}C and LSV5 cells remained low (50% of dislodged cells after 8 min; Fig 6 B). Therefore, the progressive enhancement of adhesion of L{gamma}NC and L{gamma}WT keratinocytes appeared to correlate with accumulation of laminin 5 molecules harboring the {gamma}2 short arm in the matrix. Detachment of L{gamma}GP and L{gamma}F1 keratinocytes was also assessed in similar experimental conditions. As demonstrated in Fig 6 B, in all these cells other than L{gamma}NC synthesis of mutated laminin 5 molecules had no appreciable effect on the strength of cell adhesion.



View larger version (30K):
[in this window]
[in a new window]
 
Figure 6. Detachment assay of keratinocytes expressing mutant laminin 5 and quantification of laminin 5 layered down to the culture substrate. For the detachment assay, cells (2 x 104/cm2) were seeded on a plastic cell culture vessel, left to adhere for 12 h (A) and 48 h (B), and then treated with a solution of trypsin/EDTA (Versene) diluted in PBS (1:70). The number of cells detached at the indicated time of trypsinization was determined by direct cell counting. Results were confirmed in six independent experiments. Results of one experiment are shown. (C) To quantify deposition of laminin 5, 104 cells per well were seeded in multiwell plates, allowed to adhere for 12 h (A) and 48 h (B), and detached as detailed in Materials and Methods. Quantification of the laminin 5 deposited on the plate was determined by ELISA using mAb GB3. Values represent the average of triplicates and represent the mean ± SD. The amount of laminin 5 layered down by L{gamma}NC cells was arbitrarily assumed as the 100% value.

To confirm that resistance to trypsinization of L{gamma}NC cells correlates with laminin 5 incorporation in the ECM, the amount of laminin 5 layered down by the different {gamma}2 mutant keratinocytes was determined by ELISA assay using mAb GB3. As shown in Fig 6 C, laminin 5 produced by L{gamma}NC cells was efficiently deposited on the plastic culture substrate and accumulated with increasing time, whereas mutant {gamma}C laminin 5 was inefficiently layered down. L{gamma}WT, L{gamma}GP, or L{gamma}F1 cells layered down comparable amounts of laminin 5. In addition, by seeding the mutant keratinocytes in a plastic vessel coated with different components of the ECM, we assessed the deposition rate of the wild-type and mutant laminin 5 molecules to be independent from the nature of the cell culture substrate on which the keratinocytes are grown (Fig 7). Plating on a feeder of irradiated mouse 3T3-J2 cells did not modify the deposition pattern of laminin 5 (not shown).



View larger version (35K):
[in this window]
[in a new window]
 
Figure 7. Deposition of mutant laminin 5 is not affected by the cell culture substrate. LSV5 keratinocytes expressing mutant laminin 5 (104 cells per well) were seeded in 96-multiwell plates coated with 10 µg/ml of collagen type I (coll I), collagen type IV (coll IV), vitronectin, fibronectin (FN), and laminin-1 (lam-1), and incubated for 48 h at 37°C in humidified atmosphere saturated with CO2. Cells were mechanically detached and the amount of laminin 5 deposited in each well was evaluated by ELISA performed with mAb GB3. Values represent the average of triplicates and represent the mean ± SD. Laminin 5 deposition by L{gamma}NC was assigned a value of 100%.

Because the trypsinization assay provides information on the effect of laminin 5 on the strength of cell attachment, the functional role of the laminin {gamma}2 short arm in cell adhesion was further assessed by seeding wild-type primary human keratinocytes on the ECM deposited by the different LSV5 {gamma}2 mutants. The mutant cells were seeded in a range of concentrations leading to deposition of equivalent amounts of laminin 5 48 h after plating. The ECM was prepared after detachment of the cells by EDTA treatment, and concentration of laminin 5 in the ECM was checked by ELISA assays using mAb GB3. Primary wild-type keratinocytes were then seeded and allowed to adhere for 60 min at 37°C. Results show that adhesion of keratinocytes on the matrix secreted by L{gamma}NC and L{gamma}WT cells was comparable, whereas adhesion on the matrix produced by L{gamma}C cells was strongly reduced and equivalent to the values obtained with matrix produced by the {gamma}2-null LSV5 cells (Fig 8). Adhesion on the matrix produced by the L{gamma}F1 and L{gamma}GP mutant cells was also reduced to a lesser extent. This result suggests that deposition of these laminin 5 molecules allows interaction of their COOH-terminal G domain with the adhesive integrin receptors at the cell surface, although participation of other cell receptors in adhesion cannot be excluded. However, the cell detachment assay shows that the adhesion strength of mutant L{gamma}F1 and L{gamma}GP cells is affected, which may reflect a lower binding capacity between laminin 5 secreted by these cells and the culture substrate (Fig 7 B).



View larger version (12K):
[in this window]
[in a new window]
 
Figure 8. The unprocessed form of laminin 5 promotes cell adhesion. Wild-type keratinocytes (NHK) were seeded on ECM secreted by LSV5 cell expressing laminin 5 harboring the mutant {gamma}2 chains. Cell were left to adhere for 1 h at 37°C. Cell adhesion was measured using the colorimetric reaction described in Materials and Methods. The ECM deposited by L{gamma}Wt, L{gamma}NC significantly increased adhesion of NHKs compared with the ECM produced by laminin 5–null LSV5 cells. The matrix secreted by L{gamma}F2 and L{gamma}GP keratinocytes also enhanced adhesion. Each point is the average of triplicates from three independent experiments and represents the mean ± SD of the optical density values. Values obtained with L{gamma}NC cells were taken as 100%.

Because keratinocyte adhesion was measured on a matrix produced by the different LSV mutant cells, we could not determine whether the adhesive effect we observed was directly or indirectly sustained by laminin 5. Nevertheless, our observations demonstrate that the laminin 5 molecules harboring an unprocessed {gamma}2 chain are biologically active and indicate that structural changes in the NH2-terminal region of the globular domain IV affect the biological function of laminin 5.


  Discussion
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

Transfection of a wild-type laminin {gamma}2 cDNA in LSV5 keratinocytes rescues expression of functional laminin 5 molecules (Gagnoux-Palacios et al. 1996 ). Similar to laminin 5 produced by wild-type keratinocytes, the recombinant laminin 5 secreted by the reverted LSV5 cells undergoes extracellular maturation, including proteolytic excision of the NH2-terminal domains of the {gamma}2 short arm. In this study, we examined the functional role of the laminin {gamma}2 short arm by complementing the genetic defect of LSV5 cells by transfer of mutant {gamma}2 cDNAs. Expression of the mutant cDNAs demonstrated that all the different recombinant {gamma}2 chains associate with the endogenous laminin {alpha}3 and ß3 polypeptides to assemble into {alpha}3ß3{gamma}2 heterotrimers, and that the NH2-terminal domains of the {gamma}2 chain are required for deposition and incorporation of laminin 5 in the ECM.

Our results, for the first time, define a physiologic function for the short arm of the {gamma}2 chain. We demonstrate that mutant laminin 5 molecules lacking the {gamma}2 chain NH2-terminal sequences that are excised in the extracellular processing are found in the spent media of L{gamma}C cells, but are not layered on the cell culture substrate. Specifically, deposition of laminin 5 in the ECM produced by the LSV5 keratinocytes requires integrity of the {gamma}2 globular domain IV, whereas preservation of the tightly folded structure of the EGF-like rich domains III and V is not essential. Indeed, transfection of LSV5 cells with {gamma}2 cDNA mutants carrying a deletion within the EGF-like repeats of either domain III or V results in deposition of laminin 5. Consistent with these observations, laminin 5 molecules carrying a deletion of the {gamma}2 domain V EGF-like repeat 2 has been found in the dermal–epidermal junction of a patient with mild epidermolysis bullosa consequent to in-frame skipping of LAMC2 exon 4 (Castiglia, D., P. Posteraro, M. Pinola, C. Angelo, P. Puddu, and A. Zambruno, manuscript submitted for publication). Therefore, removal of EGF-like repeats weakens the functionality of laminin 5, but may not prevent the polarized secretion and deposition of the protein to the basement membrane. Conversely, transfection of mutant p{gamma}M, in which the deleted fragment encompasses the {gamma}2 domains III and IV, results in lack of deposition of laminin 5 that correlates well with the epidermolysis bullosa phenotype of the patient carrying this mutation (Pulkkinen et al. 1994 ). We did not assess whether absent deposition of the mutant {gamma}M chain was consequent to lack of secretion. Conversely, by deletion of the proteolytic cleavage site YSGD of the {gamma}2 polypeptide, we show that laminin 5 with an unprocessed {gamma}2 chain (mutant plasmid p{gamma}NC) is efficiently layered down and enhances adhesion of LSV5 and wild-type keratinocytes. These finding imply that the extracellular 440-kD form of laminin 5 is an active adhesion ligand and not a mere precursor of the processed 44-kD form.

Basement membrane components are coordinately deposited in the ECM and subsequently assemble to form a supramolecular network sustaining multiple functions, including cell adhesion (Colognato and Yurchenco 2000 and references therein). It has been shown that laminin 5 is one of the first basement membrane components laid down by migrating keratinocytes (Rousselle et al. 1991 ; Ryan et al. 1994 ; Lampe et al. 1998 ). However, the intermolecular interactions of laminin 5 in the basement membrane remain poorly understood. Laminin 5 binds the NC-1 domain of collagen type VII (Cheng et al. 1997 ; Rousselle et al. 1997 ) and is found associated with laminin 6 in the skin and laminin 7 in amnion (Rousselle et al. 1991 ; Gerecke et al. 1994 ; Champliaud et al. 1996 ). Utani et al. 1997 have proposed that the ECM component fibulin 2 interacts with the short arm of the mouse {gamma}2 chain. Apart from Phe-202, which is required for the full binding activity of the mouse {gamma}2 chain, the remaining active residues of the consensus sequence mediating interaction between the laminin {gamma}2 chain and fibulin 2 are conserved in humans and other mammals (Table 2). We could not demonstrate a direct interaction between the {gamma}2 chain and fibulin 2 in human keratinocytes. In addition, our results show that in mutants {gamma}F1 and {gamma}F2, substitution of the putative fibulin 2 binding site with alanine residues that modify the nH2-terminal region of the {gamma}2 short arm domain IV does not affect the cleavage of the {gamma}2 chain and deposition of laminin 5. This argues against the participation of this region of the {gamma}2 globular domain IV in the extracellular processing of the {gamma}2 polypeptide (Utani et al. 1997 ). However, the adhesive function of laminin 5 harboring the mutant {gamma}F1 or the {gamma}F2 chain is diminished, as attested by the weak resistance to trypsinization of the cells expressing these molecules. The relevance of the {gamma}2 short arm in cell adhesion is confirmed by the fact that substitution of the YSGD site with the amino acids GlyPro, where the proline residue modifies the orientation on the plane of the NH2-terminal domains, also results in efficient deposition of 440-kD laminin 5 molecules exerting a reduced adhesive function. Although further investigations at the molecular level are needed to clarify the mechanisms underlying these observations, it is likely that integrity of the globular domain IV and the correct orientation of the {gamma}2 NH2 terminus determine the appropriate arrangement of laminin 5 in the ECM produced by LSV5 cells and contribute the functional activity of this adhesion ligand.

Laminin 5 purified from mouse epidermis is a mixture of molecules harboring a cleaved (105 kD) or an uncleaved (155 kD) {gamma}2 chain (Aberdam et al. 1994b ). In organ-cultured bovine skin, conversion of the 155-kD {gamma}2 chain to 105 kD was not observed, whereas laminin 5 isolated from amnion was found to contain the 105-kD {gamma}2 chain only (Marinkovich et al. 1992 ). It has been suggested that the proteolytic truncation of the {gamma}2 short arm may facilitate the interaction between the ß3 short arm of laminin 5 and other basement membrane components, such as laminins 6 and 7 and collagen type VII, and consequently may activate the adhesion function of laminin 5 (Amano et al. 2000 ). This hypothesis is not verified in our system, because the mutant laminin 5 molecules harboring a fully processed {gamma}2 short arm are secreted in the culture medium, but are not found in the matrix produced by LSV5 cells. Conversely, we demonstrate that the progressive accumulation of the 440-kD form of laminin 5 on tissue culture plastic and the dermal equivalent of organotypic cultures enhances adhesion of LSV5 cells. Our data confirm previous observations showing that a threshold level of laminin 5 accumulation is required for efficient cell adhesion (Hormia et al. 1995 ; Gagnoux-Palacios et al. 1996 ). They also indicate that cell adhesion mediated by laminin 5 is independent of the extracellular processing of the {gamma}2 chain. However, these results do not argue against a role of the processed 400-kD form of laminin 5 in cell adhesion. Proteolysis of the {gamma}2 chain, which may occur after interaction of laminin 5 with laminins 6 and 7 or collagen type VII, could trigger additional or distinct adhesion functions to laminin 5.

Proteolysis regulates ECM assembly, editing the excess ECM components and release of active polypeptides during morphogenesis, growth, tissue repair, and pathological processes (for review see Werb 1997 ). Proteinases negatively regulate the function of a variety of ECM components and cell surface receptors. It has recently been reported that collagen XVII, a transmembrane component of the hemidesmosomes that contributes to formation of the anchoring filaments, undergoes furin-mediated proteolysis resulting in excision of the large extracellular collagenic domain (Hirako et al. 1998 ). Integrin ß4 also undergoes a proteolytic processing resulting in the cleavage of the cytoplasmic and extracellular domains, probably mediated by calpain and matrilysin (Giancotti et al. 1992 ; Potts et al. 1994 ; von Bredow et al. 1997 ). Therefore, proteolysis of the major components of the anchoring filaments may constitute an effective and rapid mechanism for regulating keratinocyte anchorage. The conversion of laminin 5 into a freely shedding product may thus account for the abundance of processed laminin 5 in spent medium of keratinocyte cell cultures and in body fluids (amniotic, cerebrospinal, and inner ear fluids; Aberdam et al. 1994b ).

Proteolytic digestion of the laminin {gamma}2 chain by BMP1 at the physiologic YSGD cleavage site has recently been demonstrated in vitro (Amano et al. 2000 ). Evidence has also been provided that the 155-kD laminin {gamma}2 chain is cleaved in vitro by the matrix metalloprotease (MMP) MT1-MMP to yield the shortened 105-kD {gamma}2 polypeptide and a 80-kD {gamma}2 chain with a further truncated NH2 terminus (Koshikawa et al. 2000 ). This observation implies two MT1-MMP cleavage sites on laminin 5. The 80-kD {gamma}2 chain is not found in skin extracts and in cultures of human keratinocytes, whereas the 105-kD {gamma}2 polypeptide and the excised 50-kD NH2-terminal domain are easily detectable. In this study we demonstrate that the {gamma}2 chains missing the tetrapeptide YSGD do not undergo proteolytic steps, which confirms in vitro studies and suggests the involvement of BMP-1 in the processing of laminin 5 at this cleavage site (Amano et al. 2000 ). On the other hand, although BMP-1–null mice display an ultrastructurally altered cutaneous basement membrane, they do not suffer from epithelial adhesion defects (Suzuki et al. 1996 ). This may indicate either that the extracellular cleavage of the {gamma}2 chain is not essential to keratinocyte adhesion, or that other proteases, including MT1-MMP, can compensate for the absence of BMP-1 in the extracellular processing of the laminin {gamma}2 chain. Indeed, cleavage of the laminin {gamma}2 chain by MT1-MMP has been associated with the migratory behavior of a variety of transformed epithelial cell lines, and inhibition of MT1-MMP partially downregulates cell migration induced by laminin 5 in tumoral cells. Therefore, MT1-MMP may cleave the {gamma}2 short arm and release the interaction between laminin 5 and the ECM components. Since the proteases of the MMPs family are involved in tissue remodeling in various physiological and pathological conditions, it is tempting to speculate that MT1-MMP cleaves laminin 5 and activates cell migration in pathologic circumstances, whereas BMP-1 governs proteolysis of laminin 5 in a physiologic context.

Several proteolytic fragments of ECM proteins maintain a biological function (Sage 1997 ). A pentapeptide generated by proteolysis of collagen type I is known to regulate transcription of the col1A1 gene (Katayama et al. 1993 ), and proliferation of endothelial cells induced by specific growth factors is inhibited by the 16-kD prolactin cleavage fragment (D'Angelo et al. 1995 ). Laminin {gamma}2 chain and its proteolytic fragments are found at the invasion front of tumors, where they may play positive roles in neoplastic invasion (Pyke et al. 1994 , Pyke et al. 1995 ; Koshikawa et al. 1999 ). Monomeric laminin {gamma}2 chain is also secreted by carcinoma cells in vitro, but the biological relevance of these observations is unclear (Koshikawa et al. 1999 ; Maatta et al. 1999 ; Ono et al. 1999 ). After proteolytic processing, the {gamma}2 chain short arm is detected in the epithelial basement membrane and in the matrix produced in vitro by normal keratinocytes. Deposition of the recombinant {gamma}2 short arm ({gamma}50) in ECM by cultured keratinocytes confirms the adhesive potential of the polypeptide. Therefore, it is possible that after cleavage from laminin 5 the {gamma}2 short arm sustains interactions with specific basement membranes components and cell receptors and participates in basement membrane assembly. In this regard it has been reported that keratinocyte-specific knock-out of mouse integrin ß1 results in disorganization of the cutaneous basement membrane and induces skin blistering that correlates with a reduced immunoreactivity and an altered staining pattern of a pAb antibody directed against the {gamma}2 short arm (Brakebush et al. 2000 ).

Laminin 5 promotes adhesion, migration, and scattering of several types of cultured cells more efficiently than all the other ECM proteins. We demonstrate that the extracellular deposition of laminin 5 is mediated by the short arm of the {gamma}2 chain that then steers intermolecular interactions with the basement membrane components and promotes cell adhesion. The functional role of the proteolytic processing of the laminin {gamma}2 chain in the formation of the epithelial basement membranes remains unclear. The construction of knock-in mice expressing either a mutant {gamma}NC or a truncated {gamma}C chain will clarify the specific biological functions of the extracellular forms of laminin 5.


  Footnotes

1 Abbreviations used in this paper: ECM, extracellular matrix; HA, hemagglutinin; JEB, junctional epidermolysis bullosa; MMP, matrix metalloprotease; pAb, polyclonal antibody.


  Acknowledgements
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

We acknowledge A. Spadafora for technical assistance, A. Mastrogiacomo for the protein structural analyses, and A. Charlesworth for critical reading of the manuscript.

This work was supported by grants from EEC BIOMED 2 (BMH4-97-2062), the Programme Hospitalier de Recherche Clinique (France), the DEBRA Foundation (UK), and the Association Francaise contre les Myopathies (Crowthorne, Evry, France).

Submitted: 26 February 2001
Revised: 30 March 2001
Accepted: 30 March 2001


  References
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
Acknowledgements
References

  1. Amano, S., Scott, I.C., Takahara, K., Koch, M., Gerecke, D.R., Keene, D.R., Hudson, D.L., Nishiyama, T., Lee, S., Greenspan, D.S., and Burgeson, R.E. 2000. Bone morphogenetic protein 1 (BMP-1) is an extracellular processing enzyme of the laminin 5 gamma2 chain. J. Biol. Chem. 275:22728-22735[Abstract/Free Full Text].

  2. Baker, S.E., Hopkinson, S.B., Fitchmun, M., Andreason, G.L., Frasier, F., Plopper, G., Quaranta, V., and Jones, J.C.R. 1996. Laminin 5 and hemidesmosomes: role of the {alpha}3 chain subunit in hemidesmosome stability and assembly. J. Cell Sci. 109:2509-2520[Abstract/Free Full Text].

  3. Brakebush, C., Grose, R., Quondamatteo, F., Ramirez, A., Jorcano, J.L., Pirro, A., Svenson, M., Herken, R., Sasaki, T., Topl, R., Werner, S., and Fässel, R. 2000. Skin and air follicle integrity is crucially dependent on ß1 integrin expression on keratinocytes. EMBO (Eur. Mol. Biol. Organ.) J. 19:3990-4003[Abstract/Free Full Text].

  4. Champliaud, M.F., Lunstrum, G.P., Rousselle, P., Nishiyama, T., Keene, D.R., and Burgeson, R.E. 1996. Human amnion contains a novel laminin variant, laminin 7, which like laminin 6, covalently associates with laminin 5 to promote stable epithelial–stromal attachment. J. Cell Biol. 132:1189-1198[Abstract].

  5. Chen, M., Marinkovich, M.P., Veis, A., Cai, X., Rao, C.N., O'Toole, E.A., and Woodley, D.T. 1997. Interactions of the amino-terminal noncollagenous (NC1) domain of type VII collagen with extracellular matrix components. A potential role in epidermal-dermal adherence in human skin. J. Biol. Chem. 272:14516-14522[Abstract/Free Full Text].

  6. Chen, M., Marinkovich, M.P., Jones, J.C.R., O'Toole, E.A., Li, Y.-Y., and Woodley, D.T. 1999. NC1 domain of type VII collagen binds to the ß3 chain of laminin 5 via a unique subdomain within the fibronectin-like repeats. J. Invest. Dermatol. 112:177-183[Abstract/Free Full Text].

  7. Cheng, Y.S., Champliaud, M.F., Burgeson, R.E., Marinkovich, M.P., and Yurchenco, P.D. 1997. Self-assembly of laminin isoforms. J. Biol. Chem. 272:31525-31532[Abstract/Free Full Text].

  8. D'Angelo, G., Struman, I., Martial, J., and Weiner, R.I. 1995. Activation of mitogen-activated protein kinases by vascular endothelial growth factor and basic fibroblast growth factor in capillary endothelial cells is inhibited by the antiangiogenic factor 16-kDa N-terminal fragment of prolactin. Proc. Natl. Acad. Sci. USA 92:6374-6378[Abstract].

  9. Delwel, G.O., Hogervorst, F., Kuikman, I., Paulsson, M., Timpl, R., and Sonnenberg, A. 1993. Expression and function of the cytoplasmic variants of the integrin alpha 6 subunit in transfected K562 cells. Activation-dependent adhesion and interaction with isoforms of laminin. J. Biol. Chem. 26:25865-25875.

  10. DiPersio, C.M., Hodivala-Dilke, K.M., Jaenisch, R., Kreidberg, J.A., and Hynes, R.O. 1997. {alpha}3ß1 integrin is required for normal development of the epidermal basement membrane. J. Cell Biol. 137:729-742[Abstract/Free Full Text].

  11. Gagnoux-Palacios, L., Vailly, J., Durand-Clement, M., Wagner, E., Ortonne, J.P., and Meneguzzi, G. 1996. Functional re-expression of laminin 5 in laminin-{gamma}2 deficient human keratinocytes modifies cell morphology, motility, and adhesion. J. Biol. Chem. 271:18437-18444[Abstract/Free Full Text].

  12. Gerecke, D.R., Wagman, D.W., Champliaud, M.F., and Burgeson, R.E. 1994. The complete primary structure for a novel laminin chain, the laminin B1k chain. J. Biol. Chem. 269:11073-11080[Abstract/Free Full Text].

  13. Giancotti, F.G., Stepp, M.A., Suzuki, S., Engvall, E., and Ruoslahti, E. 1992. Proteolytic processing of endogenous and recombinant ß4 integrin subunit. J. Cell Biol. 118:951-959[Abstract].

  14. Giannelli, G., Falk-Marzillier, J., Schiraldi, O., Stetler-Stevenson, W.G., and Quaranta, V. 1997. Induction of cell migration by matrix metalloprotease-2 cleavage of laminin 5. Science 277:225-228[Abstract/Free Full Text].

  15. Goldfinger, L.E., Stack, M.S., and Jones, J.C. 1998. Processing of laminin 5 and its functional consequences: role of plasmin and tissue-type plasminogen activator. J. Cell Biol. 141:255-265[Abstract/Free Full Text].

  16. Hirako, Y., Usukura, J., Uematsu, J., Hashimoto, T., Kitajima, Y., and Owaribe, K. 1998. Cleavage of BP180, a 180-kDa bullous pemphigoid antigen, yields a 120-kDa collagenous extracellular polypeptide. J. Biol. Chem. 273:9711-9717[Abstract/Free Full Text].

  17. Hirosaki, T., Mizushima, H., Tsubota, Y., Moriyama, K., and Miyazaki, K. 2000. Structural requirement of carboxyl-terminal globular domains of laminin alpha 3 chain for promotion of rapid cell adhesion and migration by laminin 5. J. Biol. Chem. 275:22495-22502[Abstract/Free Full Text].

  18. Hormia, M., Falk-Marzillier, J., Plopper, G., Tamura, R.N., Jones, J.C., and Quaranta, V. 1995. Rapid spreading and mature hemidesmosome formation in HaCaT keratinocytes induced by incubation with soluble laminin 5r. J. Invest. Dermatol. 105:557-561[Abstract].

  19. Katayama, K., Armendariz-Borunda, J., Raghow, R., Kang, A.H., and Seyer, J.M. 1993. A pentapeptide from type I procollagen promotes extracellular matrix production. J. Biol. Chem. 268:9941-9944[Abstract/Free Full Text].

  20. Kikkawa, Y., Umeda, M., and Miyazaki, K. 1994. Marked stimulation of cell adhesion and motility by Ladsin, a laminin-like scatter factor. J. Biochem. 116:862-869[Abstract].

  21. Koshikawa, N., Moriyama, K., Takamura, H., Mizushima, H., Nagashima, Y., Yanoma, S., and Miyazaki, K. 1999. Overexpression of laminin gamma2 chain monomer in invading gastric carcinoma cells. Cancer Res. 21:5596-5601.

  22. Koshikawa, N., Giannelli, G., Cirulli, V., Miyazaki, K., and Quaranta, V. 2000. Role of cell surface metalloprotease MT1-MMP in epithelial cell migration over laminin 5. J. Cell Biol. 148:615-624[Abstract/Free Full Text].

  23. Lampe, P.D., Nguyen, B.P., Gil, S., Usui, M., Olerud, J., Takada, Y., and Carter, W. 1998. Cellular interaction of integrin alpha3beta1 with laminin 5 promotes gap junctional communication. J. Cell Biol. 143:1735-1747[Abstract/Free Full Text].

  24. Lazarova, Z., Yee, C., Darling, T., Briggaman, R.A., and Yancey, K.B. 1996. Passive transfer of anti-laminin 5 antibodies induces subepidermal blisters in neonatal mice. J. Clin. Invest. 98:1509-1518[Abstract/Free Full Text].

  25. Mainiero, F., Pepe, A., Wary, K.K., Spinardi, L., Mohammadi, M., Schlessinger, J., and Giancotti, F.G. 1995. Signal transduction by the {alpha}6ß4 integrin: distinct ß4 subunit sites mediate recruitment of Sch/Grb2 and association with the cytoskeleton of hemidesmosomes. EMBO (Eur. Mol. Biol. Organ.) J. 14:4470-4481[Abstract].

  26. Marinkovich, M.P., Lunstrum, G.P., and Burgeson, R.E. 1992. The anchoring filament protein kalinin is synthesized and secreted as a high molecular weight precursor. J. Biol. Chem. 267:17900-17906[Abstract/Free Full Text].

  27. Masunaga, T., Shimizu, H., Ishiko, A., Tomita, Y., Aberdam, D., Ortonne, J.P., and Nishikawa, T. 1996. Localization of laminin 5 in the epidermal basement membrane. J. Histochem. Cytochem. 44:1223-1230[Abstract/Free Full Text].

  28. Mizushima, H., Takamura, H., Miyagin, Y., Kikkawan, Y., Yamanakan, N., Yasumitsu, H., Misugi, K., and Miyazaki, K. 1997. Identification of integrin-dependent and -independent cell adhesion domains in COOH-terminal globular region of laminin 5 alpha 3 chain. Cell Growth Differ. 8:979-987[Abstract].

  29. Pyke, C., Romer, J., Kallunki, P., Lund, L.R., Ralfkiaer, E., and Tryggvason, K. 1994. The {gamma}2 chain of kalinin/laminin 5 is preferentially expressed in invading malignant cells in human cancers. Am. J. Pathol. 145:782-791[Abstract].

  30. Pyke, C., Salo, S., Ralfkiaer, E., Romer, J., Dano, K., and Tryggvason, K. 1995. Laminin 5 is a marker of invading cancer cells in some human carcinomas and is coexpressed with the receptor for urokinase plasminogen activator in budding cancer cells in colon adenocarcinomas. Cancer Res. 55:4132-4139[Abstract].

  31. Rousselle, P., and Aumailley, M. 1994. Kalinin is more efficient than laminin in promoting adhesion of primary keratinocytes and some other epithelial cells and has a different requirement for integrin receptor. J. Cell Biol. 125:205-214[Abstract].

  32. Rousselle, P., Lunstrum, G.P., Keene, D.R., and 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[Abstract].

  33. Rousselle, P., Keene, D.R., Ruggiero, F., Champliaud, M.F., Rest, M., and Burgeson, R.E. 1997. Laminin 5 binds the NC-1 domain of type VII collagen. J. Cell Biol. 138:719-728[Free Full Text].

  34. Ryan, M.C., Tizard, R., VanDevanter, D.R., and Carter, W.G. 1994. Cloning of the LAMA3 gene encoding the {alpha}3 chain of adhesive ligand epiligrin. J. Biol. Chem. 269:22779-22787[Abstract/Free Full Text].

  35. Ryan, M.C., Lee, K., Miyashita, Y., and Carter, W.G. 1999. Targeted disruption of the LAMA3 gene in mice reveals abnormalities in survival and late stage differentiation of epithelial cells. J. Cell Biol. 145:1309-1323[Abstract/Free Full Text].

  36. Sage, H.E. 1997. Piece of eight: bioactive fragments of extracellular proteins as regulators of angiogenesis. Trends Cell Biol. 7:182-186.

  37. Sonnenberg, A., de Melker, A.A., Martinez de Velasco, A.M., Janssen, H., Calafat, J., and Niessen, C.M. 1993. Formation of hemidesmosomes in cells of a transformed murine mammary tumor cell line and mechanisms involved in adherence of these cells to laminin and kalinin. J. Cell Sci 106:1083-1102[Abstract/Free Full Text].

  38. Stahl, S., Weitzman, S., and Jones, J.C.R. 1997. The role of laminin 5 and its receptors in mammary epithelial cell branching morphogenesis. J. Cell Sci. 110:55-63[Abstract/Free Full Text].

  39. Suzuki, N., Labosky, P.A., Furuta, Y., Hargett, L., Dunn, R., Fogo, A.B., Takahara, K., Peters, D.M., Greenspan, D.S., and Hogan, B.L. 1996. Failure of ventral body wall closure in mouse embryos lacking a procollagen C-proteinase encoded by Bmp1, a mammalian gene related to Drosophila tolloid. Development 122:3587-3595[Abstract/Free Full Text].

  40. Utani, A., Nomizu, M., and Yamada, Y. 1997. Fibulin-2 binds to the short arms of laminin-5 and laminin-1 via conserved amino acid sequences. J. Biol. Chem. 272:2814-2820[Abstract/Free Full Text].

  41. Vailly, J., Verrando, P., Champliaud, M.F., Gerecke, D., Wagman, D.W., Baudoin, C., Aberdam, D., Burgeson, R., Bauer, E., and Ortonne, J.P. 1994. The 100-kDa chain of nicein/kalinin is a laminin B2 chain variant. Eur. J. Biochem. 219:209-218[Abstract].