Skeletal myoblasts utilize a novel beta 1-series integrin and not alpha 6 beta 1 for binding to the E8 and T8 fragments of laminin.

The E8 fragment of laminin stimulates myoblast attachment and locomotion. Myoblast attachment to laminin/E8 was blocked by anti-integrin antibodies against beta 1-chains but not by antibodies against alpha 6-chains. By contrast, other cell lines (e.g. B16, HT1080, P19, F9, Pys2, 3T3, and 3T6) were blocked both by anti-beta 1 and anti-alpha 6. All cells tested also bound to approximately 125-kDa C-terminal fragments of E8 (T8 and T8'). Immunoprecipitation of surface-iodinated myoblasts revealed beta 1-, alpha 3-, and alpha 5-integrin chains and a novel chain that co-precipitated with anti-beta 1 antibodies running at approximately 95 kDa (reduced). I125-alpha 6 beta 1 was immunoprecipitated from cells whose attachment to E8 was blocked by anti-alpha 6 antibodies. By contrast, little alpha 6 beta 1 could be immunoprecipitated from myoblasts. beta 1-Integrin and the novel alpha-chain (alpha'), Mr approximately 120,000/approximately 95.000 (nonreduced/reduced), from myoblast lysates were retained during affinity chromatography on Engelbreth-Holm-Swarm-laminin affinity columns. beta 1, alpha 1, and the novel alpha' were retained from Rugli cell lysates on Engelbreth-Holm-Swarm-laminin columns. alpha 3 was not bound. When E8 was used as affinity matrix, only beta 1 and alpha' were retained. The N-terminal sequence of Rugli alpha' was homologous to alpha-chains of beta 1-series integrins and was most similar to alpha 6 (9 identical residues out of 14). However, there were distinctive differences; in particular, 2 residues were deleted in comparison with alpha 6.     

Immunocytochemical localization of laminin in hamster tracheal epithelial cell cultures

EM examination of 28 day cultures of enzymatically dissociated hamster tracheal epithelial (HTE) cells grown on collagen coated millipore filters reveals that fragments of basal lamina may be present at the basal plasmalemma. Since the basal lamina consists of several major components including type IV collagen, heparan sulfate proteoglycans, entactin/nidogen, and laminin, questions naturally arise concerning the presence of such a structure in this cell culture system. When immunocytochemical procedures utilizing anti-laminin antibody and PAP techniques are carried out with paraffin sections of HTE culture at 1,2,3, and 4 weeks in vitro, LM analysis reveals that a thin, dense line of reaction product is present between the basal surface of the HTE cells and the underlying collagen substrate. Immunoblotting evaluation carried out with supernatants of 7d HTE cell homogenates and HTE cell conditioned media also indicate that laminin is being produced by the tracheal cells. Thus, the presence of basal lamina-like fragments, the immunocytochemical localization of laminin, and immunoblot identification of laminin in hamster tracheal epithelial cell cultures, suggest that, although basal lamina components may be produced by HTE cells, at the time points tested, they are not yet being organized into a complete basal lamina.     

Laminin synthesized by stationary and migrating rat liver epithelial cells lacks the A chain

The expression of laminin chains was analyzed in normal and Ha-ras1-transformed rat liver epithelial cells. The normal, nontumorigenic cells were induced to migrate by epidermal growth factor, whereas the Ha-ras1-transformed, malignant derivatives migrate constitutively. None of these cells express a typical (EHS-like) laminin A chain. Immunoprecipitation of [35S]-methionine-labeled liver cell lysates with an antibody against EHS-laminin revealed B1 and B2 chains and, in addition, two high Mr polypeptides. These polypeptides were not recognized by the antibody in immunoblots, suggesting that they might constitute alternative laminin A chains. Analysis of the expression of all three laminin chains at the RNA and protein level revealed that the pattern of expression of the stationary cells does not differ from that of the migratory ones and is also not influenced by epidermal growth factor. These results indicate that expression of a typical laminin A chain by rat liver epithelial cells is not required for the secretion and deposition of the protein in the extracellular matrix. The data also indicate that an EHS-like laminin A chain is not required for the migration of these epithelial cells.     

Co-expression of an epitope on human free kappa-light chains and on a cytoplasmic component in activated T cells

K-1-21 is a murine monoclonal antibody that reacts with human kappa-light chains in free form but not when they are associated with immunoglobulin heavy chains. K-1-21 was unexpectedly shown to bind to a determinant, STA (Sezary T cell antigen), detected by immunofluorescence in the cytoplasm but not on the surface of Sezary T cells isolated from peripheral blood (4/4 cases) and in Sezary T cells from lymph node and bone marrow (one patient). STA was detected in F2/F7, CCRF-CEM, Molt-4, and CCRF-HSB (four human T ALL cell lines), in JURKAT (a human T cell leukemia line), and in MLA144 (a Gibbon T cell lymphoma line). It also occurred in Leu-3a+ antigen-specific T cell clones (6/6 tested). Moreover, although STA was absent from freshly isolated normal T cells, its expression could be evoked in E+ cells from peripheral blood by in vitro culture with phytohemagglutinin. Thus, STA appears to be a cytoplasmic marker for activated T cells. Cytoplasmic inhibition immunofluorescence studies indicated that K-1-21 binding to STA in Sezary cells or T cell lines was inhibited by preincubation of the K-1-21 antibody with purified kappa-Bence Jones protein. STA from radiolabeled MLA144 cell lysates was immunoprecipitated by K-1-21 and was identified on polyacrylamide gel electrophoresis under reducing conditions as a protein of m.w. 57,000. Additional experiments are underway to define the molecular basis of the interesting cross-reactivity between a determinant in T cells and the K-1-21 reactive epitope on free kappa-light chains.     

Disruption of microfilaments alters laminin synthesis but not laminin trafficking in NHEKin vitro

Summary Laminin synthesis and deposition are concomitant with the development of a basal lamina between the human epidermis and the underlying dermis. One of the challenges in tissue engineering of human epidermal models is to develop substrates and conditions that encourage the development of a basement membrane. The purpose of this study was to determine if actin filaments and/or microtubules are involved in the synthesis/secretion of laminin by normal human epidermal keratinocytes (NHEK)in vitro. NHEK synthesize and secrete laminin subunits B1, B2, and M but little, if any, of laminin subunit A. Data indicate that disruption of microfilaments by the destabilizing agent, cytochalasin D, had no apparent effect on the relative synthesis rates of most cytosolic proteins as, revealed by one-dimensional sodium dodecyl sulfate (SDS) gel electrophoresis. This drug, however, increased laminin B2 synthesis several fold over untreated controls. This enhanced synthetic rate was independent of the type of collagen, matrix on which the NHEK were grown. Similar increases in synthesis of the M and B1 laminin chains were not observed. To determine if this increase in synthesis lead to increases in laminin B2 secretion, laminin B2 was immunoprecipitated from both the apical and basal domains of NHEK cells grown on microporous membranes. While more laminin B1, B2, and M were secreted basally than apically, an observation consistent with laminin’s role in basal lamina formation, cytochalasin D had no apparent effect on either basal or apical laminin B2 secretion. Experiments with the microtubule destabilizer, nocodazole, showed no similar effects on laminin synthesis and/or secretion. We conclude that (a) disruption of the actin network in NHEK selectively increases the synthesis of laminin B2, (b) the secretion of laminin B2 from NHEK cells is not governed by either the microfilamentous cytoskeleton or the amount of laminin synthesized by NHEK, and (c) disruption of the microtubular network does not alter laminin synthesis or secretion.     

Immunolocalization of laminin during estrogen-induced differentiation of quail oviduct epithelial cells

During estrogen-induced development of the quail oviduct, tubular glands are formed by evagination of epithelial cells into the stroma. The distribution of laminin was studied during the early stages by means of immunofluorescence and immunoperoxidase techniques. Ultrastructural changes in the basal lamina were studied by electron microscopy. Basement membranes at all stages of development were delineated with 3 polyclonal antilaminin antisera. However, in ovariectomized birds, laminin could not be detected by one of the polyclonal antilaminin antisera. Subsequently, this antibody detected laminin as epithelial cell evaginations were induced by estradiol benzoate. The heavy and light chains of Engelbreth Holm sarcoma (EHS) laminin were revealed in immunoblotting by all antibodies. By electron microscopy after the immunoperoxidase technique with antilaminin antisera laminin appears to be accumulated mainly in the lamina densa. Furthermore, the thickness of the basal lamina increases during oviduct development. These data indicate that basal lamina organization is modified during oviduct cell differentiation and that immunoreactivity of epithelial basement membrane laminin changes during development.     

Biosynthesis and deposition of a noncovalent laminin-heparan sulfate proteoglycan complex and other basal lamina components by a human malignant cell line

The basal lamina components laminin, heparan sulfate proteoglycan (HSPG), and type IV collagen were synthesized and codeposited in the extracellular matrix (ECM) by a cultured human cell line from gestational choriocarcinoma (JAR). Laminin and HSPG formed a noncovalent complex detected by the coimmunoprecipitation of HSPG with laminin from cell lysates and culture media. The complex was stable in the cell lysis buffer that contained detergents (1% Triton X-100, 0.5% deoxycholate, and 0.1% sodium dodecyl sulfate) and sodium chloride (from 0.15 to 1.0 M), but was dissociated by adding 8 M urea to the detergent lysates. Even though JAR cells produced roughly equal amounts of HSPG and chondroitin sulfate proteoglycan, only HSPG complexed with laminin, suggesting a specific interaction between these basal lamina components. The laminin-HSPG complex was deposited and retained in the ECM. This was shown biochemically by isolating an enriched fraction of ECM from JAR cells cultured on native type I collagen gels. At steady state, more than half (52%) of the laminin-HSPG in the culture was recovered in the ECM fraction, in contrast to 16% of the total laminin and 29% of the total type IV collagen, which were secreted to a greater extent than laminin-HSPG into the culture medium. The retention of the laminin-HSPG complex in the ECM suggests that it may participate in the assembly of the basal lamina-like extracellular matrix deposited by JAR cultures. Omission of ascorbate from the culture medium abolished the ECM deposition of type IV collagen but had little effect on the deposition of laminin or laminin-HSPG. This demonstrates that the stable deposition of laminin-HSPG and laminin in the collagen-based choriocarcinoma cultures is not dependent on an assembled network of type IV collagen.     

α1- and α5-containing Laminins Regulate the Development of Bile Ducts via β1 Integrin Signals

Signals derived from basal lamina components are important for developing three-dimensional architecture of epithelial tissues. Laminins consisting of α, β, and γ subunits in basal lamina play pivotal roles in the formation and maintenance of epithelial tissue structures. However, it remains unclear which laminin isoforms transmit signals and how epithelial cells receive them to regulate multiple developmental processes. In three-dimensional culture of a liver progenitor cell line, Hepatic Progenitor Cells Proliferating on Laminin (HPPL), the cells establish apicobasal polarity and form cysts with a central lumen. Neutralizing antibody against β1 integrin blocked the formation and maintenance of the cyst structure, indicating that β1 integrin signaling was necessary throughout the morphogenesis. Although the addition of α1-containing laminin, a ligand of β1 integrin, induced cyst formation, it was dispensable for the maintenance of the cyst, suggesting that HPPL produces another ligand for β1 integrin to maintain the structure. Indeed, we found that HPPL produced α5-containing laminin, and siRNA against laminin α5 partially inhibited the lumen formation. In fetal liver, p75NTR(+) periportal fibroblasts and bile duct epithelial cells, known as cholangiocytes, expressed α1- and α5-containing laminins, respectively. In laminin α5 KO liver, cholangiocytes normally emerged, but the number of bile ducts was decreased. These results suggest that α1-containing laminin is sufficient as a component of the basal lamina for the commitment of bipotential liver progenitors to cholangiocytes and the apicobasal polarization, whereas α5-containing laminin is necessary for the formation of mature duct structures. Thus, α1- and α5-containing laminins differentially regulate the sequential events to form epithelial tissues via β1 integrin signals.     

Inhibition of Smad signaling is implicated in cleft palate induced by all-trans retinoic acid

The effect of all-trans retinoic acid (atRA) on palatal fusion and the underlying mechanisms were investigated using organ culture. Compared with control group, the atRA-treated group (1 μM and 5 μM) had more medial edge epithelium (ME) remaining within the midline epithelial seam (MES). At 10 μM atRA, the opposing shelves were not in contact at the culture end (72 h). Cell death detection by TUNEL and laminin immunohistochemistry demonstrated that atRA (5 μM) induced apoptosis in mesenchyme and inhibited degradation of basal lamina within MES. Notably, migration and apoptosis of ME cells and degradation of basal lamina within MES markedly represented vehicle control palatal shelves in culture. Additionally, apoptosis was not detected in mesenchyme of control palatal shelves. Immunoblotting analysis revealed that Smad2 and Smad3 were endogenously activated and expression of Smad7 was inhibited during the fusion process. In contrast, atRA treatment abrogated phosphorylation of Smad2 and Smad3 and inducible expression of Smad7 in ME. From these data, it is assumed that inhibition of Smad pathway by atRA in ME may play a critical role in abrogation of the ME cell apoptosis and degradation of the basal laminin, which might contribute to failure of palatal fusion.     

Composition in situ and in vitro of vascular smooth muscle laminin in the rat

Vascular smooth muscle cells are surrounded by a basal lamina containing an array of macromolecules: included among these are the laminins, a family of oligomeric glycoproteins composed of subunits encoded by different genes. In this study, we have used monoclonal antibodies to several of these subunits, including S-laminin, laminin B2, and laminin B1, to study these proteins in tail artery, superior mesenteric artery, and aorta of rats. In situ, immunostaining for the B2 and S chains was present in the basal lamina, between the smooth muscle cells, throughout the tunica media. In contrast, B1 chain immunostaining was concentrated around cells in the inner media. To investigate whether smooth muscle cells can produce S-laminin, laminin B2, and laminin B1, smooth muscle cells from the superior mesenteric artery were grown in culture and laminin subunit expression determined. In early culture (4 days), immunostaining showed abundant laminin B2 and less B1 synthesis and incorporation into the matrix. Staining for S-laminin was even less intense than for B1 and was localized to areas where cells were densely packed. The same pattern of S-laminin immunostaining was seen during early culture in cells grown on fibronectin, type IV collagen, or gelatin. Immunoblotting detected S-laminin in the conditioned medium from early cultured cells. In later culture (12 days), S-laminin incorporation into the matrix increased markedly compared to incorporation at 4 days. At this time, cells are much more densely packed and multilayered with extensive matrix accumulation. Cyclical stretching of cells in vitro did not increase immunostaining for S-laminin. Together these data show that S-laminin is a component of the arterial media in situ and that in vitro S-laminin is synthesized by smooth muscle cells. Increased incorporation of S-laminin into the matrix in later culture correlates with the presence of a more extensive matrix, suggesting that matrix organization may be critical to S-laminin incorporation.     

Laminin B1 expression is required for laminin deposition into the extracellular matrix of PC12 cells.

The extracellular matrix of rat pheochromocytoma PC12 cells was shown by indirect immunofluorescence to consist of a network of fibronectin. The matrix did not contain laminin. The cells synthesized messenger RNA for fibronectin, laminin B2, and s-laminin but not for entactin or the B1 and A chains of laminin. Laminin B2 but not laminin B1 was detectable in the culture medium and in cell lysates. A full-length cDNA clone for the B1 chain of laminin was constructed in the plasmid p-444, which contains the neomycin-resistance marker and human beta-actin promoter. PC12 cells were transfected with this recombinant plasmid, and stable neomycin-resistant clones were isolated and characterized. Clones that synthesized laminin B1 messenger RNA were found to deposit a laminin-containing matrix. In many of these clones the deposition of the fibronectin matrix was greatly diminished. The laminin matrix was predominantly localized in the intercellular spaces forming a honeycomb pattern. The morphology of the laminin-synthesizing transfected cells was markedly different from the parental cells. The cells grew in tight clusters that were resistant to dissociating agents. It is concluded that the B1 chain of laminin contains information that is required for the formation of a stable laminin-containing extracellular matrix network either by interaction with cell surface receptors or other extracellular matrix components. Furthermore, expression of the laminin B1 gene may be a central regulatory point in determining extracellular matrix composition during embryogenesis.     

Laminin is structurally conserved in the sea urchin basal lamina

The extracellular matrix is involved in the regulation of differentiation and morphogenesis. Here we report the identification of a sea urchin embryonic extracellular matrix protein by means of a monoclonal antibody BL1 (Mab BL1) and the isolation of the protein from basal lamina preparations. In paraffin sections of fixed embryos, the antibody can be detected on the basal surfaces of cells after the blastula stage. Immunoprecipitation from embryo lysates and salt extracts of metabolically labeled basal lamina preparations demonstrates that the basal lamina antigen is a large mol. wt protein of approximate mol. wt 10⁶ which consists of disulfide-linked subunits of mol. wts ˜480 000 and 260 000. Electron microscopic images show that the Mab BL1 basal lamina antigen is structurally related to the vertebrate extracellular matrix protein laminin.     

Interaction of Shiga toxin from Escherichia coli with human intestinal epithelial cell lines and explants: Stx2 induces epithelial damage in organ culture

Shiga toxins (Stx) produced by Escherichia coli are associated with systemic complications such as haemolytic-uraemic syndrome. The mechanism of Stx translocation across the epithelial barrier is unknown as human intestinal epithelium lacks receptor Gb3. In this study, we have examined the interaction of purified Stx1 and 2 with Caco-2 (Gb3+) and T84 (Gb3-) cell lines, and determined the effects of Stx on human intestine using in vitro organ culture (IVOC). Stx exposure caused inhibition of protein synthesis and apoptosis in Caco-2 but not in T84 cells. However, both Stx1 and 2 were transported to the endoplasmic reticulum, and the Stx1 A-subunit was cleaved in a furin-dependent manner in both cell lines. Thus, a Gb3-independent retrograde transport route exists in T84 cells for Stx that does not induce cell damage. IVOC demonstrated increased epithelial cell extrusion in response to exposure to Stx2, but not Stx1, in both small intestine and colon. Pretreatment of Stx2 with Stx2-specific antibody abrogated this effect. Overlaying frozen sections with Stx showed lamina propria, but not epithelial, cell binding that paralleled Gb3 localization, and included endothelium and pericryptal myofibroblasts. This indicates that human intestinal epithelium may evince Stx2-induced damage in the absence of Gb3 receptors, by an as yet unrecognized mechanism.     

Migrating mesoderm establish a uniform distribution of laminin in the developing grasshopper embryo

The basal lamina is composed of molecules which physically interact to form a network that serves as a migrational scaffold for many cell types. In the developing peripheral nervous system of the grasshopper, neuronal growth cones are intimately associated with the basal lamina as they migrate. Laminin is a major component of the basal lamina and is a potent promoter of neurite outgrowth in vitro. However, it is unclear what the source of laminin is or how the distribution of laminin within the basal lamina is established. To address this question, grasshopper laminin subunit genes were cloned. As expected, laminin was found within the basal lamina throughout the embryo, in particular in the limb bud, where its expression is coincident with the outgrowth and guidance of the Tibial (Til) pioneer neurons. Surprisingly, the synthesis of beta and gamma chains of laminin was restricted to migratory mesodermal cells, while in other nonmigratory tissues, such as epithelium and presumptive muscle, beta and gamma chains of laminin were not detected. In spite of this, laminin immunoreactivity in the basal lamina appears uniform and is available as a substrate for axonal outgrowth.     

Expression of J1/tenascin in the crypt-villus unit of adult mouse small intestine: implications for its role in epithelial cell shedding.

The localization of the extracellular matrix recognition molecule J1/tenascin was investigated in the crypt-villus unit of the adult mouse ileum by immunoelectron microscopic techniques. In the villus region, J1/tenascin was detected strongly in the extracellular matrix (ECM) between fibroblasts of the lamina propria. It was generally absent in the ECM at the interface between subepithelial fibroblasts and intestinal epithelium, except for some restricted areas along the epithelial basal lamina of villi, but not of crypts. These restricted areas corresponded approximately to the basal part of one epithelial cell. In J1/tenascin-positive areas, epithelial cells contacted the basal lamina with numerous microvillus-like processes, whereas in J1/tenascin-negative areas the basal surface membranes of epithelial cells contacted their basal lamina in a smooth and continuous apposition. In order to characterize the functional role of J1/tenascin in the interaction between epithelial cells and ECM, the intestinal epithelial cell line HT-29 was tested for its ability to adhere to different ECM components. Cells adhered to substratum-immobilized fibronectin, laminin and collagen types I to IV, but not to J1/tenascin. When laminin or collagen types I to IV were mixed with J1/tenascin, cell adhesion was as effective as without J1/tenascin. However, adhesion was completely abolished when cells were offered a mixture of fibronectin and J1/tenascin as substratum. The ability of J1/tenascin to reduce the adhesion of intestinal epithelial cells to their fibronectin-containing basal lamina suggests that J1/tenascin may be involved in the process of physiological cell shedding from the villus.     

Expression of laminin by human fibroblasts, HT1080 fibrosarcoma cells and MCF-7 breast adenocarcinoma cells. Lack of regulation by the cell density and extracellular matrix.

We have cultured normal fibroblasts, fibrosarcoma HT1080 cells and breast adenocarcinoma MCF-7 cells on various substrates (plastic, collagen type I, laminin). All cell types used adhered on the three substrates with, however, a delayed attachment on laminin. On all substrates, cell grew as monolayer with the exception of MCF-7 cells that formed clusters on laminin. The epithelial MCF-7 cells as well as mesenchymal cells (fibroblasts and tumoral HT1080 cells) synthesized laminin and expressed mRNA coding for laminin B1 chain and for the 67 kD laminin binding protein. The levels of these mRNAs were not modulated by culture conditions which affect cell morphology nor by cell density.     

Proteolytic disruption of laminin-integrin complexes on muscle cells during synapse formation.

To explore whether a neural modulation of muscle integrins' extracellular ligand interactions contributes to synapse induction, we compared the distributions of beta1-integrins and basal lamina proteins on Xenopus myotomal myocytes developing in culture. beta1-Integrins formed numerous organized aggregates scattered over the entire muscle surface, with particularly dense accumulations at specialized sites resembling myotendinous and neuromuscular junctions. Integrin aggregates on muscle cells differed from those on surrounding fibroblasts and epithelial cells, both in their lack of response to cross-linking by multivalent ligands and in their consistent association with the cells' own extracellular matrices. Muscle integrin clusters were usually associated with congruent basal lamina accumulations containing laminin and a heparan sulfate proteoglycan (HSPG), sometimes including fibronectin and vitronectin acquired from the surrounding medium. Immediately prior to synaptic differentiation, any existing laminin and HSPG accumulations along the path of cell contact were eliminated, disrupting otherwise stable laminin-integrin complexes. This apparently proteolytic modulation of integrins' extracellular ligand interactions was soon followed by the accumulation of new congruent accumulations of laminin and HSPG in the developing synaptic basal lamina. Combining these results with earlier findings, we consider the possibility that postsynaptic differentiation is induced, at least in part, by the proteolytic disruption of integrin-ligand complexes at sites of nerve-muscle contact.     

Laminin ultrastructural immunolocalization in rat testis during ontogenesis

Summary The synthesis of one of the main glycoproteins of the basement membrane, the laminin, was demonstrated by ultrastructural immunolocalization during rat foetal (16th day to 20th day of gestation) and postnatal development of the testis. The lamina densa, part of seminiferous tubular basement membrane, is labeled uniformly at all studied stages. The lamina lucida is not well defined before the postnatal stages, at which times discrete immunostaining extends from the lamina densa to the adjacent seminiferous epithelial cells (spermatogonia and Sertoli cells). The extracellular matrix around the peritubular cells is not labeled before birth. Intracellular immunostaining was detected as early as the 16th day of gestation in both Sertoli cells and cells around the seminiferous tubules which will transform later into peritubular cells. It was located in rough endoplasmic reticulum (RER) cisternae and secretory vesicles. After 18–20 days of postnatal life, the immunostaining faints progressively. Some positive material is seen in the RER of the gonocytes at all studied stages.Sertoli cells and peritubular cells are the main producing cells of laminin after the 16th of gestation. The laminin secreted by gonocytes may play an important role in adhesion of gonocytes to the lamina densa and adjacent Sertoli cells before their transition from basal compartment to adluminal compartment.     

The matrix form of collagen and basal microporosity influence basal lamina deposition and laminin synthesis/secretion by stratified human keratinocytes in vitro

Summary The ability of the collagen matrix form to support the formation of a basal lamina by cultured normal human epidermal keratinocytes (NHEK) was determined using transmission electron microscopy. The collagen matrix forms tested in this study were a) a dry type I collagen film and b) a type I collagen gel. NHEK were grown for 14 days on the following five different substrates: plain plastic culture dishes without the addition of collagen (PP); plain plastic culture dishes overlaid with a dry, aldehyde-crosslinked type I collagen film (DCF-P); plain plastic culture dishes overlaid with an aldehyde-crosslinked type I collagen gel (GEL-P); Millipore Millicell CM microporous membranes overlaid with a dry, aldehyde-crosslinked type I collagen film (DCF-CM); and Millipore Millicell CM microporous membranes overlaid with an aldehyde-crosslinked type I collagen gel (GEL-CM). NHEK maintained for 2 wk on PP and DCF-P were unable to secrete a basal lamina. NHEK grown for 2 wk on the GEL-P and GEL-CM substrates, however, secreted a contiguous basal lamina at the GEL-NHEK interface. To determine if the appearance of this basal lamina correlated with laminin synthesis, laminin was immunoprecipitated from cellular extracts, as well as media from the apical and basal chambers. NHEK grown on the GEL-P substrate synthesized more laminin than did NHEK grown on the other four alternative substrates. In addition, NHEK grown on GEL-CM were able to direct more laminin to the basal compartment than NHEK grown on DCF-CM substrates. Taken together, the data indicate that the matrix form of collagen can influence basal lamina deposition, laminin synthesis, and laminin trafficking in NHEK.