Mechanical ventilation is a valuable treatment regimen for respiratory failure. However, mechanical ventilation (especially with high tidal volumes) is implicated in the initiation and/or exacerbation of lung injury. Hence, it is important to understand how the cells that line the inner surface of the lung [alveolar epithelial cells (AECs)] sense cyclic stretching. Here, we tested the hypothesis that matrix molecules, via their interaction with surface receptors, transduce mechanical signals in AECs. We first determined that rat AECs secrete an extracellular matrix (ECM) rich in anastamosing fibers composed of the α3 laminin subunit, complexed with β1 and γ1 laminin subunits (i.e. laminin-6), and perlecan by a combination of immunofluorescence microscopy and immunoblotting analyses. The fibrous network exhibits isotropic expansion when exposed to cyclic stretching (30 cycles per minute, 10% strain). Moreover, this same stretching regimen activates mitogen-activated-protein kinase (MAPK) in AECs. Stretch-induced MAPK activation is not inhibited in AECs treated with antagonists to α3 or β1 integrin. However, MAPK activation is significantly reduced in cells treated with function-inhibiting antibodies against the α3 laminin subunit and dystroglycan, and when dystroglycan is knocked down in AECs using short hairpin RNA. In summary, our results support a novel mechanism by which laminin-6, via interaction with dystroglycan, transduces a mechanical signal initiated by stretching that subsequently activates the MAPK pathway in rat AECs. These results are the first to indicate a function for laminin-6. They also provide novel insight into the role of the pericellular environment in dictating the response of epithelial cells to mechanical stimulation and have broad implications for the pathophysiology of lung injury.
Introduction
In intact tissue, many types of epithelial cells are routinely subject to mechanical forces (Ingber, 2003; Wang et al., 1993). For example, urothelial cells covering the inner surface of the bladder experience cycles of stretching and contraction as the bladder fills and then discharges its contents, whereas epithelial cells that line the gut are subjected to waves of peristalsis within the alimentary canal. Endothelial cells in intact blood vessels are subject to and respond precisely to changes in hemodynamic shear stress (Davies et al., 2003; Shyy and Chien, 2002). Epithelial cells that cover the alveolar surface of the lungs are no exception and undergo cyclic mechanical deformation forces during tidal breathing, particularly following lung injury (Brower et al., 2000; Corbridge et al., 1990; Correa-Meyer et al., 2002; Edwards, 2001; Liu et al., 1999; Steinberg et al., 2002; Webb and Tierney, 1974). Moreover, in alveolar epithelial cells (AECs), mechanical stimulation is known to initiate signals that result in increases in DNA synthesis and the expression of certain growth-factor receptors, surfactant proteins and extracellular-matrix proteins (Edwards, 2001; Liu et al., 1999). In addition, certain pathological conditions are initiated when AECs are subjected to excessive external forces. In particular, ventilation of patients with lung injury leads to increased cell-membrane permeability, pulmonary edema and inflammation, and contributes to mortality in patients with acute respiratory distress syndrome (ARDS) (Brower et al., 2000; Corbridge et al., 1990; Edwards, 2001; Liu et al., 1999; Webb and Tierney, 1974).
Although it has been established that cells sense external forces, in part, through mechanosensitive channels and growth-factor-receptor circuitry, there are considerable data that indicate that certain mechanical signals are transduced via matrix cell-surface receptors, including the integrins (Blount, 2003; Chen et al., 1999; Hamill and Martinac, 2001; Hynes, 1992; Hynes, 2002; Ingber, 2003; Tschumperlin et al., 2004; Wang et al., 1993). However, whether matrix receptors and their ligands, including the laminins and laminin-binding proteins, mediate such mechanical-signal transduction by converting mechanical signals into chemical signals in the cytoplasm of a cell is not clear (Edwards, 2001; Liu et al., 1999; Nilius and Droogmans, 2001).
The composition of the matrix to which AECs adhere in the intact lung has been studied by several groups. Specifically, several laminin subunits have been identified in the matrix-rich basement membrane of AECs in vivo (Coraux et al., 2002; Mizushima et al., 1998; Pierce et al., 1998; Virtanen et al., 1996). This basement membrane is covered by a sheet of cells composed mainly of type-I (AT1, alveolar type-I pneumocytes) cells (Crapo et al., 1982). The squamous AT1 cells line ∼95% of the alveolar surface area and are susceptible to oxidant stress (Crapo et al., 1982). They share the basement membrane with type-II (AT2, pneumocyte type II) cells, which are cuboidal and cover less than 5% of the alveolar surface (Crapo et al., 1982). The type-II cells produce surfactant, proliferate and differentiate into type I cells (Crapo et al., 1982; Fehrenbach, 2001; Uhal, 1997). In the basement membrane of the lung, subunits of laminin show precise, developmentally regulated patterns of expression (Coraux et al., 2002; Mizushima et al., 1998; Pierce et al., 1998; Virtanen et al., 1996). For example, laminin α1 expression is restricted to early human lung morphogenesis, whereas the laminin α5 is continuous from early lung development to adult life (Pierce et al., 1998; Virtanen et al., 1996). Moreover, the α3 laminin subunit is expressed in the basement membrane of the alveoli of adult rat lung, where it localizes with β1, γ1 and β2 subunits. Indeed, some authors have speculated that alveolar cells might express at least five laminin isoforms (Pierce et al., 1998). In addition, several matrix-receptor complexes have been identified in the developing and adult lungs. In particular, the α2, α3 and α6 integrin subunits are found in developing alveolar tissue and in adult alveoli, and might serve in AEC adherence to laminins in the basement membrane (Virtanen et al., 1996). The β4 integrin appears to be restricted to the bronchi, where it assembles into hemidesmosome structures that tether bronchial airway epithelial cells to laminin 5 in the basement membrane (Michelson et al., 2000).
In this study, we used primary rat AECs to assay the molecular underpinning of cellular response to physical force. In particular, we tested the hypothesis that matrix molecules secreted by lung epithelial cells are crucial molecular links in the process of `converting' a mechanical stress in the form of stretching into a cytoplasmic signal. We present the first analyses of the function and organization of laminin 6 secreted by epithelial cells and we provide data that implicate dystroglycan as a component of a complex that transduces mechanical signals. Moreover, our results reveal that a novel matrix fibrillar complex transduces mechanical signals that regulate the activity of p42/p44 mitogen-activated-protein kinase (MAPK) in rat AECs. Our data and conclusions contrast with those of others, who have stated that mechanotransduction does not require `force-dependent biochemical processes within the cell or cell membrane' (Tschumperlin et al., 2004).
Materials and Methods
Cell culture
AECs were isolated from pathogen-free male Sprague-Dawley rats (200-225 g) as previously described (Correa-Meyer et al., 2002; Ridge et al., 1997). Briefly, the lungs were perfused via the pulmonary artery, lavaged and digested with elastase (3 U ml–1; Worthington Biochemical, Freehold, NJ). AECs were purified by differential adherence to immunoglobulin G (IgG) pretreated dishes and cell viability was assessed by trypan-blue exclusion (>95%). Cells were resuspended in Dulbecco's modified Eagle's medium (DMEM; Cellgro, Mediatech Inc., Herndon, CA) containing 10% fetal bovine serum (FBS; Hyclone, Logan, UT) with 2 mM glutamine, 100 U ml–1 penicillin, 0.25 μg ml–1 amphotericin B and 100 μg ml–1 streptomycin. Cells were seeded in six-well, 35 mm, elastomer-bottomed Bioflex© plates (Flexcell International, Meckeesport, PA) or peptide-coated glass coverslips at a density of 0.5×106 cells cm–2. Cells were incubated in a humidified atmosphere of 5% CO2, 95% air at 37°C. The day of isolation and plating is designated culture day 0 (zero). 804G cells were cultured as detailed previously (Riddelle et al., 1991).
Antibodies and other reagents
Polyclonal rabbit antisera against p42/p44 MAPK and activated (phosphorylated) p42/p44 MAPK were purchased from Cell Signaling Technology (Beverly, MA). The mouse monoclonal antibodies CM6 and 5C5 against the laminin α3 subunit were described previously (Baker et al., 1996; Langhofer et al., 1993). Mouse monoclonal antibodies against the γ2 and β3 subunits of rat laminin 5 were originally provided by Desmos (San Diego, CA). A rabbit antiserum against the β1 laminin subunit was obtained from P. Yurchenco (Department of Pathology, Robert Wood Johnson Medical School, Piscataway, NJ). Mouse monoclonal antibody (mAb) against the γ1 laminin subunit (mAb 1920) was obtained from Chemicon International (Temecula, CA). A goat polyclonal antiserum against the α5 laminin subunit (G20) was purchased from Santa Cruz Biotechnology (Santa Cruz, CA). A rabbit antiserum against nidogen was obtained from Calbiochem (San Diego, CA). A hamster mAb (Ha2/5) that inhibits the function of rat β1 integrin was purchased from BD Pharmingen (Franklin Lakes, NJ). A function-inhibitory rat antibody against α3 integrin (Ralph 3.1), a mouse mAb against the β2 laminin subunit and mouse mAb against perlecan were obtained from the Developmental Studies Hybridoma Bank (University of Iowa, Iowa City, IA). Mouse IgM IIH6 against α-dystroglycan has been described elsewhere (Henry et al., 2001). Mouse mAb 8D5 against β-dystroglycan was purchased from Novocastra Labs (Newcastle, UK). Mouse IgM Ab1 against actin was purchased from Calbiochem. Control IgGs and IgMs, and fluorescein, rhodamine and horseradish-peroxidase-conjugated secondary antibodies were purchased from Jackson ImmunoResearch (West Grove, PA). For imaging of unfixed matrix proteins under stretching, we labeled the matrix with the antibody 5C5 followed by Alexa-Fluor-488-conjugated goat anti-mouse IgG (Molecular Probes, Eugene, OR).
The GRGDSP peptide was purchased from Invitrogen (Carlsbad, CA) and added to the medium of the AECs at a concentration of 100 μg ml–1 in serum-free medium for 24 hours before stretching.
short hairpin RNA protocol
A set of single-stranded oligonucleotides encoding the dystroglycan target short hairpin RNA (shRNA) and its complement were synthesized by Invitrogen (Carlsbad, CA).
2719Forward:
CACCGCTCATTGCTGGAATCATTGCCGAAGCAATGATTCCAGCAATGAGC
2719Reverse:
AAAAGCTCATTGCTGGAATCATTGCTTCGGCAATGATTCCAGCAATGAGC
The sequence was selected using an algorithm provided by Invitrogen. The oligonucleotide pair was annealed, ligated into the pENTR/U6 vector and used to transform competent Escherichia coli cells following an established protocol (Invitrogen). Plasmid DNA was isolated from the kanamycin-resistant colonies and sequenced. The pENTRY/U6 construct was used in a recombination reaction with the adenoviral vector pAD/BLOCK-iT-DEST (Invitrogen). The resulting shRNA adenoviral vector was linearized with PacI and transfected into 293A cells using Lipofectamine following Invitrogen protocols. In addition, an adenoviral vector containing shRNA targeting human (but not rat) lamin A/C (supplied by Invitrogen) was processed the same way and used as a negative control for the adenoviral infection. Approximately 12 days after transfection, the adenovirus-containing 293A cells were harvested and lysed to prepare a crude viral stock. The resultant viral stock was amplified and the viral concentration determined. 2 days after plating, AECs were infected with the virus at a multiplicity of infection of 1:10. The following day, the medium was replaced and assays were performed 24 hours later.
Cyclic stretching
AECs were cultured for 3 days. After serum starvation for 24 hours, the cells were subjected to equibiaxial stretching on day 4 using the Cyclic Strain Unit FX-3000 (Flexcell International, Hillsborough, NC). This unit consists of a controlled vacuum unit and a base plate to hold the culture plates. A vacuum was cyclically applied to elastomer-bottomed six-well culture dishes using the Flexercell device with loading stations in place to impose equibiaxial stretching at 30 cycles per minute and a stretching-relaxation ratio of 1:1, resulting in a 10% linear elongation of the membrane as measured microscopically. This is the same regimen used previously (Correa-Meyer et al., 2002). Cells were harvested at 10 minutes, after the initiation of cyclic stretching.
SDS-PAGE and immunoblotting
AECs were solubilized in sample buffer consisting of 8 M urea, 1% sodium dodecyl sulfate in 10 mM Tris-HCl, pH 6.8, 15% β-mercaptoethanol (Laemmli, 1970). AEC matrix was prepared according to a previously published procedure (Langhofer et al., 1993). The matrix proteins were collected from the culture dish by solubilization in the above sample buffer. Proteins were separated by SDS-PAGE, transferred to nitrocellulose and processed for immunoblotting as previously described (Harlow and Lane, 1988; Klatte et al., 1989; Laemmli, 1970). Immunoblots were scanned and quantified using Molecular Analyst (BioRad, Richmond, CA).
Immunofluorescence microscopy
Cells on glass coverslips were extracted for 2 minutes at –20°C in acetone. Cells maintained on elastomer surfaces in six-well plates were fixed in 3.7% formaldehyde for 5 minutes, extracted in 0.5% Triton X-100 in PBS at 4°C for 8 minutes in situ and then washed thoroughly in PBS. Subsequently, the elastomer surface with attached cells was excised from the six-well plate and processed as if it were a coverslip. Appropriate single primary antibodies or mixtures were overlaid onto the cells and the preparations were incubated at 37°C for 60 minutes. The cells on coverslips or elastomer were washed in three changes of PBS and then overlaid with secondary antibodies, placed at 37°C for an additional 60 minutes, washed extensively and then mounted on slides (cells on coverslips) or covered with a glass coverslip (cells on elastomer membrane). All preparations were viewed on a Zeiss laser-scanning confocal microscope (LSM 510) (Carl Zeiss, Thornwood, NY). Microscope images were exported as TIF files and figures were generated using Adobe Photoshop software.
Image analyses of α3 laminin under stretching
AECs were cultured on elastomer membranes (Flexcell International) for 4 days. AEC matrix was prepared according to a previously published procedure and then incubated at 37°C for 60 minutes in an unfixed state using mAb 5C5 against the α3 laminin subunit (Langhofer et al., 1993). After thorough washing in PBS, the membrane was incubated in Alexa-Fluor-488-conjugated goat anti-mouse IgG for an additional 60 minutes at 37°C. The membrane was mounted in a StageFlexer system (Flexcell International) on the stage of a Leica DMRXA2 microscope (Leica Microsystems, Wetzlar, Germany) coupled to a Hamamatsu Orca-ER digital camera (Hamamatsu, Bridgewater, NJ). This allowed the fibers to be viewed while they were undergoing cyclic stretching. The membranes were stretched as described above and images captured using OpenLab in both stretched and unstretched conformations. Measurements of fiber length and areas between fibers were generated by identifying fiducial points in the images, which were subsequently analyzed using the MetaMorph Imaging System (Universal Imaging, Molecular Devices, Downingtown, PA) by examining the same networks under stretching and non-stretching conditions. Significant differences between experimental conditions were analysed using a two-way analysis of variance (ANOVA). When the ANOVA indicated a significant difference between groups, individual differences were explored with two-tailed paired Student's t-tests using the Bonferroni correction for multiple comparisons. A significant difference was prospectively identified as P<0.05.
Results
Primary AECs assemble a fibrous matrix enriched in perlecan, nidogen and laminin 6
To evaluate the potential role of extracellular matrix components in mechanotransduction in lung epithelial cells, we first characterized the composition of an extensive network of fibers that AECs deposit on their substrate (Figs 1, 2). At 2 days after plating, we detect small fibers, recognized by antibodies against perlecan along the substrate-attached surface of AECs (Fig. 1A). By contrast, antibodies against the β1, γ1 and α3 laminin subunits show either diffuse or punctate staining in the cells at the same focal plane at this time point (Fig. 1B; only perlecan and the β1-laminin-subunit staining is shown in this image). It should be realized that some of the β1-laminin-subunit-positive spots co-localize with the small fibers of perlecan (seen as yellow in Fig. 1C).
By day 4, perlecan appears in an extensive anastomosing network within the matrix of the cells (Fig. 1D). These perlecan-rich fibers are also stained by antibodies against the β1, γ1 and α3 laminin subunits and nidogen (Fig. 1E, Fig. 2A-F, Fig. 3). Other antibodies against laminin subunits, including those that recognize rat γ2 and β3 subunits, generate no obvious staining of cells at all time points we analysed, indicating that, in vitro, AECs fail to secrete a matrix rich in laminin 5 (α3β3γ2) (data not shown). Antibodies against the α5 laminin subunit [a component of laminins 10 and 11 (α5β1γ1 and α5β2γ1)] and the β2-laminin subunit [a component of laminins 7 and 11 (α3β2γ1 and α5β2γ1)] stain AEC cell bodies and show only weak, diffuse staining of the AEC matrix (Fig. 2J, only β2 laminin antibody staining is shown). Both α5 and β2 laminin subunit antibodies fail to stain the perlecan/nidogen/α3-laminin-subunit-rich fibers secreted by the cells (Fig. 2J-L, only β2-laminin antibody staining is shown). These data suggest that the laminin-positive fibers in the matrix of AECs are rich in laminin 6 but lack laminins 7, 10 and 11.
In support of the immunofluorescence data, western blotting confirms that primary AECs express a distinct subset of laminin subunits. Antibodies against α3, β1, β2 and γ1 laminin recognize proteins of 190 kDa and 160 kDa, 200 kDa, 190 kDa, and 200 kDa (respectively) in immunoblots of AEC extracts, whereas antibodies against other laminin subunits including γ2 and β3 show no obvious reactivity against the same protein preparation (Fig. 4). The latter antibodies, however, show strong reactivity with extracts derived from the rat bladder-cell line 804G, which is known to secrete a laminin-5-rich matrix (Baker et al., 1996; Langhofer et al., 1993) (Fig. 4A). It should be realized that we detect β2 laminin subunit in extracts of 804G cells even though this protein is not deposited into the matrix that 804G cells secrete onto their culture support (J. C. R. Jones et al., unpublished).
We have previously demonstrated that post-translational proteolytic processing of the α3 laminin subunit can alter cellular responses to laminin-rich matrix (Goldfinger et al., 1998). In whole-cell extracts of AECs, both unprocessed (190 kDa) and processed (160 kDa) α3 laminin subunit isoforms are present (Amano et al., 2000; Goldfinger et al., 1999; Goldfinger et al., 1998; Nguyen et al., 2000) (Fig. 4A). In sharp contrast to this, only processed α3 laminin subunit is detectable in AEC matrix, indicating that α3 laminin has undergone extracellular proteolytic cleavage in its G domain upon secretion (Amano et al., 2000; Goldfinger et al., 1999; Goldfinger et al., 1998; Nguyen et al., 2000) (Fig. 4B).
Matrix and matrix-receptor involvement in the transduction of mechanical signals
A major goal of our study was to investigate whether mechanotransduction in AECs might involve matrix-receptor complexes (Chen et al., 1999; Ingber, 2003; Meyer et al., 2000; Pavalko et al., 1998; Shyy and Chien, 2002). Indeed, we hypothesized that the fibrous nature of the matrix of AECs might facilitate the transduction of stretching stimuli to adherent cells if it were to deform upon mechanical stimulation. To evaluate this possibility experimentally, we first subjected native AEC matrix to an equibiaxial stretch regimen (a linear 10% elongation at a frequency of 30 cycles per minute, with a stretching:relaxation ratio of 1:1), which Correa-Meyer et al. have previously shown elicits specific signaling events in AECs (Correa-Meyer et al., 2002). We chose to stimulate the matrix of AECs mechanically at 4 days after plating because, by this time, the AECs have established the same extensive fibrillar matrix on elastomer membranes that we observe when the cells are plated onto glass coverslips (compare Figs 1, 2, 3 with Fig. 5). α3-Laminin subunits in unfixed, native AEC matrix were immunolabeled. The labeled preparation was visualized before stretching, during the stretching regimen mentioned previously and following stretching in liquid medium. An overlay of three images of the labeled matrix fibers under these distinct conditions is shown (Fig. 6A).
Before and after stretching, the α3-laminin-subunit-rich fibers show colocalization, whereas the same fibers are displaced from their non-stretched organization upon mechanical stimulation (Fig. 6A). Upon exposure to cyclic stretching, the overall shape of the matrix network is not appreciably altered (Fig. 6A). Indeed, this suggests that the matrix fibers adhere to the substrate continuously or at multiple, closely spaced, points along their length. It should also be realized that stretching causes no obvious damage to or fragmentation of the matrix.
We next derived measurements of the changes in area enclosed by the fibers (A/A0; where A is the area during stretching and A0 is the area before stretching) and the length of the fibers (L/L0; where L is the fiber length during stretching and L0 is the fiber length before stretching) in the matrix of AECs (Fig. 6B). Both fiber area and fiber length are increased significantly during stretching, and return more or less to the baseline after cessation of stretching.
When AECs are subjected to the stretching regimen mentioned above, p42/p44 MAPK undergoes activation within 15 minutes (Correa-Meyer et al., 2002). Hence, we were able to use this endpoint, in combination with a collection of function-blocking antibodies to define which particular matrix components play a role in stretching-induced signaling in AECs. AECs were washed with serum-free medium and then incubated in the same medium with antibody or control immunoglobulin for 24 hours before applying the regimen of cyclic stretching. Extracts of cells were processed for immunoblotting using antibodies that recognize activated p42/p44 MAPK, and then reprobed with antibodies against total p42/p44 MAPK. We show pairs of images of one representative immunoblot and quantification of at least three trials of each experimental treatment (Fig. 7).
Inhibiting the function of the α3 laminin subunit results in a ∼40% decrease in stretching-induced p42/p44 MAPK phosphorylation (Baker et al., 1996) (Fig. 7A,B). By contrast, blocking the function of either α3 or β1 integrin with antibody antagonists has no obvious impact on stretching-activated p42/p44 MAPK phosphorylation (Fig. 7A,B). These same inhibitors are functionally active against rat integrins in our hands, because both inhibit rat 804G bladder-cell adhesion to laminin 5 in a 30 minute adhesion assay (J. C. R. Jones, unpublished).
Our data showing expression of dystroglycan by AECs suggest that dystroglycan might function as a receptor for the perlecan/laminin-6 complexes (Fig. 4C). This hypothesis is supported by the observation that the α-dystroglycan function-perturbing antibody IIH6 effectively inhibits stretching-induced MAPK activation in AECs by about 30% (Michele and Campbell, 2003) (Fig. 7A,B). To confirm this result, we infected AECs 2 days after plating with adenovirus encoding shRNA to knockdown specifically the production of dystroglycan (Fig. 7C) (Elbashir et al., 2002). Knockdown of dystroglycan is >90% in AECs 2 days after infection (Fig. 7C). At the same time, we then assayed dystroglycan-shRNA and control-shRNA-expressing cells for MAPK activity following stretch (Fig. 7B). MAPK activation is inhibited by at least 50% in AECs in which production of dystroglycan is knocked down compared with untreated cells and cells expressing control shRNA (Fig. 7B).
It should be realized that AECs show no obvious morphological perturbation, including detachment or rounding, following treatment with any of the function-perturbing antibodies we used in these studies, or following treatment with adenovirus (not shown). Furthermore, laminin-6-fiber organization is not perturbed by our antibody or viral regimens. Moreover, the same approximate amount of total cell protein is collected from cultures of untreated cells and cells treated with antibodies or adenovirus at the conclusion of the stretch regimen (not shown). Together, these results indicate that no obvious loss or death of cells is caused by antibody incubation or viral infection.
Irrelevant IgG and IgM treatment has no impact on activation of MAPK in AECs subject to stretching (not shown). We have performed several other control studies to assess the specificity of matrix molecule involvement in transducing mechanical signals in the AECs. For example, AECs 3 days after plating were incubated with an excess of RGD-containing peptide in serum-free medium and then, 24 hours later, the treated cells were subjected to stretch (Fig. 7B). This peptide is a competitive inhibitor of the receptor-binding site on matrix molecules including fibronectin and vitronectin for several β1- and β3-subunit-containing integrin-family members (Hynes, 1992). The RGD-containing peptide does not inhibit stretching-induced p42/p44 MAPK activation in AECs, indicating that RGD-binding integrins, including α5β1 and αvβ3, are not involved in mediating signaling in the stretched cells. Rather, our results suggest roles for laminin-6, the proteoglycan perlecan and dystroglycan in mediating stretching-induced signaling in AECs.
Discussion
The alveolar cells of the lung lie on a basement membrane composed of a complex of matrix proteins (Miner et al., 1997; Nguyen et al., 2002). In the intact lung, the production of laminin subunits is developmentally regulated. For example, the α1 and α2 subunits are expressed in fetal lungs, whereas α3, α4 and α5 laminin subunits are found in both fetal and adult lungs. Previous workers have shown that both α3 and α5 laminin subunits are produced by cultured rat AECs (Pierce et al., 1998). However, the exact identity of the α3-subunit-containing laminin heterotrimer in the matrix of AECs has not been reported. Here, we provide the first evidence that the α3 laminin subunit is secreted by cultured rat AECs in cable-like structures. Moreover, we detect the β1 and γ1, but not the γ2, β2 and β3 laminin subunits, localized with the α3 laminin subunit in these cables, indicating that the rat cells are generating a laminin-6-rich matrix. To our knowledge, this is the first identification of a cell type that secretes a laminin-6-rich matrix in the absence of laminin 5 or 7 in vitro. Moreover, we have been able to use AECs to study not only the precise organizational state of laminin 6 in the extracellular matrix but also the role of laminin 6 as a mediator of signaling.
Laminin heterotrimers assemble into polymeric matrix arrays in distinct ways in different cultured cell types. For example, in the rat epithelial cell line 804G, laminin 5 assembles into a “cat's-paw” array, whereas the same molecule assembles in cloud-like arrays, arcs and circles in the matrix of keratinocytes (deHart et al., 2003; Langhofer et al., 1993). By contrast, laminin 1 assembles as a reticular network on the surface of muscle cells (Colognato et al., 1999), and the organizational state of laminin 6 in AEC matrix resembles this. Exactly how laminin 6 assembles into cable-like structural arrays remains to be determined. However, our time-course studies suggest that perlecan is laid down in a fibrillar organization before laminin 6. Indeed, we speculate that AECs first assemble fibers of perlecan whose distribution subsequently determines the arrangement of laminin 6. Perlecan is certainly capable of doing so via an interaction with nidogen, which cross-links the immunoglobulin-like domain 3 of perlecan with an epidermal-growth-factor-like repeat within the laminin γ1 subunit (Kvansakul et al., 2001; Mayer et al., 1993; Ries et al., 2001). In support of this, we show that nidogen codistributes with perlecan and the subunits of laminin 6 in the matrix of AECs.
The fibrous nature of perlecan/nidogen/laminin-6-rich complexes in the matrix of AECs led us to ask whether these fibers provide the structural means for cells to resist and/or respond to mechanical stresses. Indeed, by visualizing labeled fibers, we have shown that the fibers adhere to the matrix at sites sufficiently close to one another to result in isotropic expansion during stretching. Hence, the ability of fibers rich in laminin 6 to respond to stretching by undergoing a precise deformation makes them ideal transducers of force from the outside to the inside of cells, initiating signaling cascades that, in turn, trigger specific physiological responses (Gillespie and Walker, 2001). To test this hypothesis, we used activation of the p42/p44 MAPK pathway as our endpoint. This important cytoprotective signal pathway is maximally activated within 15 minutes of the initiation of cyclic stretching in AECs (Correa-Meyer et al., 2002). Using an antibody that we have previously shown to bind to and inhibit the function of the α3 laminin subunit, we have provided evidence that laminin 6 is one link in the molecular pathway that transmits an outside-in mechanical signal (Baker et al., 1996). It should be realized that this pathway is distinct from the recently detailed growth-factor-receptor circuitry involved in mechanical signaling in bronchial airway cells (Tschumperlin et al., 2004).
We initially assumed that laminin 6 would transduce a signal via its interaction with an integrin at the surface of AECs, because the role of integrins in signal transduction is well established (Howe et al., 1998; Hynes, 1992; Hynes, 2002). There are several potential integrin receptors for laminins containing the α3 laminin subunit, including the integrin heterodimers α6β4, α3β1 and α6β1 (Carter et al., 1991; Jones et al., 1998). Our primary AECs do not produce the β4 integrin subunit, as assessed by immunoblotting and immunofluorescence using a polyclonal antibody against the β4 integrin subunit that recognizes β4 integrin in rat bladder cells (not shown). By contrast, rat AECs produce β1-containing integrin heterodimers. Thus, we focused on testing the hypothesis that β1-subunit-containing integrin heterodimers mediate the signal initiated by stretching that impacts MAPK activation in AECs. We did so using an antibody that inhibits rat β1-integrin function. However, function-perturbing antibodies against both β1 and α3 integrins, as well as the RGD peptide, which inhibit the activity of a range of integrin receptors, fail to block stretching-induced p42/p44 MAPK activation in AECs (Hynes, 1992; Hynes, 2002).
If integrins are not involved in mediating mechanical signaling in AECs, what senses matrix deflections at the surface of these cells? A candidate receptor for mediating laminin-6 signaling is dystroglycan. Dystroglycan is best known as a component of the dystrophin-glycoprotein complex, whose absence or abnormality leads to muscular dystrophies and several types of cardiomyopathy (Michele and Campbell, 2003). This complex plays a structural role in muscle by forming a mechanically strong link between the sarcolemma and actin, but whether it transduces signals is controversial (Michele and Campbell, 2003; Rybakova et al., 2000; Spence et al., 2004). When bound to laminin, dystroglycan is reported to inhibit MAPK activation (Ferletta et al., 2003). In epithelial cells, the functions of dystroglycan are not clear, although it is believed to be primarily a structural protein involved in basement-membrane assembly, growth control, cytoskeleton organization, development of cell polarity and epithelial morphogenesis (Durbeej et al., 2001; Muschler et al., 2002).
Our study provides the first evidence that dystroglycan is a component of a distinct molecular pathway that transduces mechanical signals from the outside to the inside of AECs. The binding site for dystroglycan on laminins resides within the C-terminal G-domain modules of the α laminin subunit (Ido et al., 2004). Hence, because the α3 subunit lacks these modules, we presume that dystroglycan does not directly bind laminin 6 in the matrix of AECs (Ferletta et al., 2003; Timpl et al., 2000; Yu and Talts, 2003). Rather, dystroglycan probably interacts with the perlecan secreted by AECs. Indeed, previous biochemical data and the results of the present study support a model for integrin-independent, matrix-driven mechanotransduction in AECs. In our model, perlecan binds dystroglycan located in the membrane of AECs and interacts with laminin 6 in the matrix via nidogen (Talts et al., 1999) (Fig. 8). Moreover, our data indicate that stretching induces deformational changes in the supramolecular organization of the copolymers of laminin 6 and perlecan. Furthermore, we hypothesize that the proteoglycan perlecan relays these changes at the surface of AECs via its interaction with dystroglycan. At the surface of AECs, dystroglycan is the direct mediator of mechanical signaling and activates p42/p44 MAPK (Fig. 8). The ability of dystroglycan to regulate MAPK might relate to their existence as a complex at the cell surface, evidence for which has recently been reported (Spence et al., 2004).
In summary, analyses of AECs and their response to stretching support a major role for dystroglycan in mediating integrin-independent, matrix-driven mechanotransduction in AECs. Our studies hold implications not only for the ways epithelial cells sense and respond to mechanical stimulation in general but also for the pathophysiology of certain lung diseases. Specifically, AECs undergo stretching when the lung is mechanically ventilated with high lung volumes. This might be injurious, leading to the failure of the epithelial sheet that covers the lung surface (Liu et al., 1999). Our results suggest that mechanically induced MAPK activation functions as a protective mechanism to ameliorate potential damage caused by overdistention of AECs. There is precedent for this because activation of MAPK pathways is known to promote the survival of several cell types, most notably in the nervous and immune systems (Bonni et al., 1999; Holmström et al., 2000). Defining the precise molecular pathway(s) by which AECs respond to mechanical stretching and elicit survival signals might lead to the design of strategies to protect the alveolar epithelium against injury induced by positive-pressure ventilation (Matthay et al., 2003; Sznajder, 2001).
Acknowledgements
This work was supported by grants RO1 DK60589 (J.C.R.J.) and PO1 HL 071643 (J.C.R.J., S.B., D.A.D. and J.I.S.) from the NIH. We are grateful to the Core of the latter grant for providing cells for our studies. We thank M. Glucksberg and T.-L. Chew for their great help in data analyses. We are most grateful to P. Yurchenco for his generous gift of antibodies.