Airway epithelial cell migration dynamics. MMP-9 role in cell-extracellular matrix remodeling.

Cell spreading and migration associated with the expression of the 92-kD gelatinase (matrix metalloproteinase 9 or MMP-9) are important mechanisms involved in the repair of the respiratory epithelium. We investigated the location of MMP-9 and its potential role in migrating human bronchial epithelial cells (HBEC). In vivo and in vitro, MMP-9 accumulated in migrating HBEC located at the leading edge of a wound and MMP-9 expression paralleled cell migration speed. MMP-9 accumulated through an actin-dependent pathway in the advancing lamellipodia of migrating cells and was subsequently found active in the extracellular matrix (ECM). Lamellipodia became anchored through primordial contacts established with type IV collagen. MMP-9 became amassed behind collagen IV where there were fewer cell-ECM contacts. Both collagen IV and MMP-9 were involved in cell migration because when cell-collagen IV interaction was blocked, cells spread slightly but did not migrate; and when MMP-9 activation was prevented, cells remained fixed on primordial contacts and did not advance at all. These observations suggest that MMP-9 controls the migration of repairing HBEC by remodeling the provisional ECM implicated in primordial contacts.

Distribution of a1(IV) and a3(IV) chains of type IV collagen in lung tumours.

Tumour invasion is associated with strong remodelling of the extracellular matrix, including the basement membrane (BM). The major structural component of BMs is type IV collagen, which is composed of an association of three a chains. In this study, the distribution of the a1 and a3 chains in both normal and neoplastic lung tissues has been examined by immunohistochemistry, using specific monoclonal antibodies. In normal tissues, the a1(IV) chain was found in all BMs, whereas the a3(IV) chain was only found in alveolar BMs. In 36 lung tumours, the a1(IV) chain was detected in all cases, with irregular positivity around tumour clusters and in the stroma. It was noteworthy that this stromal distribution was particularly associated with the presence of cancer cells, whatever their invasive properties. In contrast, in 22 tumours out of 36, the a3(IV) chain was only found at the interface between invasive tumour clusters and stroma, with a linear and disrupted pattern. These data show a distinctive distribution of type IV collagen chains in lung tumours, with expression of a1(IV) chain and likely neosynthesis of the a3(IV) chain around some invasive tumour clusters. The results suggest the involvement of these BM components in the process of tumour invasion.

Wound repair-induced expression of a stromelysins is associated with the acquisition of a mesenchymal phenotype in human respiratory epithelial cells.

Wound repair involves many processes including cell migration, provisional matrix deposition, and remodeling. All of these processes are likely to be affected by matrix-modifying enzymes. Members of the matrix metalloproteinases family are physiologic mediators of the extracellular matrix degradation. Within this matrix metalloproteinases family, stromelysins can degrade many components of the extracellular matrix. We therefore tested the hypothesis that stromelysins could be produced by human surface respiratory epithelial (HSRE) cells repairing a wound. Experimental wounds were created in vitro in HSRE cell cultures and in situ in human bronchial mucosa maintained in organ culture. Stromelysin production was measured by casein-gel zymography in cellular protein extracts derived from repairing migratory and nonrepairing stationary cells of wounded HSRE cell cultures. Stromelysin-producing cells present in cell and tissue cultures were localized and characterized using immunofluorescence techniques. Zymographic and immunofluorescence techniques showed that stromelysins were produced exclusively by the migratory HSRE cells. Zymogram analysis showed that stromelysins were overexpressed and overactivated during the wound repair process, with the maximal production observed at wound closure. Using an anti-cytokeratin 14 antibody, we identified stromelysin-3-producing cells as basal epithelial cells. Moreover, most stromelysin-3-producing cells expressed the mesenchymal marker vimentin. Similar to stromelysins localization, vimentin-positive HSRE cells were exclusively located in the wounded area, and they were also positive to cytokeratin 14. In conclusion, stromelysins are suggested to be involved in HSRE cell migration and extracellular matrix remodeling during wound repair. Furthermore, stromelysin production by repairing HSRE cells is linked to the acquisition of a mesenchymal phenotype. HSRE cell migration may then be associated with the shift from an epithelial to a mesenchymal phenotype.

Gelatinase B is involved in the in vitro wound repair of human respiratory epithelium.

Following epithelial injury, extracellular matrix undergoes imposing remodelings. We examined the contribution of matrix metalloproteinases, gelatinases A and B, in an in vitro wound repair model of human respiratory epithelium. Confluent human surface respiratory epithelial (HSRE) cells cultured from dissociated surface cells of human nasal polyps were chemically injured. Over the next 3 to 5 days, cells migrated onto the injured area to repair the circular wound. Repair kinetics of these wounds was monitored until wound closure occurred. Gelatinolytic activities were analysed in culture supernates and in cell protein extracts derived from repairing migratory and non repairing stationary cells. Small amounts of gelatinase A were expressed by HSRE cells, and variations of this gelatinase remained very weak for the time of the wound repair. In contrast, gelatinase B was upregulated during the wound repair process, with a maximum peak observed at wound closure. A marked gelatinase B activation occurred only in cells involved in the repair process. Gelatinase B was localized in some migratory basal cells, recognized by an anti-cytokeratin 14 antibody and located around the wound. We could not detect any gelatinase A in repairing or in stationary HSRE cells. Addition of the 6-6B monoclonal antibody, known to inhibit gelatinase B activation, to the culture medium during the repair process resulted in a dose-dependent decrease of the wound repair speed. These results suggest that gelatinase B, produced by epithelial cells, actively contributes to the wound repair process of the respiratory epithelium.

Glandular-like morphogenesis and secretory activity of human tracheal gland cells in a three-dimensional collagen gel matrix.

The extracellular matrix has been demonstrated to affect the differentiation of epithelial cells. We present evidence that in a three-dimensional (3-D) type I collagen gel matrix, isolated human adult tracheal gland (HTG) cells are capable of reconstructing new functional gland-like tubules in vitro. During the first two weeks in culture, HTG cells developed globular epithelial cell aggregates in which lumina is absent. By the third week in culture, the tubulogenesis and the formation of branching structures became evident with a polarized morphology, which in many aspects resembles the in vivo morphology. A central lumen was lined by polarized secretory epithelial cells exhibiting well-developed microvilli and apical secretory granules. Furthermore, we showed that the capacity of in vitro tracheal gland differentiation was associated with the basal deposition of laminin and type IV collagen around the gland-like tubules. A cell-associated 72 kDa type IV collagenase was expressed in developing tubule cells, as shown by immunocytochemistry. The secretion of the antileucoprotease (ALP), a protein marker of tracheal gland serous cells, was bidirectional in gland-like tubules, since up to 65% of released ALP was in the basolateral direction. Taken together, these observations indicate that isolated HTG cells in a 3-D collagen matrix form functional tracheal gland-like tubules and suggest that similar new tracheobronchial gland formations may occur during the human normal gland development and remodeling.