The respiratory epithelium is frequently injured by inhaled toxic agents or by micro-organisms. The epithelial wound repair represents a crucial process by which surface respiratory cells maintain the epithelial barrier integrity. The repair process involves both cell migration and proliferation, but as yet, the kinetic of these two mechanisms has not been extensively studied. Using an in vitro model of human respiratory epithelium wound repair, proliferative cell immunofluorescent staining and a computer-assisted technique allowing the tracking of living cells, we studied the cell proliferation and migration during the wound repair process. Respiratory epithelial cells were dissociated from human nasal polyps and cultured on a collagen I matrix. At confluency, a chemical wound was made on the culture. We observed that the cell mitotic activity peaked at 48 h after wounding (23% of the cells) and mainly concerned the cells located 160 to 400 µm from the wound edge. The migration speed was highest (35 to 45 µm/h) for the spreading cells at the wound edge and progressively decreased for the cells more and more distant from the wound edge. The temporal analysis of the cell migration speed during the wound repair showed that it was almost constant during the first 3 days of the repair mechanism and thereafter dropped down until the wound closure was completed (after 4 days). We also observed that over a 1-hour period, the intra-individual and interindividual variation of the cell migration speed was 43% and 37%, respectively. These results demonstrate that cell proliferation and cell migration during respiratory epithelial wound repair are differently expressed with regard to the cell location within the repairing area.
The cell migration that occurs during wound repair is dependent on modifications of the cell-matrix interaction in which extracellular matrix proteins and their receptors, the integrins, are involved. To study the interactions between airway epithelial cells and the extracellular matrix during the process of wound repair, we developed an in vitro wound model of human epithelial cells. Surface epithelial cells were dissociated from human nasal polyps and cultured on a type I collagen matrix. At confluency, a wound was made by the addition of 2 microliters of NaOH (1 N) to the cell culture. After the cell culture was washed, the wound area was recorded every 12 h for 96 h by a videomicroscopic technique. We calculated the wound-repair index that represents the decrease in the wound area per hour. Using immunofluorescence techniques, we first examined the localization, during wound repair, of fibronectin and of the beta 1-, alpha v-, alpha 2-, alpha 3-, and alpha 5-integrin subunits. Secondly, we carried out a series of wound-repair blocking experiments with the use of anti-integrin or anti-fibronectin antibodies diluted in the culture medium. We observed that fibronectin and the alpha 5- integrin subunit were exclusively expressed by the migratory cells in the wounded area. No difference in the localization of the alpha v-, alpha 2-, and alpha 3-integrin subunits was observed between the nonrepairing and repairing cells. The blocking experiments showed a significant decrease in the wound-repair index in the presence of either the anti-beta 1, -alpha 3, alpha 5, or the anti-fibronectin antibodies. Furthermore, the addition of fibronectin to the culture medium induced a significant increase in the wound repair index. These results suggest that fibronectin and the corresponding alpha 5 beta 1-integrin play an important role in the process of airway epithelium wound repair.
The surface epithelium of the airway mucosa forms a continuous barrier to a wide number of noxious substances present in the lumen. The restoration of the barrier integrity after injury represents a key issue in the defense capacity of the airway epithelium. Using an in vitro wound repair model of the airway epithelium, we investigated the dynamic of the restoration of the epithelial barrier integrity during the wound repair process. Airway epithelial cells in culture were chemically wounded by sodium hydroxide. The immunolocalization of zonula occludens 1 (ZO-1), a cytoplasmic protein associated with the tight junctions, was examined during the wound repair process. Junctional integrity was examined by analyzing the transepithelial resistance (TER) and the permeability to [3H]mannitol and by visualizing the permeability to lanthanum nitrate during 5 days after injury. Immediately after injury, we simultaneously observed a 36.7% decrease in the TER and a 74.9% rise in the permeability to [3H]mannitol. In addition, lanthanum nitrate penetrated in the intercellular spaces in the repairing areas, which was also characterized by the absence of ZO-1 staining, as opposed to nonrepairing cells. TER and [3H]mannitol flux values as well as lanthanum nitrate and ZO-1 localizations were found to be similar to those observed in confluent cultures only 1 to 2 days after complete wound closure. This study demonstrates that using our culture model, confluent airway epithelial cells form a continuous and efficient barrier with tight junctions. Epithelial integrity is affected immediately after injury and is completely restored within 1 to 2 days after wound closure. During such a period of time, the airway epithelium may remain exposed to the noxious effect of environment in vivo, which can prevent the epithelial barrier restoration by modifying tight junction formation.
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