In the normal respiratory tract, the airway epithelial surface is protected from pathogenic bacterial colonization by the mucociliary clearance. The mucins present in the gel mucus layer exhibit a high diversity of carbohydrate receptors that allow specific bacterial recognition followed by bacterial and mucus elimination. As soon as the mucociliary clearance mechanism is impaired, the bacterial attachment to mucins in association with mucus stasis represent critical pathways for bacterial colonization of the airway epithelium. Several sources of injury may damage the epithelial integrity and induce partial or complete epithelial shedding, exposing cellular receptors and unmasked extracellular matrix (ECM) components that can be recognized by bacterial adhesins. Laminin and type I and IV collagens represent sites of Pseudomonas aeruginosa attachment to the ECM components. During airway epithelium repair after injury, particularly in cystic fibrosis (CF), the repairing cells exhibit apical receptors such as asialylated gangliosides (asialo GM1) to which P. aeruginosa adheres. The identification of the different receptors for P. aeruginosa, present either on the ECM proteins or on the apical surface of the remodeled airway epithelium, particularly in repairing respiratory CF epithelial cells, is a prerequisite to further therapeutic strategies to prevent airway colonization by P. aeruginosa.
The respiratory mucus is a very complex biological material, which possesses both flow and deformation rheological properties, characterized by non-linear and time-dependent viscoelasticity and physical properties of adhesiveness and wettability. Viscosity and elasticity are directly involved in the transport capacity of mucus, whereas wettability and adhesiveness contribute to the optimal interface properties between the mucus and the epithelial surface. Optimal conditions for the protective and lubricant properties of respiratory mucus are represented by high wettability, and adhesiveness high enough not to induce flow of mucus in the respiratory bronchioles under gravity but low enough to mobilize mucus by airflow during coughing. An intermediate viscoelasticity is also required for an optimal mucociliary transport. Different biochemical constituents such as glycoproteins, proteins, proteoglycans and lipids are involved in the gel properties of respiratory mucus. During bronchial infection and particularly in cystic fibrosis, the loss of water and the increase in macromolecules result in a marked increase in viscosity and adhesiveness responsible for the mucus transport impairment. The various lipids present in mucus contribute differently to the physicochemical properties. Surface-active phospholipids, such as phosphatidylcholine and phosphatidylglycerol improve the wettability of mucus, whereas neutral lipids and glycosphyngolipids contribute to the hyperviscosity of mucus during infection. Phospholipids and associated mucins are also implicated in the interaction between bacteria and epithelial cells. Therefore, the respiratory mucus needs appropriate physicochemical properties for the protection, hydration and lubrication of the underlying airway epithelium.
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