Adenovirus vector expressing keratinocyte growth factor using CAG promoter impairs pulmonary function of mice with elastase-induced emphysema.

Pulmonary emphysema impairs quality of life and increases mortality. It has previously been shown that administration of adenovirus vector expressing murine keratinocyte growth factor (KGF) before elastase instillation prevents pulmonary emphysema in mice. We therefore hypothesized that therapeutic administration of KGF would restore damage to lungs caused by elastase instillation and thus improve pulmonary function in an animal model. KGF expressing adenovirus vector, which prevented bleomycin-induced pulmonary fibrosis in a previous study, was constructed. Adenovirus vector (1.0 × 109 plaque-forming units) was administered intratracheally one week after administration of elastase into mouse lungs. One week after administration of KGF-vector, exercise tolerance testing and blood gas analysis were performed, after which the lungs were removed under deep anesthesia. KGF-positive pneumocytes were more numerous, surfactant protein secretion in the airspace greater and mean linear intercept of lungs shorter in animals that had received KGF than in control animals. Unexpectedly, however, arterial blood oxygenation was worse in the KGF group and maximum running speed, an indicator of exercise capacity, had not improved after KGF in mice with elastase-induced emphysema, indicating that KGF-expressing adenovirus vector impaired pulmonary function in these mice. Notably, vector lacking KGF-expression unit did not induce such impairment, implying that the KGF expression unit itself may cause the damage to alveolar cells. Possible involvement of the CAG promoter used for KGF expression in impairing pulmonary function is discussed.

Keratinocyte growth factor gene transduction ameliorates pulmonary fibrosis induced by bleomycin in mice.

Pulmonary fibrosis has high rates of mortality and morbidity, but there is no established therapy at present. We demonstrate here that bleomycin-induced pulmonary fibrosis in mice is ameliorated by intratracheal administration of keratinocyte growth factor (KGF)-expressing adenovirus vector. Progressive pulmonary fibrosis was created by continuous subcutaneous administration of 120 mg/kg of bleomycin subcutaneously using an osmotic pump twice from Day 1 to 7 and Day 29 to 35. The mice initially exhibited subpleural fibrosis and then exhibited advanced fibrosis in the parenchyma of the lungs. These histopathological changes were accompanied by reduced lung compliance (0.041 ± 0.011 versus 0.097 ± 0.004; P < 0.001), reduced messenger expression of surfactant proteins, and reduced KGF messenger expression in the lungs at 4 weeks compared with naive group. Intratracheal instillation of Ad-KGF at 1 week after the first administration of bleomycin increased KGF mRNA expression in the lungs compared with the fibrosis-induced mice that received saline alone. The phenotype was associated with alveolar epithelial cell proliferation, increased pulmonary compliance (0.062 ± 0.005 versus 0.041 ± 0.011; P = 0.023), and decreased mortality (survival rate on Day 56: 68.8% versus 0%; P = 0.002), compared with mice receiving only the saline vehicle. These observations suggest the therapeutic utility of a KGF-expressing adenoviral vector for pulmonary fibrosis.

Keratinocyte growth factor gene transduction ameliorates acute lung injury and mortality in mice.

At present there is no known effective pharmacological therapy for acute lung injury (ALI). Because keratinocyte growth factor (KGF) promotes epithelial cell growth, intratracheal administration of KGF has the possibility of restoring lung tissue integrity in injured lungs and improving patient outcomes. However, treatment using recombinant KGF protein is limited by its short effective duration. Thus, we investigated the effectiveness of intratracheal KGF gene transduction using adenoviral vector in ALI. We constructed an adenoviral vector expressing mouse KGF (mKGF), and 1.0 x 10(9 ) plaque-forming units of mKGF cDNA-expressing (Ad-KGF) and control (Ad-1w1) adenoviral vector was intratracheally instilled, using a MicroSprayer, into anesthetized BALB/c mice. Three days later, the mice were exposed to >90% oxygen for 72 hr, and the effect of KGF on hyperoxia-induced lung injury was examined. In the Ad-KGF group, KGF was strongly expressed in the airway epithelial cells, while peribronchiolar and alveolar inflammation caused by adenoviral vector instillation was minimal. The KGF overexpression not only induced proliferation of surfactant protein C-positive cuboidal cells, especially in the terminal bronchiolar and alveolar walls, but also prevented lung injury including intraalveolar exudation/hemorrhage, albumin permeability increase, and pulmonary edema. The arterial oxygen tension and the survival rate were significantly higher in the KGF-transfected group. These findings suggest that KGF gene transduction into the airway epithelium is a promising potential treatment for ALI.