Knockout of insulin-like growth factor-1 receptor impairs distal lung morphogenesis.

BACKGROUND: Insulin-like growth factors (IGF-I and -II) are pleiotropic regulators of somatic growth and development in vertebrate species. Endocrine and paracrine effects of both hormones are mediated by a common IGF type 1 receptor (IGF-1R). Lethal respiratory failure in neonatal IGF-1R knockout mice suggested a particular role for this receptor in pulmonary development, and we therefore investigated the consequences of IGF-1R inactivation in lung tissue. METHODS AND FINDINGS: We first generated compound heterozygous mutant mice harboring a hypomorphic (Igf1r(neo)) and a null (Igf1r(-)) allele. These IGF-1R(neo/-) mice express only 22% of normal IGF-1R levels and are viable. In adult IGF-1R(neo/-) mice, we assessed lung morphology and respiratory physiology and found normal histomorphometric characteristics and normal breathing response to hypercapnia. We then generated homozygous IGF-1R knockout mutants (IGF-1R(-/-)) and analyzed their lung development during late gestation using histomorphometric and immunohistochemical methods. IGF-1R(-/-) embryos displayed severe lung hypoplasia and markedly underdeveloped diaphragms, leading to lethal neonatal respiratory distress. Importantly, IGF-1R(-/-) lungs from late gestation embryos were four times smaller than control lungs and showed markedly thickened intersaccular mesenchyme, indicating strongly delayed lung maturation. Cell proliferation and apoptosis were significantly increased in IGF-1R(-/-) lung tissue as compared with IGF-1R(+/+) controls. Immunohistochemistry using pro-SP-C, NKX2-1, CD31 and vWF as markers revealed a delay in cell differentiation and arrest in the canalicular stage of prenatal respiratory organ development in IGF-1R(-/-) mutant mice. CONCLUSIONS/SIGNIFICANCE: We found that low levels of IGF-1R were sufficient to ensure normal lung development in mice. In contrast, complete absence of IGF-1R significantly delayed end-gestational lung maturation. Results indicate that IGF-1R plays essential roles in cell proliferation and timing of cell differentiation during fetal lung development.

Deficiency in type 1 insulin-like growth factor receptor in mice protects against oxygen-induced lung injury.

BACKGROUND: Cellular responses to aging and oxidative stress are regulated by type 1 insulin-like growth factor receptor (IGF-1R). Oxidant injury, which is implicated in the pathophysiology of a number of respiratory diseases, acutely upregulates IGF-1R expression in the lung. This led us to suspect that reduction of IGF-1R levels in lung tissue could prevent deleterious effects of oxygen exposure. METHODS: Since IGF-1R null mutant mice die at birth from respiratory failure, we generated compound heterozygous mice harboring a hypomorphic (Igf-1rneo) and a knockout (Igf-1r-) receptor allele. These IGF-1Rneo/- mice, strongly deficient in IGF-1R, were subjected to hyperoxia and analyzed for survival time, ventilatory control, pulmonary histopathology, morphometry, lung edema and vascular permeability. RESULTS: Strikingly, after 72 h of exposure to 90% O2, IGF-1Rneo/- mice had a significantly better survival rate during recovery than IGF-1R+/+ mice (77% versus 53%, P < 0.05). The pulmonary injury was consistently, and significantly, milder in IGF-1Rneo/- mice which developed conspicuously less edema and vascular extravasation than controls. Also, hyperoxia-induced abnormal pattern of breathing which precipitated respiratory failure was elicited less frequently in the IGF-1Rneo/- mice. CONCLUSION: Together, these data demonstrate that a decrease in IGF-1R signaling in mice protects against oxidant-induced lung injury.