Lung development and the pulmonary surfactant system: Hormonal influences

Hitchcock, Karen R.

doi:10.1002/ar.1091980103

Cited by 46 publications

(26 citation statements)

References 304 publications

(180 reference statements)

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“…Extracted samples were dried completely under a stream of air, reconstituted in 1 mL of chloroform and mixed with 9 mL of scintillation fluid. Counts for 3 [H] were obtained as cpm using a Wallac 1409 liquid scintillation counter. Data were expressed as percent surfactant release using the following calculation: [cpm in the extracted media/cpm in the extracted media ϩ cpm in the extracted cells] ϫ 100.…”

Section: Methodsmentioning

confidence: 99%

“…The release of surfactant by ATII cells is a highly coordinated process that is regulated by numerous circulating factors (1)(2)(3). Previous studies have demonstrated that the hormone atrial natriuretic peptide (ANP) is capable of modulating ATII cell function in the adult (4); however, its role in regulating surfactant release in the perinatal period is unknown.…”

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confidence: 99%

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Ontogeny of Atrial Natriuretic Peptide and Its Receptor In the Lung: Effects on Perinatal Surfactant Release

et al. 2008

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ABSTRACT:During the transition at birth to air breathing, regulation of surfactant release from alveolar type II (ATII) cells is critical. Atrial natriuretic peptide (ANP) stimulates natriuretic peptide receptor-A (NPR-A) and increases intracellular cGMP. We examined the changes in ANP and NPR-A in respiratory epithelium during the perinatal period using immunohistochemistry and studied the effect of ANP on surfactant release from ATII cells isolated from fetal and newborn lambs. NPR-A mRNA was detected in the fetal lung by Northern Blot and RT-PCR. At 100 d gestation (term 145 d), ANP staining was absent and NPR-A staining was weak in cuboidal epithelial cells. ANP and NPR-A staining was prominent in ATII cells at 136 d gestation and was undetectable postnatally. ANP stimulated (maximal effect at 10 Ϫ10 M) surfactant release from both late gestation fetal and neonatal ATII cells. Protein kinase G inhibition significantly blocked this release. We conclude that ANP stimulates surfactant release in isolated perinatal ATII cells by a cGMPdependent mechanism. ANP and NPR-A expression in ATII cells is greatest in late gestation and declines sharply postnatally. We speculate that increased activity of the ANP/NPR-A pathway in late gestation may prime the surfactant system, preparing the lung for air breathing. (Pediatr Res 63: 239-244, 2008)

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Section: Methodsmentioning

confidence: 99%

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confidence: 99%

Ontogeny of Atrial Natriuretic Peptide and Its Receptor In the Lung: Effects on Perinatal Surfactant Release

et al. 2008

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“…GC therapy is widely used in the prenatal and postnatal periods either as a prophylactic or curative measure. Use of prenatal GCs is often motivated by the observed positive effects on lung maturation and surfactant production in preterm babies (1,2), who otherwise stand a high chance of developing respiratory distress syndrome (3) and subsequent chronic lung disease, also known as bronchopulmonary dysplasia (4,5). The positive effects of postnatal GCs on pulmonary inflammatory processes (6,7) and the prophylactic effects against hyperoxic lung injury (8) seem to improve the survival chances of preterm neonates.…”

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confidence: 99%

Effects of Neonatal High-Dose Short-Term Glucocorticoid Treatment on the Lung: A Morphologic and Morphometric Study in the Rat

Tschanz

2003

Pediatric Research

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Glucocorticoids are often applied in neonatology and perinatology to fight the problems of respiratory distress and chronic lung disease. There are, however, many controversies regarding the adverse side effects and long-term clinical benefits of this therapeutic approach. In rats, glucocorticoids are known to seriously impair the formation of alveoli when applied during the first two postnatal weeks even at very low dosage. The current study investigates short-term and long-term glucocorticoid effects on the rat lung by means of morphologic and morphometric observations at light and electron microscopic levels. Application of a high-dosage protocol for only few days resulted in a marked acceleration of lung development with a precocious microvascular maturation resulting in single capillary network septa in the first 4 postnatal days. By postnatal d 10, the lung morphologic phenotype showed a step back in the maturational state, with an increased number of septa with double capillary layer, followed by an exceptional second round of the alveolarization process. As a result of this process, there was an almost complete recovery in the parenchymal lung structure by postnatal d 36, and by d 60, there were virtually no qualitative or quantitative differences between experimental and control rats. These findings indicate that both dosage and duration of glucocorticoid therapy in the early postnatal period are very critical with respect to lung development and maturation and that a careful therapeutic strategy can minimize late sequelae of treatment. GC therapy is widely used in the prenatal and postnatal periods either as a prophylactic or curative measure. Use of prenatal GCs is often motivated by the observed positive effects on lung maturation and surfactant production in preterm babies (1, 2), who otherwise stand a high chance of developing respiratory distress syndrome (3) and subsequent chronic lung disease, also known as bronchopulmonary dysplasia (4, 5). The positive effects of postnatal GCs on pulmonary inflammatory processes (6, 7) and the prophylactic effects against hyperoxic lung injury (8) seem to improve the survival chances of preterm neonates. In perinatal medicine, a variety of therapeutic schemes have been adopted, but controversies regarding the long-term benefits and the negative side effects of GC in neonatology abound (9 -11). Indeed, besides the apparent benefits of GC therapy, adverse effects on lung maturation have been reported in animal experiments (12, 13). Furthermore, reserves have been expressed over the general outcome of treated newborns (14,15). In the recent past, there have been numerous studies on the positive and negative effects of postnatal GC therapy, but as noted by Barrington (16), there are no published long-term pulmonary data.Previously we have indicated that long-term administration of minute doses of GC results in a permanent impairment of lung alveolarization in postnatal rats (17,18). Alveolarization is achieved by subdivision of the preexisting saccular air spaces ...

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“…Although the physiologic importance of this T3 neogenesis remains unclear, it is quite possible that T3 exerts the biologic effects of thyroid hormone and, therefore, is responsible for the morphologic changes in fetal and adult type I1 cells which have been described by a number of investigators (for review, see [20][21][22]. It is also possible that T4, rather than acting as a prohormone, has effects of its own, and that in the course of its activity it is metabolized peripherally to other thyronines such as T3 and rT3 These compounds might then simply represent by-products of thyroid hormone action.…”

Section: Discussionmentioning

confidence: 99%

“…More recently, Hitchcock and collaborators (20)(21)(22) demonstrated that thyroxine (T4) can accelerate rat lung development and that this acceleration is maximal in the presence of glucocorticoids. Similar findings were noted by Ballard and associates (1, 2) during transplacental stimulation of fetal rabbit lung by an analog of T4 known as DIMIT.…”

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Thyroxine Metabolism in Cultured Cells Derived from Fetal Rat Lung

et al. 1983

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SummaryThe role of thyroxine (T4) in fetal lung development has been demonstrated previously. Because triiodothyronine (T3), not T4, is thought to be the active hormone, and because T3 nuclear recep tors appear to be present in fetal lung, the following studies were performed to examine peripheral metabolism of [12'I] [1311JT3 and [1251]T3; the ratio of these provided an index of intracellular conversion of [12'I]T4 to [l2'IjT3. The mean of five such experiments demonstrated that of the total ['2'IJT3 attached to the nuclear fraction at the end of the incubation, 32% was newly generated and 68% was derived by influx from the medium. These results indicate that organotypic cultures derived from day 19 fetal rat lung are capable of deiodinating T4 and that both rT3 and T3 are generated. The generated T3 appears to be retained by the lung cells and is bound to the nuclear fraction. On the other hand, rT3 is distributed more evenly throughout the cell and in the medium and presumably is not bound. Abbreviations DIMIT, 3,5-dimethyl-3'-isopropyl-L-thyronine FBS, fetal bovine serum PC, phosphatidylcholme T3, triiodothyronine rT3, reverse T3 T4, thyroxine TAA, hexane-tertiary amyl alcohol3 N ammoniaThe role of thyroid hormone in fetal lung development is well recognized, but its mechanism of action is not clear (20-22, 27, 38). The hormonal milieu of the mammalian fetus is characterized by low triiodothyronine (T3) levels and high concentrations of reverse T3 (rT3) (16, 38); and yet, certain target organs, including the lung, appear to depend on the active form of thyroid hormone (i.e., T3) during certain developmental stages.Early studies by Redding et al. (27) showed that thyroidectomy and subsequent thyroid hormone replacement profoundly influenced the morphologic characteristics of type I1 pneumonocytes and their lamellar bodies, and that there was a correlation between the demonstrated ultrastructural changes and lung surfactant secretion. More recently, Hitchcock and collaborators (20-22) demonstrated that thyroxine (T4) can accelerate rat lung development and that this acceleration is maximal in the presence of glucocorticoids. Similar findings were noted by Ballard and associates (1, 2) during transplacental stimulation of fetal rabbit lung by an analog of T4 known as DIMIT. The effects of hormones on fetal lung metabolism have also been studied using fetal lung cells under conditions of short term monolayer culture. smith and Torday (33), using monolayer cultures of fetal rabbit lung cells, found that T4 produced a significant increase in incorporation of [14C]-choline into PC. In a similar tissue culture system, Farrell et al. (14) have shown an increase in activity of cholinekinase, and both T4 and cortisol exposure led to an increase in choline phosphotransferase.With the increasing evidence that most, if not all, actions of thyroid hormone are expressed by T3, there have been additional investigations of the effect of T3 on lung development. Using organotypic cultures of fetal rat lung alveolar type I1 ...

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Lung development and the pulmonary surfactant system: Hormonal influences

Cited by 46 publications

References 304 publications

Ontogeny of Atrial Natriuretic Peptide and Its Receptor In the Lung: Effects on Perinatal Surfactant Release

Ontogeny of Atrial Natriuretic Peptide and Its Receptor In the Lung: Effects on Perinatal Surfactant Release

Effects of Neonatal High-Dose Short-Term Glucocorticoid Treatment on the Lung: A Morphologic and Morphometric Study in the Rat

Thyroxine Metabolism in Cultured Cells Derived from Fetal Rat Lung

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