Sharon Jayne Flecknoe

Determination of alveolar epithelial cell phenotypes in fetal sheep: evidence for the involvement of basal lung expansion

The factors that control the differentiation of alveolar epithelial cells (AECs) into type‐I and type‐II cells in vivo are largely unknown. As sustained increases in fetal lung expansion induce type‐II AECs to differentiate into type‐I cells, our aim was to determine whether reduced fetal lung expansion can induce type‐I AECs to trans‐differentiate into type‐II AECs. Chronically catheterised fetal sheep were divided into two age‐matched control groups and three experimental groups (n= 5 for each). The experimental groups were exposed to either: (1) 10 days of increased lung expansion induced by tracheal obstruction (TO), (2) 10 days of TO followed by 5 days of reduced lung expansion induced by lung liquid drainage (LLD), or (3) 10 days of TO followed by 10 days of LLD. Following 10 days of TO, 5 days of LLD reduced the proportion of type‐I AECs from 89.4 ± 0.9 % to 68.4 ± 2.8 %, which was similar to control values (64.8 ± 0.5 %), and increased the proportion of type‐II AECs from 1.9 ± 0.3 % to 21.9 ± 2.8 %, which remained below control values (33.4 ± 1.7 %). The same treatment increased surfactant protein (SP)‐A, SP‐B and SP‐C mRNA levels (expressed as a percentage of control values) from 26.7 ± 6.0 %, 40.0 ± 7.3 % and 10.3 ± 1.8 % to 78.1 ± 10.3 %, 105.8 ± 12.7 % and 121.0 ± 14.1 %, respectively. Similar results were obtained after 10 days of LLD, which followed 10 days of TO. These results indicate that the phenotypes of type‐I and type‐II AECs are strongly influenced by the basal degree of lung expansion in fetal sheep. Furthermore, the coincident increase in type‐II AEC proportions and SP mRNA levels in response to LLD suggests that type‐I AECs can trans‐differentiate into functional type‐II cells, and hence are not terminally differentiated.

Identification of glucocorticoid‐regulated genes that control cell proliferation during murine respiratory development

Glucocorticoids play a vital role in fetal respiratory development and act via the intracellular glucocorticoid receptor (GR) to regulate transcription of key target genes. GR‐null mice die at birth due to respiratory dysfunction associated with hypercellularity and atelectasis. To identify events associated with this lung phenotype we examined perinatal cellular proliferation rates and apoptotic indices. We demonstrate that compared to wild‐type controls, day 18.5 postcoitum (p.c.) GR‐null mouse lungs display significantly increased cell proliferation rates (1.8‐fold P < 0.05) and no change in apoptosis. To examine underlying molecular mechanisms, we compared whole genome expression profiles by microarray analysis at 18.5 days p.c. Pathways relating to cell proliferation, division and cell cycle were significantly down‐regulated while pathways relating to carbohydrate metabolism, kinase activities and immune responses were significantly up‐regulated. Differential levels of gene expression were verified by quantitative‐RT‐PCR and/or Northern analysis. Key regulators of proliferation differentially expressed in the lung of 18.5 p.c. GR‐null lungs included p21CIP1 (decreased 2.9‐fold, P < 0.05), a negative regulator of the cell cycle, and Mdk (increased 6.0‐fold, P < 0.05), a lung growth factor. The more under‐expressed genes in 18.5 p.c. GR‐null lungs included Chi3l3 (11‐fold, P < 0.05), a macrophage inflammatory response gene and Ela1 (9.4‐fold, P < 0.05), an extracellular matrix remodeling enzyme. Our results demonstrate that GR affects the transcriptional status of a number of regulatory processes during late fetal lung development. Amongst these processes is cell proliferation whereby GR induces expression of cell cycle repressors while suppressing induction of a well characterized cell cycle stimulator.

Ventilation of the Very Immature Lung In Utero Induces Injury and BPD-Like Changes in Lung Structure in Fetal Sheep

Preterm infants are at high risk of developing ventilator-induced lung injury (VILI), which contributes to bronchopulmonary dysplasia. To investigate causes of VILI, we have developed an animal model of in utero ventilation (IUV). Our aim was to characterize the effects of IUV on the very immature lung, in the absence of nonventilatory factors that could contribute to lung pathology. Fetal sheep were ventilated in utero at 110 d gestation for 1, 6, or 12 h (two groups; n = 5 each). Lung tissue was collected at 12 h after initiating IUV in the 1, 6, and one 12 h IUV groups. Lung liquid was replaced in the second 12 h IUV group and tissues collected at 117 d. Operated, nonventilated 110 and 117 d fetuses were controls. IUV reduced secondary septal crest densities, simplified distal airsacs, caused abnormal collagen and elastin deposition, and stimulated myofibroblast differentiation and cellular proliferation. IUV causes VILI in very immature lungs in the absence of other complicating factors and reproduces bronchopulmonary dysplasia -like changes in lung morphology. IUV offers a novel method for dissociating VILI from other iatrogenic factors that could contribute to altered lung development caused by VILI.

cAMP response element binding protein is required for differentiation of respiratory epithelium during murine development

The cAMP response element binding protein 1 (Creb1) transcription factor regulates cellular gene expression in response to elevated levels of intracellular cAMP. Creb1 −/− fetal mice are phenotypically smaller than wildtype littermates, predominantly die in utero and do not survive after birth due to respiratory failure. We have further investigated the respiratory defect of Creb1−/− fetal mice during development. Lungs of Creb1−/− fetal mice were pale in colour and smaller than wildtype controls in proportion to their reduced body size. Creb1−/− lungs also did not mature morphologically beyond E16.5 with little or no expansion of airway luminal spaces, a phenotype also observed with the Creb1−/− lung on a Crem −/− genetic background. Creb1 was highly expressed throughout the lung at all stages examined, however activation of Creb1 was detected primarily in distal lung epithelium. Cell differentiation of E17.5 Creb1 −/− lung distal epithelium was analysed by electron microscopy and showed markedly reduced numbers of type-I and type-II alveolar epithelial cells. Furthermore, immunomarkers for specific lineages of proximal epithelium including ciliated, non-ciliated (Clara), and neuroendocrine cells showed delayed onset of expression in the Creb1−/− lung. Finally, gene expression analyses of the E17.5 Creb1 −/− lung using whole genome microarray and qPCR collectively identified respiratory marker gene profiles and provide potential novel Creb1-regulated genes. Together, these results demonstrate a crucial role for Creb1 activity for the development and differentiation of the conducting and distal lung epithelium.

Persistent bronchiolar remodeling following brief ventilation of the very immature ovine lung

Children and adults who were mechanically ventilated following preterm birth are at increased risk of reduced lung function, suggesting small airway dysfunction. We hypothesized that short periods of mechanical ventilation of very immature lungs can induce persistent bronchiolar remodeling that may adversely affect later lung function. Our objectives were to characterize the effects of brief, positive-pressure ventilation per se on the small airways in very immature, surfactant-deficient lungs and to determine whether the effects persist after the cessation of ventilation. Fetal sheep (0.75 of term) were mechanically ventilated in utero with room air (peak inspiratory pressure 40 cmH2O, positive end-expiratory pressure 4 cmH2O, 65 breaths/min) for 6 or 12 h, after which tissues were collected; another group was studied 7 days after 12-h ventilation. Age-matched unventilated fetuses were controls. The mean basement membrane perimeter of airways analyzed was 548.6+/-8.5 microm and was not different between groups. Immediately after ventilation, 21% of airways had epithelial injury; in airways with intact epithelium, there was more airway smooth muscle (ASM) and less collagen, and the epithelium contained more mucin-containing and apoptotic cells and fewer proliferating cells. Seven days after ventilation, epithelial injury was absent but the epithelium was thicker, with greater cell turnover; there were increased amounts of bronchiolar collagen and ASM and fewer alveolar attachments. The increase in ASM was likely due to cellular hypertrophy rather than hyperplasia. We conclude that brief mechanical ventilation of the very immature lung induces remodeling of the bronchiolar epithelium and walls that lasts for at least 7 days; such changes could contribute to later airway dysfunction.

Alveolar epithelial cell differentiation and surfactant protein expression after mild preterm birth in sheep

As the transition to extrauterine life at birth alters the proportions of type I and II alveolar epithelial cells (AECs), our aim was to determine the effect of mild preterm birth on AECs and surfactant protein (SP) gene expression. Preterm lambs were born at ∼133 d of gestational age (DGA); controls were born at term (∼147 DGA). Lungs were collected from preterm lambs at term-equivalent age (TEA; ∼2 wk after preterm birth) and 6 wk post-TEA. Control lung tissue was collected from fetuses (at 132 DGA), as well as from lambs at ∼6 h (normal term) and 2, 6, and 8 wk of postnatal age (PNA). In controls, the proportion of type I AECs decreased from 65.1 ± 3.9% at term to 50.9 ± 3.3%, while the proportion of type II AECs increased from 33.7 ± 3.9% to 48.5 ± 3.3% at 6 wk PNA. At 2 wk after preterm birth, the proportions of type I and II AECs were similar in preterm lambs compared to 132-d fetal levels and term controls but differed from control values at 2 wk PNA; differences between control and preterm lambs persisted at 8 wk PNA. At ∼2 wk after preterm birth, SP-A and SP-B, but not SP-C, mRNA levels were significantly reduced in preterm lambs compared with term controls, but these differences did not persist at 2 and 6 wk PNA. We conclude that mild preterm birth alters the normal postnatal changes in type I and II cell proportions but does not severely affect SP gene expression.

Ventilation and oxygen: dose-related effects of oxygen on ventilation-induced lung injury.

Preterm infants are at high risk of developing ventilator-induced lung injury. We have used an animal model of in utero ventilation (IUV) to investigate the separate effects of ventilation and acute oxygen exposure on the very immature lung. Fetal sheep were ventilated in utero at 110 d gestation for 6 h with 100, 21, or 0% (100% nitrogen) oxygen (n = 5 each) and survived in utero, without further ventilation, until tissue collection at 118 d. Nonventilated 110 d and 118 d fetuses were used as controls. All IUV exposed fetuses had reduced secondary septal crest densities and increased elastin staining irrespective of the inspired oxygen concentration. IUV with 100% and 21% oxygen, but not 100% nitrogen, increased lung tissue volumes and myofibroblast differentiation and apoptosis within the distal lung parenchyma in a dose-dependent manner. This study shows that IUV without oxygen can reduce alveolarization, whereas ventilation with oxygen (6 h), even at levels found in air (21%), increases distal lung tissue volumes, elastin deposition, myofibroblast differentiation, and apoptosis.

Structural and Functional Development of the Respiratory System in a Newborn Marsupial with Cutaneous Gas Exchange

Marsupials are born with structurally immature lungs and rely, to varying degrees, on cutaneous gas exchange. With a gestation of 13 d and a birth weight of 13 mg, the fat-tailed dunnart (Sminthopsis crassicaudata) is one of the smallest and most immature marsupial newborns. We determined that the skin is almost solely responsible for gas exchange in the early neonatal period. Indeed, fewer than 35% of newborn dunnarts were observed to make any respiratory effort on the day of birth, with pulmonary ventilation alone not meeting the demand for oxygen until approximately 35 d postpartum. Despite the lack of pulmonary ventilation, the phrenic nerve had made contact with the diaphragm, and the respiratory epithelium was sufficiently developed to support gas exchange on the day of birth. Both type I and type II (surfactant-producing) alveolar epithelial cells were present, with fewer than 7% of the cells resembling undifferentiated alveolar epithelial precursor cells. The type I epithelial cells did, however, display thickened cytoplasmic extensions, leading to a high diffusion distance for oxygen. In addition, the architecture of the lung was immature, resembling the early canalicular stage, with alveolarization not commencing until 45 d postpartum. The pulmonary vasculature was also immature, with a centrally positioned single-capillary layer not evident until 100 d postbirth. These structural limitations may impede efficient pulmonary gas exchange, forcing the neonatal fat-tailed dunnart to rely predominately on its skin, a phenomenon supported by a low metabolic rate and small size.

Pulmonary hemodynamic responses to in utero ventilation in very immature fetal sheep

BackgroundThe onset of ventilation at birth decreases pulmonary vascular resistance (PVR) resulting in a large increase in pulmonary blood flow (PBF). As the large cross sectional area of the pulmonary vascular bed develops late in gestation, we have investigated whether the ventilation-induced increase in PBF is reduced in immature lungs.MethodsSurgery was performed in fetal sheep at 105 d GA (n = 7; term ~147 d) to insert an endotracheal tube, which was connected to a neonatal ventilation circuit, and a transonic flow probe was placed around the left pulmonary artery. At 110 d GA, fetuses (n = 7) were ventilated in utero (IUV) for 12 hrs while continuous measurements of PBF were made, fetuses were allowed to develop in utero for a further 7 days following ventilation.ResultsPBF changes were highly variable between animals, increasing from 12.2 ± 6.6 mL/min to a maximum of 78.1 ± 23.1 mL/min in four fetuses after 10 minutes of ventilation. In the remaining three fetuses, little change in PBF was measured in response to IUV. The increases in PBF measured in responding fetuses were not sustained throughout the ventilation period and by 2 hrs of IUV had returned to pre-IUV control values.Discussion and conclusionVentilation of very immature fetal sheep in utero increased PBF in 57% of fetuses but this increase was not sustained for more than 2 hrs, despite continuing ventilation. Immature lungs can increase PBF during ventilation, however, the present studies show these changes are transient and highly variable.

High bias gas flows increase lung injury in the ventilated preterm lamb.

Background Mechanical ventilation of preterm babies increases survival but can also cause ventilator-induced lung injury (VILI), leading to the development of bronchopulmonary dysplasia (BPD). It is not known whether shear stress injury from gases flowing into the preterm lung during ventilation contributes to VILI. Methods Preterm lambs of 131 days’ gestation (term = 147 d) were ventilated for 2 hours with a bias gas flow of 8 L/min (n = 13), 18 L/min (n = 12) or 28 L/min (n = 14). Physiological parameters were measured continuously and lung injury was assessed by measuring mRNA expression of early injury response genes and by histological analysis. Control lung tissue was collected from unventilated age-matched fetuses. Data were analysed by ANOVA with a Tukey post-hoc test when appropriate. Results High bias gas flows resulted in higher ventilator pressures, shorter inflation times and decreased ventilator efficiency. The rate of rise of inspiratory gas flow was greatest, and pulmonary mRNA levels of the injury markers, EGR1 and CTGF, were highest in lambs ventilated with bias gas flows of 18 L/min. High bias gas flows resulted in increased cellular proliferation and abnormal deposition of elastin, collagen and myofibroblasts in the lung. Conclusions High ventilator bias gas flows resulted in increased lung injury, with up-regulation of acute early response genes and increased histological lung injury. Bias gas flows may, therefore, contribute to VILI and BPD.