bromochloroacetic-acid and Hyperoxia

The mammalian placenta represents the interface between maternal and embryonic tissues and provides nutrients and gas exchange during embryo growth. Recently, keratin intermediate filament proteins were found to regulate embryo growth upstream of the mammalian target of rapamycin pathway through glucose transporter relocalization and to contribute to yolk sac vasculogenesis through altered bone morphogenetic protein 4 signaling. Whether keratins have vital functions in extraembryonic tissues is not well understood. Here, we report that keratins are essential for placental function. In the absence of keratins, we find hyperoxia in the decidual tissue directly adjacent to the placenta, because of an increased maternal vasculature. Hyperoxia causes impaired vasculogenesis through defective hypoxia-inducible factor 1α and vascular endothelial growth factor signaling, resulting in invagination defects of fetal blood vessels into the chorion. In turn, the reduced labyrinth, together with impaired gas exchange between maternal and embryonic blood, led to increased hypoxia in keratin-deficient embryos. We provide evidence that keratin-positive trophoblast secretion of prolactin-like protein a (Prlpa) and placental growth factor (PlGF) during decidualization are altered in the absence of keratins, leading to increased infiltration of uterine natural killer cells into placental vicinity and increased vascularization of the maternal decidua. Our findings suggest that keratin mutations might mediate conditions leading to early pregnancy loss due to hyperoxia in the decidua.

Topics: Animals; Cell Lineage; Chorion; Decidua; Female; Gene Expression Regulation, Developmental; Hyperoxia; In Situ Hybridization; Keratins; Mice; Mice, Transgenic; Microscopy, Fluorescence; Mutation; Placenta; Placenta Growth Factor; Pregnancy; Pregnancy Proteins

In this study, C57BL/6J mice were exposed to hyperoxia and allowed to recover in room air. The sublethal dose of hyperoxia for C57BL/6J was 48 h. Distal lung cellular isolates from treated animals were characterized as 98% epithelial, with minor fibroblast and endothelial cell contaminants. Cells were then verified as 95% pure alveolar epithelial type II cells (AEC2) by surfactant protein C (SP-C) expression. After hyperoxia exposure in vivo, fresh, uncultured AEC2 were analyzed for proliferation by cell yield, cell cycle, PCNA expression, and telomerase activity. DNA damage was assessed by TdT-dUTP nick-end labeling, whereas induction of DNA repair was evaluated by GADD-153 expression. A baseline level for proliferation and damage was observed in cells from control animals that did not alter significantly during acute hyperoxia exposure. However, a rise in these markers was observed 24 h into recovery. Over 72 h of recovery, markers for proliferation remained elevated, whereas those for DNA damage and repair peaked at 48 h and then returned back to baseline. The expression of GADD-153 followed a distinct course, rising significantly during acute exposure and peaking at 48 h recovery. These data demonstrate that in healthy, adult male C57BL/6J mice, AEC2 proliferation, damage, and repair follow separate courses during hyperoxia recovery and that both proliferation and efficient repair may be required to ensure AEC2 survival.

Topics: Animals; Biomarkers; Cell Proliferation; DNA Damage; DNA Repair; Epithelial Cells; Hyperoxia; Keratins; Male; Mice; Mice, Inbred C57BL; Proliferating Cell Nuclear Antigen; Pulmonary Alveoli; Pulmonary Surfactant-Associated Protein C; Recovery of Function; S Phase; Telomerase; Time Factors; Transcription Factor CHOP; Up-Regulation

Hyperoxia is closely linked with the development of chronic lung disease of prematurity (CLD), but the exact mechanisms whereby hyperoxia alters the lung architecture in the developing lung remain largely unknown. We developed a fetal human lung organ culture model to investigate (a) the morphologic changes induced by hyperoxia and (b) whether hyperoxia resulted in differential cellular responses in the epithelium and interstitium. The effects of hyperoxia on lung morphometry were analyzed using computer-assisted image analysis. The lung architecture remained largely unchanged in normoxia lasting as long as 4 d. In contrast, hyperoxic culture of pseudoglandular fetal lungs resulted in significant dilatation of airways, thinning of the epithelium, and regression of the interstitium including the pulmonary vasculature. Although there were no significant differences in Ki67 between normoxic and hyperoxic lungs, activated caspase-3 was significantly increased in interstitial cells, but not epithelial cells, under hyperoxic conditions. These changes show that exposure of pseudoglandular lungs to hyperoxia modulates the lung architecture to resemble saccular lungs.

Topics: Apoptosis; Blood Vessels; Caspase 3; Caspases; Cell Proliferation; Cell Shape; Epithelium; Female; Fetus; Gestational Age; Humans; Hyperoxia; Keratins; Lung; Organ Culture Techniques; Platelet Endothelial Cell Adhesion Molecule-1; Pregnancy; Random Allocation; Vascular Endothelial Growth Factor A

Hyperoxia-induced neutrophil infux in neonatal rats may contribute to impaired lung development through oxidative DNA damage. To determine whether blocking neutrophil influx prevents DNA damage, we treated newborn rats with 95% O2 beginning at birth, and at 3 and 4 d with nonimmune immunoglobulin G (IgG) (control) or anti-cytokine-induced neutrophil chemoattractant (CINC). At 8 d, lungs were inflation-fixed. Random sections were labeled using terminal transferase nick end-labeling (TUNEL), and DNA oxidation was measured using anti-8-OH-2'-deoxyguanosine (OHdG). To determine whether hyperoxia-induced TUNEL represented apoptosis, we labeled sections with anti-Bax (proapoptotic) and anti-Bcl-2 (antiapoptotic). We labled additional sections with anti-M30, directed against an epitope formed by caspase 6 digestion of cytokeratin 18 during apoptosis. Hyperoxia induced marked increases in TUNEL and OHdG signal in lung parenchymal cells, which was substantially prevented by treatment with anti-CINC. The large effects of hyperoxia on TUNEL were not accompanied by substantial effects on Bax, Bcl-2, or M30. We conclude that neutrophil influx during hyperoxia damages DNA by nicking and oxidation, and that blocking neutrophil influx can prevent this. Effects of 95% O2 on TUNEL are not primarily due to apoptosis in this model. Neutrophil-mediated oxidative DNA damage may contribute to abnormal lung development in newborns subjected to significant oxidative stress.

Topics: 8-Hydroxy-2'-Deoxyguanosine; Animals; Animals, Newborn; Apoptosis; bcl-2-Associated X Protein; Caspase 6; Caspases; Chemokines, CXC; Chemotactic Factors; DNA Damage; Epithelium; Growth Substances; Guanine; Hyperoxia; Immunoglobulin G; In Situ Nick-End Labeling; Intercellular Signaling Peptides and Proteins; Keratins; Lung; Neutrophils; Oxidative Stress; Proto-Oncogene Proteins; Proto-Oncogene Proteins c-bcl-2; Rats