Estrogens have well-documented effects on lung development and physiology. However, the classical estrogen receptor ␣ (ER␣) is undetectable in the lung, and this has left many unanswered questions about the mechanism of estrogen action in this organ. Here we show, both in vivo and in vitro, that ER is abundantly expressed and biologically active in the lung. Comparisons of lungs from wild-type mice and mice with an inactivated ER gene (ER ؊/؊ ) revealed decreased numbers of alveoli in adult female ER ؊/؊ mice and findings suggesting deficient alveolar formation as well as evidence of surfactant accumulation. Plateletderived growth factor A (PDGF-A) and granulocyte-macrophage colony-stimulating factor (GM-CSF), key regulators of alveolar formation and surfactant homeostasis, respectively, were decreased in lungs of adult female ER ؊/؊ mice, and direct transcriptional regulation of these genes by ER was demonstrated. This suggests that estrogens act via ER in the lung to modify PDGF-A and GM-CSF expression. These results provide a potential molecular mechanism for the gender differences in alveolar structure observed in the adult lung and establish ER as a previously unknown regulator of postnatal lung development and homeostasis.The vital function of the lung is to provide a gas-exchange surface to meet the organism's needs for oxygen uptake and carbon dioxide elimination. Several parameters in lung biology and pathology, both during development and in the adult, are sexually dimorphic. A role for estrogen in these dimorphisms was suggested in 1980 when Mendelson et al. (21) showed an estrogen-binding component in human fetal lung tissue. Lung maturation during fetal development is more rapid in female fetuses than in male fetuses, and the onset of surfactant synthesis occurs later in the male fetus. This difference appears to be mediated mainly by inhibitory effects of androgens, but stimulatory effects of estrogens have also been demonstrated (2). Postnatal sex differences in the rodent lung have been described by Massaro et al. (20). Adult females have a larger number of alveoli, smaller in size, than males, probably to allow for elevated oxygen consumption during pregnancy and lactation. This difference develops as animals reach sexual maturity and seems to be mediated mainly by estrogens (19). In the human population, women are more prone than men to developing chronic obstructive pulmonary disease (29) and incur a higher risk of developing lung cancer (13, 41), indicating that women are more susceptible to the deleterious effects of tobacco smoking. The reasons for these sex differences are unknown, but estrogens are likely to play a major role, since in animal models, there are estrogen-dependent gender differences in susceptibility towards tobacco-associated lung carcinogens (23), and furthermore, epidemiological studies suggest that hormone replacement therapy with estrogen is associated with a higher risk of lung cancer in postmenopausal women (1,39).Although previous data suggest that estrogen...
Scanning transmission electron microscopy (STEM) data with atomic resolution can contain a large amount of information about the structure of a crystalline material. Often, this information is hard to extract, due to the large number of atomic columns and large differences in intensity from sublattices consisting of different elements. In this work, we present a free and open source software tool for analysing both the position and shapes of atomic columns in STEM-images, using 2-D elliptical Gaussian distributions. The software is tested on variants of the perovskite oxide structure. By first fitting the most intense atomic columns and then subtracting them, information on all the projected sublattices can be obtained. From this, we can extract changes in the lattice parameters and shape of A-cation columns from annular dark field images of perovskite oxide heterostructures. Using annular bright field images, shifts in oxygen column positions are also quantified in the same heterostructure. The precision of determining the position of atomic columns is compared between STEM data acquired using standard acquisition, and STEM-images obtained as an image stack averaged after using non-rigid registration.
Bronchoalveolar lavage fluid exosomes from asthmatic and healthy individuals exhibit distinct phenotypes and functions. BALF exosomes from asthmatics might contribute to subclinical inflammation by increasing cytokine and LTC(4) generation in airway epithelium.
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