Sex-Specific Differences in MicroRNA Expression During Human Fetal Lung Development.

Background: Sex-specific differences in fetal lung maturation have been well described; however, little is known about the sex-specific differences in microRNA (miRNA) expression during human fetal lung development. Interestingly, many adult chronic lung diseases also demonstrate sex-specific differences in prevalence. The developmental origins of health and disease hypothesis suggests that these sex-specific differences in fetal lung development may influence disease susceptibility later in life. In this study, we performed miRNA sequencing on human fetal lung tissue samples to investigate differential expression of miRNAs between males and females in the pseudoglandular stage of lung development. We hypothesized that differences in miRNA expression are present between sexes in early human lung development and may contribute to the sex-specific differences seen in pulmonary diseases later in life. Methods: RNA was isolated from human fetal lung tissue samples for miRNA sequencing. The count of each miRNA was modeled by sex using negative binomial regression models in DESeq2, adjusting for post-conception age, age2, smoke exposure, batch, and RUV factors. We tested for differential expression of miRNAs by sex, and for the presence of sex-by-age interactions to determine if miRNA expression levels by age were distinct between males and females. Results: miRNA expression profiles were generated on 298 samples (166 males and 132 females). Of the 809 miRNAs expressed in human fetal lung tissue during the pseudoglandular stage of lung development, we identified 93 autosomal miRNAs that were significantly differentially expressed by sex and 129 miRNAs with a sex-specific pattern of miRNA expression across the course of the pseudoglandular period. Conclusion: Our study demonstrates differential expression of numerous autosomal miRNAs between the male and female developing human lung. Additionally, the expression of some miRNAs are modified by age across the pseudoglandular stage in a sex-specific way. Some of these differences in miRNA expression may impact susceptibility to pulmonary disease later in life. Our results suggest that sex-specific miRNA expression during human lung development may be a potential mechanism to explain sex-specific differences in lung development and may impact subsequent disease susceptibility.

Lack of effects of acemetacin on signalling pathways for leukocyte adherence may explain its gastrointestinal safety.

BACKGROUND AND PURPOSE: Acemetacin is a non-steroidal anti-inflammatory drug which is rapidly bioconverted to indomethacin, but produces significantly less gastric damage than indomethacin. This study was performed to investigate several possible mechanisms that could account for the gastrointestinal tolerability of acemetacin. EXPERIMENTAL APPROACH: The gastric and intestinal damaging effects of acemetacin and indomethacin were examined in the rat. Effects of the drugs on blood levels of leukotriene B(4) and thromboxane B(2), on leukocyte-endothelial adherence in post-capillary mesenteric venules, and on gastric expression of tumour necrosis factor-alpha (TNF-alpha) were determined. The two drugs were also compared for gastric toxicity in rats pretreated with inhibitors of COX-2 and NOS. KEY RESULTS: Acemetacin induced significantly less gastric and intestinal damage than indomethacin, despite markedly suppressing COX activity. Indomethacin, but not acemetacin, significantly increased leukocyte adherence within mesenteric venules, and gastric expression of TNF-alpha. Pretreatment with L-nitro-arginine methyl ester or lumiracoxib increased the severity of indomethacin-induced gastric damage, but this was not the case with acemetacin. CONCLUSIONS AND IMPLICATIONS: The increased gastric and intestinal tolerability of acemetacin may be related to the lack of induction of leukocyte-endothelial adherence. This may be attributable to the reduced ability of acemetacin to elevate leukotriene-B(4) synthesis and TNF-alpha expression, compared to indomethacin, despite the fact that acemetacin is rapidly bioconverted to indomethacin after its absorption.

[Amino acid transport and protein synthesis in ground squirrels during hibernation and artificial hypothermia]. / Transport aminokislot i sintez belkov u suslikov pri gibernatsii i iskusstvennoi gipotermii.

The intensity of labelled leucine penetration from the blood-circulating system to the tissues and its incorporation into proteins of some organs of gophers have been studied under hibernation and hypothermia. It is shown that, in spite of the low temperature of the gopher body under hibernation, the intensity of amino acids transfer from the blood to the tissue was approximately the same as in active state. But the rate of proteins synthesis under hibernation considerably decreases though it is not completely stopped. Under artificial hypothermia of the mammals the transition of amino acids from the blood to the tissue is considerably hampered. Under these conditions the incorporation of labelled amino acids is completely stopped.

[Protein synthesis during hyperthermia in ground squirrels]. / Sintez belkov pri gipotermii suslikov.

The intensity of [14C]leucine incorporation into heart, liver, brain, muscle, and blood plasma protein in gophers under deep artificial hypothermia has been studied. It was shown that the intensity of protein synthesis decreased sharply under these conditions. Insignificant incorporation of [14C]leucine into proteins was observed during the first two hours after the onset of hypothermia and then ceased completely.