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Sexual dimorphism of miRNA signatures in feto-placental endothelial cells is associated with altered barrier function and actin organization
Author(s) -
Silvija Cvitic,
Jasmin Strutz,
Hannah M Appel,
Elisa Weiß,
Waltraud Brandl,
Andrea Thüringer,
Eva Bernhart,
Luciana Lassance,
Christian Wadsack,
Carolin Schliefsteiner,
Ivana Sreckovic,
Karl Kashofer,
Ursula Hiden
Publication year - 2020
Publication title -
clinical science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.91
H-Index - 138
eISSN - 1470-8736
pISSN - 0143-5221
DOI - 10.1042/cs20190379
Subject(s) - biology , adherens junction , microrna , microbiology and biotechnology , actin cytoskeleton , sexual dimorphism , focal adhesion , cytoskeleton , signal transduction , genetics , cell , endocrinology , cadherin , gene
Endothelial function and the risk for endothelial dysfunction differ between males and females. Besides the action of estrogen, sex chromosome gene expression and programming effects also provoke this sexual dimorphism. MicroRNAs (miRNAs) have emerged as regulators of endothelial cell function and dysfunction. We here hypothesized distinct miRNA expression patterns in male versus female human endothelial cells that contribute to the functional differences. We used our well-established model of fetal endothelial cells isolated from placenta (fpEC) and analyzed sexual dimorphic miRNA expression and potentially affected biological functions. Next-generation miRNA sequencing of fpEC isolated after pregnancies with male and female neonates identified sex-dependent miRNA expression patterns. Potential biological pathways regulated by the altered set of miRNAs were determined using mirPath and mirSystem softwares, and suggested differences in barrier function and actin organization. The identified pathways were further investigated by monolayer impedance measurements (ECIS) and analysis of F-actin organization (Phalloidin). Nine miRNAs were differentially expressed in fpEC of male versus female neonates. Functional pathways most significantly regulated by these miRNAs included ‘Adherens junction’, ‘ECM receptor interaction’ and ‘Focal adhesion’. These pathways control monolayer barrier function and may be paralleled by altered cytoskeletal organization. In fact, monolayer impedance was higher in fpEC of male progeny, and F-actin staining revealed more pronounced peripheral stress fibers in male versus female fpEC. Our data highlight that endothelial cell function differs between males and females already in utero, and that altered miRNAs are associated with sex dependent differences in barrier function and actin organization.

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