Gene expression modulation in human dermal substitute exposed to reversible electroporation (ECT or GET types)
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ABSTRACT: In this project we aimed at deciphering modulation in genes expression induced by external pulsed electric fields applied in reversible electroporation-based treatments. Thanks to their local application and transient effects, physical stimuli appear as attractive tools to remodel extracellular matrix, which was the point of interest in our to be published study. We assessed the potential of pulsed electric field technology, classically applied to drug delivery, to induce collagen remodeling at the tissue scale. A sophisticated in vitro tissue-engineered human dermal substitute, a tissue model rich in endogeneous extracellular matrix such as collagens, was used to demonstrate the effects of microsecond and millisecond pulsed electric fields applied respectively in electrochemotherapy (ECT) treatment and gene electrotransfer (GET) strategy. Our analyses, focused on matrisome genes and extracellular matrix remodeling, underpin that pulsed electric fields, a technology already approved for clinical use combined with anti-cancer agents, are particularly promising to provide local and effective treatment of abnormal extracellular matrix. Part of this dataset was used to describe how pulsed electric field on its own (with no addition of external drugs) induce extracellular matrix (ECM) remodeling at human dermal scale, by focusing at genes related to matrisome subset. In this manuscript to be published, electrochemotherapy (ECT) parameters were named SP for "short pulses" and gene electrotransfer (GET) parameters were named LP for "long pulses". W demonstrated that these both types of electric parameters inducing reversible electroporation of the cells whitin the dermal tissue substitute induced 1) a rapid modulation (4h after electrostimulation) of mRNA’s genes composing the matrisome, particularly a down-regulation of pro-collagens and ECM maturation’s enzymes such as transglutaminase TG2 and LOX-like; 2) a transient decrease in pro-collagens production and hydroxyproline tissue content within a week after electrostimulation; 3) a long-lasting ROS-dependent over-activation of MMPs for at least 48h and 4) a down-regulation at both mRNA and protein level of pro-fibrotic TGF-β.
ORGANISM(S): Homo sapiens
PROVIDER: GSE180644 | GEO | 2021/07/26
REPOSITORIES: GEO
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