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Physiological Impact of a Synthetic Elastic Protein in Arterial Diseases Related to Alterations of Elastic Fibers: Effect on the Aorta of Elastin-Haploinsufficient Male and Female Mice.

Quentin BoëtéMing LoKiao-Ling LiuGuillaume VialEmeline LemariéMaxime RougelotIris SteuckardtOlfa HarkiAxel CouturierJonathan GaucherSophie BouyonAlexandra DemoryAntoine Boutin-ParadisNaima El KholtiAurore BerthierJean Louis PépinAnne Briançon-MarjolletElise LambertRomain DebretGilles Faury
Published in: International journal of molecular sciences (2022)
Elastic fibers, made of elastin (90%) and fibrillin-rich microfibrils (10%), are the key extracellular components, which endow the arteries with elasticity. The alteration of elastic fibers leads to cardiovascular dysfunctions, as observed in elastin haploinsufficiency in mice ( Eln +/- ) or humans (supravalvular aortic stenosis or Williams-Beuren syndrome). In Eln +/+ and Eln +/- mice, we evaluated (arteriography, histology, qPCR, Western blots and cell cultures) the beneficial impact of treatment with a synthetic elastic protein (SEP), mimicking several domains of tropoelastin, the precursor of elastin, including hydrophobic elasticity-related domains and binding sites for elastin receptors. In the aorta or cultured aortic smooth muscle cells from these animals, SEP treatment induced a synthesis of elastin and fibrillin-1, a thickening of the aortic elastic lamellae, a decrease in wall stiffness and/or a strong trend toward a reduction in the elastic lamella disruptions in Eln +/- mice. SEP also modified collagen conformation and transcript expressions, enhanced the aorta constrictive response to phenylephrine in several animal groups, and, in female Eln +/- mice, it restored the normal vasodilatory response to acetylcholine. SEP should now be considered as a biomimetic molecule with an interesting potential for future treatments of elastin-deficient patients with altered arterial structure/function.
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