Inhibition of alphaV integrins with cilengitide downregulates in vitro pro-fibrotic events in aortic smooth muscle cells and limits in vivo thoracic aortic aneurysm progression

Abstract Funding Acknowledgements Type of funding sources: Public grant(s) – National budget only. Main funding source(s): Italian Ministry of Health "Ricerca Finalizzata - Giovani Ricercatori" Background The ‘greatest artery’, i.e., the aorta, can be affected by either acute conditions or chronic disorders, such as the aneurysm, which is the segmental aortic dilation with at least 50% increase in the normal diameter. Aortic dilation can often lead to lethal events, such as aortic dissection and/or vessel rupture. The aneurysms occurring in the thoracic trait of the aorta (TAA) may depend on comorbidities, such as hypertension (i.e., sporadic non-syndromic TAA, sTAA), or on genetically determined conditions, such as Marfan syndrome (MFS). To date, the surgical replacement of aorta represents the most effective therapeutic approach in all TAA patients, since an etiologic pharmacological treatment is still lacking. Thus, the identification of novel disease targets is mandatory. Integrin receptors are key players in cellular mechanotransduction responses. Specifically, integrins containing αV subunit have been described as important mechanotransduction mediators and responsible for pro-fibrotic molecular events. Recently, it has been reported the effectiveness of a broad αV integrin inhibitor in limiting the TAA progression by acting on FAK/AKT/mTORC signaling pathway in a MFS in vivo model. However, the specific αV integrin subgroup directly involved in this detrimental process is yet not known. Purpose We evaluated the effectiveness of a specific αVβ3 and αVβ5 integrin inhibitor (i.e., cilengitide) in downregulating pro-fibrotic in vitro events on vascular smooth muscle cells (VSMC) isolated from TAA patients’ aortic wall, and in limiting in vivo thoracic aortic dilation on a MFS mice model. Results By comparison with healthy control (HC)-VSMC, both sTAA-VSMC and MFS-VSMC showed higher levels of αVβ3 and αVβ5 integrins as well as pro-fibrotic collagen I. The in vitro inhibition of these two αV integrins mediated by cilengitide resulted more effective in collagen I downregulation when compared with GLPG0187 (pan αV inhibitor). Noteworthy, the cilengitide-mediated αV integrin inhibition consistently tempered pro-fibrotic phenotype of sTAA- and MFS-VSMC by directly acting on both canonical (p-SMAD2/3) and non-canonical (p-ERK1/2) TGF-β downstream pathways and by downregulating mechanotransduction mediators (e.g., RhoA GTPase, ROCK1, talin-1). The 2D-echocardio