Abstract Background The thoracic aortic aneurysm or dissection (TAAD) is a fatal cardiovascular disease with unclear pathogenic mechanisms. Integrins are important in coordinating the transmembrane connections between the extracellular matrix (ECM) and cytoskeleton, contributing to pathological processes of various diseases. Integrin α9 (Itga9), one of the integrin family subunits, has emerged as critical for vascular homeostasis. However, the contribution of Itga9 to TAAD remains elusive. Purpose The present study aimed to determine the role of Itga9 in the development of TAAD and its underlying mechanisms. Methods Western blotting and immunofluorescence staining were used to evaluate ITGA9 expression in the human Standford-A AAD tissues and rodent model of TAAD. Beta-aminopropionitrile monofumarate (BAPN) was used to induce TAAD mouse model. Vascular smooth muscle cell (VSMC)-specific Itga9 knockout mice or adeno-associated virus (AAV)-treated Itga9 overexpressed mice were generated to detect the role of Itga9 in the progression of TAAD. RNA-sequencing analysis was performed to discern possible transcriptome changes in the aorta tissues of VSMC-specific Itga9 knockout mice after BAPN treatment. Primary mouse aortic VSMC culture, flow cytometry analysis, EdU incorporation assay, transmission electron microscopy, and autophagy flux experiments were performed to evaluate the function of Itga9 on VSMCs and uncover its downstream target. Results ITGA9 expression levels were reduced in the aorta tissues of Standford-A AAD patients and BAPN-induced TAAD mice. VSMC-specific deletion of Itga9 exacerbated the incidence of BAPN-induced TAAD in mice. Itga9 deficiency downregulated Valosin-containing protein (Vcp) expression in mice aorta and caused reduced autophagy biomarkers of LC3 after BAPN treatment. In the primary aortic VSMCs, Itga9 deficiency resulted in repressed autophagy, accelerated apoptosis, and reduced proliferation ability. Mechanistically, Itga9 recruited the transcription factor Pre-B-cell leukemia transcription factor 1 (Pbx1) to activate the Vcp and promote VSMC autophagy. Consistently, overexpression of Itga9 in vitro and in vivo rescued the autophagic change and protected against the TAAD progression by upregulating the expression of Pbx1 and Vcp. Conclusions Our findings indicate a critical role of Itga9 in the regulation of VSMC autophagy by controlling Pbx1-Vcp. The Itga9-Pbx1-Vcp axis may represent a novel therapeutic target against TAAD.
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