ARHGEF17 Deficiency Induces Endothelial Dysfunction and Intracranial Aneurysm Formation via RhoA/ROCK2/MLC Signaling Pathway
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BACKGROUND
Genetic susceptibility is a major determinant in intracranial aneurysm (IA) formation and rupture, yet the underlying mechanisms linking genetic variation to vascular dysfunction remain largely unknown. We have identified mutations in ARHGEF17, a guanine nucleotide exchange factor that regulates RhoA activation and cytoskeletal organization, as potential risk variants for IA. Given ARHGEF17’s regulatory role in endothelial barrier integrity and actin remodeling, we hypothesized that ARHGEF17 deficiency promotes IA pathogenesis through dysregulation of the RhoA/ROCK2/MLC signaling axis, leading to endothelial dysfunction and vascular wall instability.
METHODS
CRISPR–Cas9–mediated ARHGEF17 knockout (ARHGEF17 ⁻/⁻ ) mice and morpholino-based ARHGEF17-deficient zebrafish were established to assess the in vivo vascular effects of ARHGEF17 loss. An intracranial aneurysm model combining elastase injection and deoxycorticosterone acetate (DOCA)–induced hypertension was used to evaluate aneurysm incidence, rupture rate, and survival. Structural remodeling of the Circle of Willis (CoW) was assessed by Victoria Blue, EVG, and Picrosirius Red staining, as well as immunofluorescence for α-SMA, OPN, CD31, and inflammatory markers. Complementary in vitro studies were performed in HUVECs using lentiviral ARHGEF17 silencing (three shRNAs of varying efficiency) to examine endothelial proliferation, migration, tube formation, and barrier function (TEER). Activation of RhoA/ROCK2/MLC signaling was quantified by G-LISA and Western blotting. The ROCK inhibitor Y-27632 (10 μM) was applied to determine pathway dependence.
RESULTS
ARHGEF17 ⁻/⁻ mice exhibited a significantly higher incidence and rupture rate of intracranial aneurysms, accompanied by fragmentation of elastic fibers, loss of collagen organization, vascular smooth muscle cell dedifferentiation, and robust inflammatory activation in the CoW. Zebrafish lacking ARHGEF17 showed frequent intracranial hemorrhage and compromised vascular wall integrity, further confirming ARHGEF17’s role in cerebrovascular stability. In ECs, ARHGEF17 knockdown impaired proliferation, migration, tube formation, and barrier integrity in a silencing-efficiency–dependent manner. Mechanistically, ARHGEF17 deficiency activated the RhoA/ROCK2/MLC pathway, leading to increased phosphorylation of MLC and MYPT1 and disorganization of F-actin and junctional proteins. Pharmacological inhibition with Y-27632 restored endothelial function, normalized cytoskeletal structure, and re-established junctional continuity, indicating a ROCK2-dependent mechanism.
CONCLUSIONS
Our findings establish ARHGEF17 as a critical regulator of cerebrovascular integrity and identify RhoA/ROCK2/MLC mediated cytoskeletal remodeling as the mechanistic link between ARHGEF17 deficiency and aneurysm pathogenesis. Loss of ARHGEF17 compromises endothelial barrier function, triggers vascular inflammation, and promotes aneurysm formation and rupture. Importantly, ROCK inhibition rescues endothelial dysfunction, highlighting the RhoA/ROCK2/MLC axis as a promising therapeutic target for ARHGEF17 mutation–associated intracranial aneurysms.
