Short-term disruption of TGF-β signaling in adult mice renders the aorta vulnerable to hypertension-induced dissection
Bo Jiang, Pengwei Ren, Changshun He, Mo Wang, Sae-Il Murtada, María Jesús Ruiz-Rodríguez, Yu Chen, Abhay B. Ramachandra, Guangxin Li, Lingfeng Qin, Roland Assi, Martin A. Schwartz, Jay D. Humphrey, George Tellides
Bo Jiang, Pengwei Ren, Changshun He, Mo Wang, Sae-Il Murtada, María Jesús Ruiz-Rodríguez, Yu Chen, Abhay B. Ramachandra, Guangxin Li, Lingfeng Qin, Roland Assi, Martin A. Schwartz, Jay D. Humphrey, George Tellides
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Research Article Cell biology Vascular biology

Short-term disruption of TGF-β signaling in adult mice renders the aorta vulnerable to hypertension-induced dissection

Abstract

Hypertension and transient increases in blood pressure from extreme exertion are risk factors for aortic dissection in patients with age-related vascular degeneration or inherited connective tissue disorders. Yet, a common experimental model of angiotensin II–induced aortopathy in mice appears independent of high blood pressure, as lesions do not occur in response to an alternative vasoconstrictor, norepinephrine, and are not prevented by cotreatment with a vasodilator, hydralazine. We investigated vasoconstrictor administration to adult mice following 1 week of disrupted TGF-β signaling in smooth muscle cells (SMCs). Norepinephrine increased blood pressure and induced aortic dissection by 7 days and even within 30 minutes (as did angiotensin II) that was prevented by hydralazine. Initial medial injury manifested as blood extravasation among SMCs and fibrillar matrix, progressive delamination from accumulation of blood, and stretched or ruptured SMCs with persistent attachments to elastic fibers. Altered regulatory contractile molecule expression was not of pathological importance. Rather, reduced synthesis of extracellular matrix yielded a vulnerable aortic phenotype by decreasing medial collagen, most dynamically basement membrane–associated multiplexin collagen, and impairing cell-matrix adhesion. We conclude that transient and sustained increases in blood pressure can cause dissection in aortas rendered vulnerable by inhibition of TGF-β–driven extracellular matrix production by SMCs.

Authors

Bo Jiang, Pengwei Ren, Changshun He, Mo Wang, Sae-Il Murtada, María Jesús Ruiz-Rodríguez, Yu Chen, Abhay B. Ramachandra, Guangxin Li, Lingfeng Qin, Roland Assi, Martin A. Schwartz, Jay D. Humphrey, George Tellides

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Figure 4

Traction on and rapid fragmentation of SMCs.

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Traction on and rapid fragmentation of SMCs. Twelve-week-old Tgfbr1/2iSM...
Twelve-week-old Tgfbr1/2iSMCKO mice were infused with NE at 1.28 mg/kg i.p. for 30 minutes and the ascending aortas examined. Confocal microscopy after labeling smooth muscle α-actin (SMA) for SMC cytoskeleton (green), TER-119 for RBCs (red), Alexa Fluor 633–hydrazide for elastin (white), and DAPI for nuclei (blue) shows (A) intimomedial entry tear (arrow), (B) nonwidened inner laminae with SMCs adjacent to elastic fibers (arrow), (C) varying RBC accumulation in outer laminae, (D) widened laminae with radially oriented SMCs attached to ill-defined intralaminar elastic fibers (arrow), and (E) RBCs between SMCs (arrow). Alternative labeling of integrin α8 (ITGA8) for SMC plasma membrane (green) and binding of tdTomato-CNA35 to collagen (blue) shows (F) intimomedial entry tear (arrow), (G) nonwidened laminae with intact SMC plasma membranes (arrow), (H) varying RBC accumulation in outer laminae, (I) RBCs among SMCs (arrow), and (J) widened lamina with attached SMC plasma membrane fragments (arrow) and areas where elastic laminae are stripped clean of cell and fibrillar matrix. Transmission electron microscopy showing (K) RBC accumulation in outer laminae and (L) nonwidened lamina with SMCs contacting elastic (E) and collagen (C) fibers adjacent to widened lamina with RBCs abutting elastic and collagen fibers and cellular fragments (F). Pressure-fixed (A, F, K, and L) and unpressurized (BE and G-J) specimens. Scale bars: 50 μm (A, C, F, and H), 10 μm (B, D, E, G, and IK), and 2 μm (L).