RhoBTB1 reverses established arterial stiffness in angiotensin II–induced hypertension by promoting actin depolymerization
Shi Fang, … , Frederick W. Quelle, Curt D. Sigmund
Shi Fang, … , Frederick W. Quelle, Curt D. Sigmund
Published March 31, 2022
Citation Information: JCI Insight. 2022;7(9):e158043. https://doi.org/10.1172/jci.insight.158043.
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Research Article Vascular biology

RhoBTB1 reverses established arterial stiffness in angiotensin II–induced hypertension by promoting actin depolymerization

Abstract

Arterial stiffness predicts cardiovascular disease and all-cause mortality, but its treatment remains challenging. Mice treated with angiotensin II (Ang II) develop hypertension, arterial stiffness, vascular dysfunction, and a downregulation of Rho-related BTB domain–containing protein 1 (RhoBTB1) in the vasculature. RhoBTB1 is associated with blood pressure regulation, but its function is poorly understood. We tested the hypothesis that restoring RhoBTB1 can attenuate arterial stiffness, hypertension, and vascular dysfunction in Ang II–treated mice. Genetic complementation of RhoBTB1 in the vasculature was achieved using mice expressing a tamoxifen-inducible, smooth muscle–specific RhoBTB1 transgene. RhoBTB1 restoration efficiently and rapidly alleviated arterial stiffness but not hypertension or vascular dysfunction. Mechanistic studies revealed that RhoBTB1 had no substantial effect on several classical arterial stiffness contributors, such as collagen deposition, elastin content, and vascular smooth muscle remodeling. Instead, Ang II increased actin polymerization in the aorta, which was reversed by RhoBTB1. Changes in the levels of 2 regulators of actin polymerization, cofilin and vasodilator-stimulated phosphoprotein, in response to RhoBTB1 were consistent with an actin depolymerization mechanism. Our study reveals an important function of RhoBTB1, demonstrates its vital role in antagonizing established arterial stiffness, and further supports a functional and mechanistic separation among hypertension, vascular dysfunction, and arterial stiffness.

Authors

Shi Fang, Jing Wu, John J. Reho, Ko-Ting Lu, Daniel T. Brozoski, Gaurav Kumar, Alec M. Werthman, Sebastiao Donato Silva Jr., Patricia C. Muskus Veitia, Kelsey K. Wackman, Angela J. Mathison, Bi Qing Teng, Chien-Wei Lin, Frederick W. Quelle, Curt D. Sigmund

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Figure 8

Actin polymerization.

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Actin polymerization. (A and B) F-actin and G-actin were separated by ul...
(A and B) F-actin and G-actin were separated by ultracentrifugation and assessed by Western blot (with 6–10 biological replicates, as indicated in the dot plot in B). The last lane was loaded with purified actin as a positive control. Molecular weight markers are as indicated in kilodaltons. (B) Densitometry was used to quantify F-actin and G-actin content in the Western blot. Actin polymerization was indicated by the ratio of F-actin to G-actin (n = 6–10, as indicated in the dot plot). One sample from the ISM-Cre vehicle group and another from the S-RhoBTB1 vehicle group were identified as outliers and were excluded using the Grubb’s outlier test. (C) Actin polymerization was confirmed using fluorescence staining in aorta (n = 4–7, as indicated in the dot plot in D). F-actin was stained with Alexa Fluor 594–phalloidin (red, upper panels) and G-actin was stained by Alexa Fluor 488–DNase I (green, lower panels). Scale bar: 100 μm. (D) MFI of the same volume of aortic samples was measured under the same optical configuration using confocal microscopy. Ratio of F-actin to G-actin was used to assess action polymerization. All data are presented as mean ± SEM (n = 4–7, as indicated in the dot plot). Two-way ANOVA with Tukey’s multiple comparisons were used for data analysis. *P < 0.05 vs. ISM-Cre, vehicle; #P < 0.05 vs. ISM-Cre, Ang II.