Shifting osteogenesis in vascular calcification
Jiayi Yao, Xiuju Wu, Xiaojing Qiao, Daoqin Zhang, Li Zhang, Jocelyn A. Ma, Xinjiang Cai, Kristina I. Boström, Yucheng Yao
Jiayi Yao, Xiuju Wu, Xiaojing Qiao, Daoqin Zhang, Li Zhang, Jocelyn A. Ma, Xinjiang Cai, Kristina I. Boström, Yucheng Yao
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Research Article Vascular biology

Shifting osteogenesis in vascular calcification

Abstract

Transitions between cell fates commonly occur in development and disease. However, reversing an unwanted cell transition in order to treat disease remains an unexplored area. Here, we report a successful process of guiding ill-fated transitions toward normalization in vascular calcification. Vascular calcification is a severe complication that increases the all-cause mortality of cardiovascular disease but lacks medical therapy. The vascular endothelium is a contributor of osteoprogenitor cells to vascular calcification through endothelial-mesenchymal transitions, in which endothelial cells (ECs) gain plasticity and the ability to differentiate into osteoblast-like cells. We created a high-throughput screening and identified SB216763, an inhibitor of glycogen synthase kinase 3 (GSK3), as an inducer of osteoblastic-endothelial transition. We demonstrated that SB216763 limited osteogenic differentiation in ECs at an early stage of vascular calcification. Lineage tracing showed that SB216763 redirected osteoblast-like cells to the endothelial lineage and reduced late-stage calcification. We also found that deletion of GSK3β in osteoblasts recapitulated osteoblastic-endothelial transition and reduced vascular calcification. Overall, inhibition of GSK3β promoted the transition of cells with osteoblastic characteristics to endothelial differentiation, thereby ameliorating vascular calcification.

Authors

Jiayi Yao, Xiuju Wu, Xiaojing Qiao, Daoqin Zhang, Li Zhang, Jocelyn A. Ma, Xinjiang Cai, Kristina I. Boström, Yucheng Yao

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Figure 3

Enhanced β-catenin decreases SMAD1, and together they mediate SB216763-induced osteoblastic-endothelial transition.

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Enhanced β-catenin decreases SMAD1, and together they mediate SB216763-i...
(A) Immunoblotting of SMAD1, phosphorylated SMAD1 (p-SMAD1), and β-catenin from osteoblasts treated with different doses of SB216763 (n = 6). (B) Immunoblotting of SMAD1 from osteoblasts transfected with β-catenin siRNA together with 10 μM SB216763 (n = 6). SCR, scrambled siRNA. (C) Immunoblotting of β-catenin, SMAD1, Cbfa1, osterix (OSX), Flk1, and VE-cadherin (VE-cad) from osteoblasts with overexpression of β-catenin or knockdown of SMAD1 or both (n = 6). β-Actin was used as control. CMV–β-catenin, CMV promoter–driven β-catenin cDNA. (D) Micro-CT images of ectopic bone formation and relative volume of bone formation in the implants after cell transplantation. Osteoblasts were used as controls. SB216763, SB216763-treated osteoblasts. SB216763/CMV-SMAD1, SB216763-treated osteoblasts infected with lentiviral vectors containing CMV promoter–driven SMAD1 cDNA. SB216763/β-catenin si, SB216763-treated osteoblasts infected with lentiviral vectors containing β-catenin siRNA (si) (n = 6). Scale bar: 5 mm. (E) Laser Doppler perfusion images and percentage of blood flow perfusion after cell transplantation (n = 8). Osteoblast and mouse pulmonary endothelial cells (ECs) were used as controls. Scale bar: 10 mm. D and E were analyzed for statistical significance by ANOVA with post hoc Tukey’s analysis. The bounds of the boxes are upper and lower quartiles. The line in the box is the median, and the whiskers are the maximum and minimal values. Data are shown as mean ± SD.