Integration of flow-dependent endothelial phenotypes by Kruppel-like factor 2
Kush M. Parmar, H. Benjamin Larman, Guohao Dai, Yuzhi Zhang, Eric T. Wang, Sripriya N. Moorthy, Johannes R. Kratz, Zhiyong Lin, Mukesh K. Jain, Michael A. Gimbrone Jr., Guillermo García-Cardeña
Kush M. Parmar, H. Benjamin Larman, Guohao Dai, Yuzhi Zhang, Eric T. Wang, Sripriya N. Moorthy, Johannes R. Kratz, Zhiyong Lin, Mukesh K. Jain, Michael A. Gimbrone Jr., Guillermo García-Cardeña
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Research Article Cardiology

Integration of flow-dependent endothelial phenotypes by Kruppel-like factor 2

Abstract

In the face of systemic risk factors, certain regions of the arterial vasculature remain relatively resistant to the development of atherosclerotic lesions. The biomechanically distinct environments in these arterial geometries exert a protective influence via certain key functions of the endothelial lining; however, the mechanisms underlying the coordinated regulation of specific mechano-activated transcriptional programs leading to distinct endothelial functional phenotypes have remained elusive. Here, we show that the transcription factor Kruppel-like factor 2 (KLF2) is selectively induced in endothelial cells exposed to a biomechanical stimulus characteristic of atheroprotected regions of the human carotid and that this flow-mediated increase in expression occurs via a MEK5/ERK5/MEF2 signaling pathway. Overexpression and silencing of KLF2 in the context of flow, combined with findings from genome-wide analyses of gene expression, demonstrate that the induction of KLF2 results in the orchestrated regulation of endothelial transcriptional programs controlling inflammation, thrombosis/hemostasis, vascular tone, and blood vessel development. Our data also indicate that KLF2 expression globally modulates IL-1β–mediated endothelial activation. KLF2 therefore serves as a mechano-activated transcription factor important in the integration of multiple endothelial functions associated with regions of the arterial vasculature that are relatively resistant to atherogenesis.

Authors

Kush M. Parmar, H. Benjamin Larman, Guohao Dai, Yuzhi Zhang, Eric T. Wang, Sripriya N. Moorthy, Johannes R. Kratz, Zhiyong Lin, Mukesh K. Jain, Michael A. Gimbrone Jr., Guillermo García-Cardeña

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Figure 6

KLF2 expression is essential for endothelial cellular phenotypes conferred by flow.

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KLF2 expression is essential for endothelial cellular phenotypes conferr...
(A) HL-60 cell adhesion to HUVEC monolayers under the indicated conditions. After preconditioning (static or atheroprotective flow), the cells were treated with 1 U/ml of IL-1β for 6 hours and then incubated with fluorescently labeled HL-60 cells. Shown are representative fields of HUVEC monolayers (blue) and attached monocytes (yellow). The bar graph on the right displays quantification of bound HL-60 cells. (B) Role of KLF2 in flow-mediated resistance to oxidant stress. Cells under static conditions (top row) were infected with either Ad-GFP or Ad-KLF2 for 24 hours, and cells preconditioned with atheroprotective flow (bottom row) were treated with control or KLF2 siRNA. Cells were then incubated with or without 200 μM tert-butyl H2O2 for an additional 4 hours. (C) Total protein from GFP- or KLF2-expressing HUVECs blotted for catalase, manganese superoxide dismutase (MnSOD), or α-tubulin as a loading control. All data are expressed as mean ± SEM (n = 3). *P < 0.05 versus control; Student’s t test.