Abstract

Abstract Funding Acknowledgements Type of funding sources: None. Introduction Atherosclerotic lesions preferentially develop in arterial regions exposed to disturbed blood flow, which are characterized by a dysfunctional proinflammatory endothelial cell (EC) phenotype. ECs release ATP in response to changes in wall shear stress (WSS), which subsequently regulates the inflammatory response. ATP can be released from cells in a controlled manner through Pannexin1 (Panx1) channels. Objective To study the expression of Panx1 in response to WSS and its role in the endothelium. Methods Human ECs (HUVECs or EA.hy926) were exposed to physiological high laminar shear stress (HLSS) and atheroprone oscillatory shear stress (OSS) for 48h using an orbital shaker. Panx1 transcript and protein levels were determined by qPCR and Western blot, respectively. mRNA was extracted for RNAseq. WSS-modifying casts were placed for 1 week around the carotid artery of mice and Panx1 expression was analyzed en face. Carotid WSS-modifying casts were also placed in Tie2CreTgPanx1fl/flApoE-/- and Panx1fl/flApoE-/- mice followed by 9 weeks high fat diet. CD68+ cells were quantified in OSS-induced atherosclerotic lesions. Results We found that Panx1 expression was increased in carotid regions exposed to OSS as compared to HLSS regions. These results were confirmed in vitro in HUVECs. In silico analysis of the promotor of Panx1 revealed binding sites for the WSS-sensitive transcription factors NF-kB and CREB. NF-kB and CREB mRNA levels were similar under OSS and HLSS, however NF-kB activation (phospho-NF-kB) was detected in ECs under OSS. Surprisingly, Panx1 mRNA level was not affected under these conditions, suggesting that the increased Panx1 protein observed under OSS may be due to decreased Panx1 degradation rather than to increased synthesis of the protein. Unbiased analysis of differential gene expression in ECs exposed to HLSS or OSS revealed 320 up-regulated and 353 down-regulated genes under OSS. Down-regulated genes included proteins involved in macro-autophagy. Inhibition of macro-autophagy in ECs by exposure to chloroquine for 6h increased the expression of glycosylated Panx1, suggestive for more Panx1 channels at the plasma membrane under these conditions. Finally, we observed that atherosclerotic lesions in OSS regions of Tie2CreTgPanx1fl/flApoE-/- mice contained more CD68+ cells than Panx1fl/flApoE-/- controls. Conclusion Endothelial Panx1 expression is upregulated in response to OSS. Absence of OSS effects on NF-kB, CREB and Panx1 mRNA revealed that the upregulation of Panx1 protein is not due to transcriptional effects of OSS. Expression of genes involved in the macro-autophagic process were down-regulated under OSS, and chemical inhibition of macro-autophagy augmented the plasma membranous form of Panx1. OSS-induced decrease in autophagic flux may enhance ATP release through Panx1 channels, thereby counterbalancing leukocyte recruitment in atherosclerosis.

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