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Abstract

It has been shown that the KCa3.1 channel-specific blocker, TRAM34, is a promising antiatherosclerosis (AS) agent, but its side effects restrict its clinical application. Notably, its effect on endothelial progenitor cells (EPCs) is unclear. We aim to unravel the effect of TRAM34 on EPCs and identify the underlying mechanism. Rats were injected intraperitoneally with TRAM34, and EPCs were isolated from bone marrow. The gene and protein levels of corresponding factors were detected by real-time PCR, enzyme-linked immunosorbent assay, western blotting, and fluorescence-activated cell sorting. Liquid chromatography–tandem mass spectrometry (LC-MS) was applied to detect metabolite differences. We showed that when rats were treated with TRAM34 in vivo, colony formation and proliferation of early EPCs were reduced, but their senescence and apoptosis were enhanced. Moreover, TRAM34 enhanced NOX activity, promoted an increase in intracellular ROS levels, increased PKC expression, and subsequently promoted EPC senescence, which is unfavorable for EPC angiogenesis in vivo and in vitro. Combining these results with LC-MS data, we found that TRAM34 significantly promoted pyrimidine and purine metabolism, leading to cellular senescence. Furthermore, the NOX inhibitor, Setanaxib, enhanced antioxidant metabolic pathways, especially S-adenosylmethioninamine (SAM) metabolism, to exert an antisenescence effect. Finally, we confirmed that SAM alleviates TRAM34-induced cellular senescence, suggesting an efficient approach to improve the quality of endogenous EPCs. This study reveals the mechanism of TRAM34-induced EPC senescence, providing a solution for the extended application of KCa3.1 inhibitor in AS.

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References

Wei

, Gutman

, Aldrich

, Chandy

, Grissmer

and Wulff

. (2005). International Union of Pharmacology. LII. Nomenclature and molecular relationships of calcium-activated potassium channels. Pharmacol Rev, 57:463–472.

Grimaldi

, D'Alessandro

, Golia

, Grossinger

, Di Angelantonio

, Ragozzino

, Santoro

, Esposito

, Wulff

, Catalano

and Limatola

. (2016). KCa3.1 inhibition switches the phenotype of glioma-infiltrating microglia/macrophages. Cell Death Dis, 7:e2174.

Freise

and Querfeld

. (2014). Inhibition of vascular calcification by block of intermediate conductance calcium-activated potassium channels with TRAM-34. Pharmacol Res, 85:6–14.

Fei

, Wang

, Hou

, Li

, Cai

, Yang

, Zhang

, Wei

, Chen

, Wang

and Li

. (2019). Macrophages facilitate post myocardial infarction arrhythmias: roles of gap junction and KCa3.1. Theranostics, 9:6396–6411.

Toyama

, Wulff

, Chandy

, Azam

, Raman

, Saito

, Fujiwara

, Mattson

, Das

, et al. (2008). The intermediate-conductance calcium-activated potassium channel KCa3.1 contributes to atherogenesis in mice and humans. J Clin Investig, 118:3025–3037.

, Li

, Wu

, Shen

, Ma

, Qian

and Ge

. (2017). Role of KCa3.1 channels in macrophage polarization and its relevance in atherosclerotic plaque instability. Arterioscler Thromb Vasc Biol, 37:226–236.

Grgic

, Eichler

, Heinau

, Si

, Brakemeier

, Hoyer

and Köhler

. (2005). Selective blockade of the intermediate-conductance Ca2+-activated K+ channel suppresses proliferation of microvascular and macrovascular endothelial cells and angiogenesis in vivo. Arterioscler Thromb Vasc Biol, 25:704–709.

Zhu

Y-R

, Jiang

X-X

and Zhang

D-M

. (2019). Critical regulation of atherosclerosis by the KCa3.1 channel and the retargeting of this therapeutic target in in-stent neoatherosclerosis. J Mol Med, 97:1219–1229.

Rahimi

, Yubero-Serrano

, Fernandez-Gandara

, Garcia-Rios

, Rangel-Zuñiga

, Gutierrez-Mariscal

, Torres-Peña

, Marin

, Lopez-Moreno

, et al. (2020). Mediterranean diet and endothelial function in patients with coronary heart disease: an analysis of the CORDIOPREV randomized controlled trial. PLoS Med, 17:e1003282.

10.

Hristov

and Weber

. (2008). Endothelial progenitor cells in vascular repair and remodeling. Pharmacol Res, 58:148–151.

11.

Strobaek

, Brown

, Jenkins

, Chen

, Coleman

, Ando

, Chiu

, Jorgensen

, Demnitz

, Wulff

and Christophersen

. (2013). NS6180, a new K(Ca) 3.1 channel inhibitor prevents T-cell activation and inflammation in a rat model of inflammatory bowel disease. Br J Pharmacol, 168:432–444.

12.

, Feng

, Ke

, Qiu

, He

, Wang

, Li

, Xu

, Shi

and Xiong

. (2020). KCNN4 promotes invasion and metastasis through the MAPK/ERK pathway in hepatocellular carcinoma. J Investig Med, 68:68–74.

13.

Grgic

, Eichler

, Heinau

, Si

, Brakemeier

, Hoyer

and Kohler

14.

, Xia

, Yang

, Huang

, Gao

, Zhou

, Lian

and Zhou

. (2012). Intermediate-conductance Ca(2+)-activated potassium and volume-sensitive chloride channels in endothelial progenitor cells from rat bone marrow mononuclear cells. Acta Physiol (Oxf), 205:302–313.

15.

, He

, Bu

, Wang

, Yu

, Li

, Zhang

, Cui

and Cheng

. (2020). Oscillating shear stress mediates mesenchymal transdifferentiation of EPCs by the Kir2.1 channel. Heart Vessels, 35:1473–1482.

16.

Gao

, Cui

, Wang

, Zhang

, He

, Li

, Zhang

and Cheng

. (2020). Oscillatory shear stress induces the transition of EPCs into mesenchymal cells through ROS/PKCzeta/p53 pathway. Life Sci, 253:117728.

17.

Zhang

, Cui

, Li

, Yan

, Li

, Guan

, Wang

, Liu

, Qin

and Cheng

. (2019). Inhibition of Kir2.1 channel-induced depolarization promotes cell biological activity and differentiation by modulating autophagy in late endothelial progenitor cells. J Mol Cell Cardiol, 127:57–66.

18.

, Wang

, Mei

, Wang

and Cheng

. (2018). Human adipose mesenchymal stem cells show more efficient angiogenesis promotion on endothelial colony-forming cells than umbilical cord and endometrium. Stem Cells Int, 2018:7537589.

19.

Zhang

, Liu

, Xiong

, Zhang

, Kang

, Gao

, Li

, Ge

, Cheng

, et al. (2020). Microbiota from alginate oligosaccharide-dosed mice successfully mitigated small intestinal mucositis. Microbiome, 8:112.

20.

Shao

, Cheng

, Li

and Ni

. (2020). Liquid chromatography-mass spectrometry-based plasma metabolomics study of the effects of moxibustion with seed-sized moxa cone on hyperlipidemia. Evid Based Complement Alternat Med, 2020:1231357.

21.

Hur

, Yoon

, Kim

, Choi

, Kang

, Hwang

, Oh

, Lee

and Park

. (2004). Characterization of two types of endothelial progenitor cells and their different contributions to neovasculogenesis. Arterioscler Thromb Vasc Biol, 24:288–293.

22.

Fujita

and Kawamoto

. (2017). Stem cell-based peripheral vascular regeneration. Adv Drug Deliv Rev, 120:25–40.

23.

Rastogi

, Geng

, Li

and Ding

. (2016). NOX Activation by subunit interaction and underlying mechanisms in disease. Front Cell Neurosci, 10:301.

24.

Panday

, Sahoo

, Osorio

and Batra

. (2015). NADPH oxidases: an overview from structure to innate immunity-associated pathologies. Cell Mol Immunol, 12:5–23.

25.

and Wu

. (2009). CD133 as a marker for cancer stem cells: progresses and concerns. Stem Cells Dev, 18:1127–1134.

26.

Griguer

, Oliva

, Gobin

, Marcorelles

, Benos

, Lancaster

Jr. and Gillespie

. (2008). CD133 is a marker of bioenergetic stress in human glioma. PLoS One, 3:e3655.

27.

Kutikhin

, Sinitsky

, Yuzhalin

and Velikanova

. (2018). Shear stress: an essential driver of endothelial progenitor cells. J Mol Cell Cardiol, 118:46–69.

28.

De Marchi

, Baldassari

, Bononi

, Wieckowski

and Pinton

. (2013). Oxidative stress in cardiovascular diseases and obesity: role of p66Shc and protein kinase C. Oxid Med Cell Longev, 2013:564961.

29.

Krylatov

, Maslov

, Voronkov

, Boshchenko

, Popov

, Gomez

, Wang

, Jaggi

and Downey

. (2018). Reactive oxygen species as intracellular signaling molecules in the cardiovascular system. Curr Cardiol Rev, 14:290–300.

30.

Burtenshaw

, Hakimjavadi

, Redmond

and Cahill

. (2017). Nox, reactive oxygen species and regulation of vascular cell fate. Antioxidants (Basel), 6:90.

31.

Fukai

and Ushio-Fukai

. (2020). Cross-talk between NADPH oxidase and mitochondria: Role in ROS signaling and angiogenesis. Cells, 9:1849.

32.

Kim

, Eom

and Koh

. (2020). Mechanism of zinc excitotoxicity: A focus on AMPK. Front Neurosci, 14:577958.

33.

Vrijsen

, Besora-Casals

, van Veen

, Zielich

, Van den Haute

, Hamouda

, Fischer

, Ghesquiere

, Tournev

, et al. (2020). ATP13A2-mediated endo-lysosomal polyamine export counters mitochondrial oxidative stress. Proc Natl Acad Sci U S A, 117:31198–31207.

34.

Murray Stewart

, Dunston

, Woster

and Casero

Jr . (2018). Polyamine catabolism and oxidative damage. J Biol Chem, 293:18736–18745.

35.

Loenen

WAM

. (2018). S-adenosylmethionine metabolism and aging. In: Epigenetics of Aging and Longevity. Moskalev

, Vaiserman

, eds. Academic Press, Cambridge, MA, pp 59–93.

36.

Iorio

, Petroni

, Duranti

and Lastraioli

. (2019). Potassium and sodium channels and the Warburg effect: Biophysical regulation of cancer metabolism. Bioelectricity, 1:188–200.

37.

Ouyang

, Wu

, Li

, Sun

and Sun

. (2020). S-adenosylmethionine: a metabolite critical to the regulation of autophagy. Cell Prolif, 53:e12891.

38.

Zhang

, Sun

, Liu

, Xie

, Cui

and Zhu

. (2015). Homocysteine accelerates senescence of endothelial cells via DNA hypomethylation of human telomerase reverse transcriptase. Arterioscler Thromb Vasc Biol, 35:71–78.

39.

Wilson

, Zhang

, Lee

, MacDonald

, Heathcote

, Alorfi

NMN

, Buckley

, Dolan

and McCarron

. (2020). Disrupted endothelial cell heterogeneity and network organization impair vascular function in prediabetic obesity. Metabolism, 111:154340.

40.

Triggle

, Ding

, Marei

, Anderson

and Hollenberg

. (2020). Why the endothelium? The endothelium as a target to reduce diabetes-associated vascular disease. Can J Physiol Pharmacol, 98:415–430.

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Combined NOX/ROS/PKC Signaling Pathway and Metabolomic Analysis Reveals the Mechanism of TRAM34-Induced Endothelial Progenitor Cell Senescence

Abstract

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