Nitric Oxide Plays a Dual Role in Cardiorenal Syndrome in Vitro Model.

IF 2.5 Q3 CELL BIOLOGY Cellular Physiology and Biochemistry Pub Date : 2024-01-22 DOI:10.33594/000000681
Giovana Marchini Armentano, Joana Claudio Pieretti, Carlos Alexandre Falconi, Amedea Barozzi Seabra, Marcela Sorelli Carneiro-Ramos
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Abstract

Background/aims: Nitric oxide (NO) plays a dual role, acting as both an oxidant and a reducer, with various effects depending on its concentration and environment. Acute kidney injury's (AKI) pathogenesis observed in cardiorenal syndrome 3 (CRS 3) involves inflammatory responses and the production of reactive oxygen and nitrogen species. However, the role of NO on the development of CRS 3 is still not completely understood. The study aimed to mimic CRS 3 in vitro and investigate NO signaling and inflammatory molecules.

Methods: Thus, HEK293 cells were submitted to normoxia (NX) or hypoxia (HX) protocols for 16 h followed by 3 h of reoxygenation, treated or not with L-NAME. Conditionate medium by HEK293 was transferred to H9c2 for 24 h. Cellular viability was evaluated by MTT assay, real time PCR was used to analyze gene expression and NO content were evaluated in the intra and extracellular medium by amperimetry.

Results: Carbonic anhydrase 9 (CA9) expression increased 2.9-fold after hypoxia. Hypoxia reduced 18 % cell viability in HEK293 that was restored by L-NAME treatment. The sum of nitrite (NO2-) and S-nitrosothiol (S-NO) fractions in HEK293 cells showed a substantial decrease on NO intracellular content (38 %). Both IL-6 and IL-10 decreased in all groups compared to NX cells. Besides TNF-α and Bax/Bcl2 ratio increased in hypoxia (approximately 120-fold and 600-fold, respectively) and L-NAME restored this effect. Regarding H9c2 cells, the S-NO fractions showed a substantial decrease in extracellular content after HX (17%) that was not restored by L-NAME. IL-1β decreases in cardiac cells treated with conditioned medium from HX/L-NAME.

Conclusion: In conclusion this study highlights the complex interplay of NO and inflammatory factors in hypoxia-induced renal and cardiac cell responses, with potential implications for cardiorenal syndrome.

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一氧化氮在心肾综合征体外模型中发挥双重作用
背景/目的:一氧化氮(NO)具有双重作用,既是氧化剂又是还原剂,其作用因浓度和环境而异。在心肾综合征 3(CRS 3)中观察到的急性肾损伤(AKI)发病机制涉及炎症反应以及活性氧和氮物种的产生。然而,人们对 NO 在 CRS 3 发生过程中的作用仍不完全清楚。本研究旨在体外模拟 CRS 3,研究 NO 信号传导和炎症分子:因此,将 HEK293 细胞置于常氧(NX)或低氧(HX)方案中 16 小时,然后复氧 3 小时,并用 L-NAME 处理或不处理。用 MTT 法评估细胞活力,用实时 PCR 分析基因表达,用安培法评估细胞内外培养基中 NO 的含量:结果:缺氧后,碳酸酐酶 9(CA9)的表达增加了 2.9 倍。缺氧降低了 HEK293 细胞 18% 的存活率,L-NAME 处理后可恢复存活率。HEK293 细胞中亚硝酸盐(NO2-)和亚硝基硫醇(S-NO)组分的总和显示,细胞内的 NO 含量大幅下降(38%)。与 NX 细胞相比,所有组中的 IL-6 和 IL-10 都有所下降。此外,TNF-α和Bax/Bcl2比率在缺氧情况下增加(分别约为120倍和600倍),而L-NAME可恢复这一效应。关于 H9c2 细胞,S-NO 组份在 HX 后显示细胞外含量大幅下降(17%),L-NAME 无法恢复。用 HX/L-NAME 条件培养基处理的心脏细胞中 IL-1β 减少:总之,这项研究强调了氮氧化物和炎症因子在缺氧诱导的肾脏和心脏细胞反应中复杂的相互作用,对心肾综合征具有潜在的影响。
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来源期刊
CiteScore
5.80
自引率
0.00%
发文量
86
审稿时长
1 months
期刊介绍: Cellular Physiology and Biochemistry is a multidisciplinary scientific forum dedicated to advancing the frontiers of basic cellular research. It addresses scientists from both the physiological and biochemical disciplines as well as related fields such as genetics, molecular biology, pathophysiology, pathobiochemistry and cellular toxicology & pharmacology. Original papers and reviews on the mechanisms of intracellular transmission, cellular metabolism, cell growth, differentiation and death, ion channels and carriers, and the maintenance, regulation and disturbances of cell volume are presented. Appearing monthly under peer review, Cellular Physiology and Biochemistry takes an active role in the concerted international effort to unravel the mechanisms of cellular function.
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