Mandatory role of endoplasmic reticulum and its pentose phosphate shunt in the myocardial defense mechanisms against the redox stress induced by anthracyclines.

IF 3.5 2区 生物学 Q3 CELL BIOLOGY Molecular and Cellular Biochemistry Pub Date : 2024-11-01 Epub Date: 2023-12-12 DOI:10.1007/s11010-023-04903-z
Gianmario Sambuceti, Vanessa Cossu, Francesca Vitale, Eva Bianconi, Sonia Carta, Consuelo Venturi, Sabrina Chiesa, Francesco Lanfranchi, Laura Emionite, Sebastiano Carlone, Luca Sofia, Francesca D'Amico, Tania Di Raimondo, Silvia Chiola, Anna Maria Orengo, Silvia Morbelli, Pietro Ameri, Matteo Bauckneht, Cecilia Marini
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引用次数: 0

Abstract

Anthracyclines' cardiotoxicity involves an accelerated generation of reactive oxygen species. This oxidative damage has been found to accelerate the expression of hexose-6P-dehydrogenase (H6PD), that channels glucose-6-phosphate (G6P) through the pentose phosphate pathway (PPP) confined within the endoplasmic/sarcoplasmic reticulum (SR). To verify the role of SR-PPP in the defense mechanisms activated by doxorubicin (DXR) in cardiomyocytes, we tested the effect of this drug in H6PD knockout mice (H6PD-/-). Twenty-eight wildtype (WT) and 32 H6PD-/- mice were divided into four groups to be treated with intraperitoneal administration of saline (untreated) or DXR (8 mg/Kg once a week for 3 weeks). One week thereafter, survivors underwent imaging of 18F-deoxyglucose (FDG) uptake and were sacrificed to evaluate the levels of H6PD, glucose-6P-dehydrogenase (G6PD), G6P transporter (G6PT), and malondialdehyde. The mRNA levels of SR Ca2+-ATPase 2 (Serca2) and ryanodine receptors 2 (RyR2) were evaluated and complemented with Hematoxylin/Eosin staining and transmission electron microscopy. During the treatment period, 1/14 DXR-WT and 12/18 DXR-H6PD-/- died. At microPET, DXR-H6PD-/- survivors displayed an increase in left ventricular size (p < 0.001) coupled with a decreased urinary output, suggesting a severe hemodynamic impairment. At ex vivo analysis, H6PD-/- condition was associated with an oxidative damage independent of treatment type. DXR increased H6PD expression only in WT mice, while G6PT abundance increased in both groups, mismatching a generalized decrease of G6PD levels. Switching-off SR-PPP impaired reticular accumulation of Ca2+ decelerating Serca2 expression and upregulating RyR2 mRNA level. It thus altered mitochondrial ultrastructure eventually resulting in a cardiomyocyte loss. The recognized vulnerability of SR to the anthracycline oxidative damage is counterbalanced by an acceleration of G6P flux through a PPP confined within the reticular lumen. The interplay of SR-PPP with the intracellular Ca2+ exchanges regulators in cardiomyocytes configure the reticular PPP as a potential new target for strategies aimed to decrease anthracycline toxicity.

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内质网及其磷酸戊糖分流在心肌防御蒽环类药物引起的氧化还原压力的机制中起着强制性作用。
蒽环类药物的心脏毒性涉及活性氧的加速生成。研究发现,这种氧化损伤会加速己糖-6P-脱氢酶(H6PD)的表达,该酶通过磷酸戊糖途径(PPP)引导葡萄糖-6-磷酸(G6P)进入内质/肌质网(SR)。为了验证 SR-PPP 在多柔比星(DXR)激活的心肌细胞防御机制中的作用,我们在 H6PD 基因敲除小鼠(H6PD-/-)中测试了这种药物的效果。我们将 28 只野生型(WT)小鼠和 32 只 H6PD-/- 小鼠分成四组,分别腹腔注射生理盐水(未处理)或 DXR(8 毫克/千克,每周一次,连续 3 周)。一周后,对存活小鼠进行 18F-脱氧葡萄糖(FDG)摄取成像,并对 H6PD、葡萄糖-6P-脱氢酶(G6PD)、G6P 转运体(G6PT)和丙二醛的水平进行评估。此外,还对 SR Ca2+-ATPase 2(Serca2)和雷诺丁受体 2(RyR2)的 mRNA 水平进行了评估,并辅以 Hematoxylin/Eosin 染色和透射电子显微镜检查。在治疗期间,1/14 的 DXR-WT 和 12/18 的 DXR-H6PD-/- 死亡。在 microPET 上,DXR-H6PD-/- 存活者的左心室体积增大(p -/-)与氧化损伤有关,与治疗类型无关。DXR 仅在 WT 小鼠中增加了 H6PD 的表达,而在两组小鼠中 G6PT 的丰度都增加了,这与 G6PD 水平的普遍下降不匹配。关闭 SR-PPP 会阻碍 Ca2+ 在网状结构中的积聚,降低 Serca2 的表达并上调 RyR2 mRNA 水平。因此,它改变了线粒体的超微结构,最终导致心肌细胞丧失。公认的 SR 易受蒽环类药物氧化损伤,而网状结构腔内的 PPP 可加速 G6P 通量,从而抵消这种损伤。SR-PPP 与心肌细胞内 Ca2+ 交换调节器的相互作用将网状结构 PPP 配置为旨在降低蒽环类药物毒性的潜在新靶点。
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来源期刊
Molecular and Cellular Biochemistry
Molecular and Cellular Biochemistry 生物-细胞生物学
CiteScore
8.30
自引率
2.30%
发文量
293
审稿时长
1.7 months
期刊介绍: Molecular and Cellular Biochemistry: An International Journal for Chemical Biology in Health and Disease publishes original research papers and short communications in all areas of the biochemical sciences, emphasizing novel findings relevant to the biochemical basis of cellular function and disease processes, as well as the mechanics of action of hormones and chemical agents. Coverage includes membrane transport, receptor mechanism, immune response, secretory processes, and cytoskeletal function, as well as biochemical structure-function relationships in the cell. In addition to the reports of original research, the journal publishes state of the art reviews. Specific subjects covered by Molecular and Cellular Biochemistry include cellular metabolism, cellular pathophysiology, enzymology, ion transport, lipid biochemistry, membrane biochemistry, molecular biology, nuclear structure and function, and protein chemistry.
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