Modern representations about signaling pathways and protective mechanisms of ferroptosis. A biological role of diffusion of death signals of ferroptotic cells

Vladimir I. Vashchenko, Elena F. Sorocoletova, Petr D. Shabanov
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Abstract

Ferroptosis as the type nonapoptosis adjustable destruction of cells arises and develops by means of difficult signals and regulatory mechanisms. The reactive oxygen species (ROS) used to initiate ferroptosis come from a variety of sources, including iron-mediated Fenton reactions, mitochondrial ROS, and membrane-associated ROS driven by the NOX protein family. Polyunsaturated fatty acid-containing phospholipids are the main substrates of lipid peroxidation in ferroptosis, which is positively regulated by enzymes, such as ACSL4, LPCAT3, ALOXs, or POR. Selective activation of autophagic degradation pathways promotes ferroptosis by increasing iron accumulation to cause lipid peroxidation. In contrast, system Xc-glutathioneGPX4 axis plays a central role in limiting lipid peroxidation, although other antioxidants (such as coenzyme Q10 and tetrahydrobiopterin) can also inhibit ferroptosis. A main nuclear mechanism of cell defense against ferroptosis is the activation of the NFE2L2-dependent antioxidant response by transcriptionally upregulating the expression of antioxidants or cytoprotective genes. Additionally, the membrane damage caused by ferroptotic stimulus can be repaired by ESCRT-III-dependent membrane scission machinery. In this review, we summarize recent progress in understanding the signaling pathways and defense mechanisms of ferroptosis.
铁下垂的信号通路及保护机制的现代研究进展。嗜铁细胞死亡信号扩散的生物学作用
铁凋亡作为一种非凋亡可调节的细胞破坏,通过复杂的信号和调控机制发生和发展。用于引发铁死亡的活性氧(ROS)有多种来源,包括铁介导的芬顿反应、线粒体ROS和由NOX蛋白家族驱动的膜相关ROS。含多不饱和脂肪酸的磷脂是铁下垂中脂质过氧化的主要底物,这一过程受到ACSL4、LPCAT3、ALOXs或POR等酶的正向调节。选择性激活自噬降解途径通过增加铁积累引起脂质过氧化促进铁下垂。相比之下,系统xc -谷胱甘肽egpx4轴在限制脂质过氧化中起核心作用,尽管其他抗氧化剂(如辅酶Q10和四氢生物terin)也可以抑制铁下垂。细胞防御铁凋亡的主要核机制是通过转录上调抗氧化剂或细胞保护基因的表达来激活nfe2l2依赖的抗氧化反应。此外,由高铁刺激引起的膜损伤可以通过escrt - iii依赖的膜断裂机制修复。本文就铁下垂的信号通路和防御机制的研究进展作一综述。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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