Membrane TNF-alpha-activated programmed necrosis is mediated by Ceramide-induced reactive oxygen species.

Q2 Biochemistry, Genetics and Molecular Biology

Journal of Molecular Signaling Pub Date : 2013-11-01 DOI:10.1186/1750-2187-8-12

Shidrokh Ardestani, Desirae L Deskins, Pampee P Young

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引用次数: 53

Abstract

Background: Programmed necrosis is a form of caspase-independent cell death whose molecular regulation is poorly understood. While tumor necrosis factor-alpha (TNF-α) has been identified as an activator of programmed necrosis, the specific context under which this can happen is unclear. Recently we reported that TNF-α can be expressed by human tumor cells as both a membrane tethered (mTNF-α) and a soluble (sTNF-α) form. Whereas low level, tumor-derived sTNF-α acts as a tumor promoter, tumor cell expression of mTNF-α significantly delays tumor growth in mice, in large part by induction of programmed necrosis of tumor associated myeloid cells. In this study we sought to determine the molecular mechanism involved in mTNF-α oxidative stress-induced cell death by evaluating the known pathways involved in TNF receptor-induced programmed necrosis.

Methods: The source of Reactive Oxygen Species (ROS) in mTNF-α treated cells was determined by coculturing RAW 264.7 monocytic and L929 fibroblasts cells with fixed B16F10 control or mTNF-α expressing-melanoma cells in the presence of inhibitors of NADPH and mitochondria ROS. To identify the down-stream effector of TNF-a receptors (TNFR), level of phospho-RIP-1 and ceramide activity were evaluated.To determine whether mTNF-mediated cell death was dependent on a specific TNFR, cell death was measured in primary CD11b myeloid cells isolated from wild-type or TNFR-1, TNFR-2, TNFR-1 and TNFR-2 double knockout mice, cocultured with various TNF-α isoform.

Results: Tumor derived-mTNF-α increased ROS-mediated cytotoxicity, independent of caspase-3 activity. Although TNFR on target cells were required for this effect, we observed that mTNF-induced cell death could be mediated through both TNFR-1 and the death domain-lacking TNFR-2. ROS generation and cytotoxicity were inhibited by a mitochondrial respiratory chain inhibitor but not by an inhibitor of NADPH oxidase. mTNF-α mediated cytotoxicity was independent of RIP-1, a serine/threonine kinase that serves as a main adaptor protein of sTNF-α induced programmed necrosis. Instead, mTNF-α-induced ROS and cell death was prohibited by the ceramide-activated protein kinase (CAPK) inhibitor.

Conclusion: These findings demonstrate that the mTNF-α isoform is an effective inducer of programmed necrosis through a caspase independent, ceramide-related pathway. Interestingly, unlike sTNFα, mTNF-induced programmed necrosis is not dependent on the presence of TNFR1.

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膜tnf - α激活的程序性坏死是由神经酰胺诱导的活性氧介导的。

背景:程序性坏死是一种不依赖半胱天酶的细胞死亡形式，其分子调控机制尚不清楚。虽然肿瘤坏死因子-α (TNF-α)已被确定为程序性坏死的激活剂，但其发生的具体背景尚不清楚。最近我们报道了TNF-α可以在人肿瘤细胞中以膜系结(mTNF-α)和可溶性(sTNF-α)形式表达。而低水平的肿瘤源性sTNF-α作为肿瘤启动子，肿瘤细胞表达mTNF-α在小鼠中显著延迟肿瘤生长，这在很大程度上是通过诱导肿瘤相关骨髓细胞的程序性坏死。在这项研究中，我们试图通过评估TNF受体诱导的程序性坏死的已知途径来确定mTNF-α氧化应激诱导的细胞死亡的分子机制。方法:在NADPH和线粒体ROS抑制剂存在的情况下，将RAW 264.7单核细胞和L929成纤维细胞与固定B16F10对照或表达mTNF-α的黑色素瘤细胞共培养，测定mTNF-α处理细胞中活性氧(ROS)的来源。为了鉴定TNF-a受体(TNFR)的下游效应，我们评估了磷酸化- rip -1水平和神经酰胺活性。为了确定mtnf介导的细胞死亡是否依赖于特定的TNFR，我们从野生型或TNFR-1、TNFR-2、TNFR-1和TNFR-2双敲除小鼠中分离的原代CD11b骨髓细胞，与各种TNF-α亚型共培养，测量细胞死亡。结果:肿瘤源性mtnf -α增加ros介导的细胞毒性，与caspase-3活性无关。虽然这种作用需要靶细胞上的TNFR，但我们观察到mtnf诱导的细胞死亡可以通过TNFR-1和缺乏死亡结构域的TNFR-2介导。线粒体呼吸链抑制剂能抑制ROS的产生和细胞毒性，而NADPH氧化酶抑制剂不能抑制ROS的产生和细胞毒性。mTNF-α介导的细胞毒性不依赖于RIP-1, RIP-1是一种丝氨酸/苏氨酸激酶，是sTNF-α诱导的程序性坏死的主要衔接蛋白。相反，神经酰胺活化蛋白激酶(CAPK)抑制剂可抑制mTNF-α-诱导的ROS和细胞死亡。结论:这些发现表明mTNF-α异构体是一种有效的程序性坏死诱导剂，其途径与半胱天蛋白酶无关，与神经酰胺相关。有趣的是，与sTNFα不同，mtnf诱导的程序性坏死不依赖于TNFR1的存在。

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Journal of Molecular Signaling Biochemistry, Genetics and Molecular Biology-Biochemistry

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期刊介绍： Journal of Molecular Signaling is an open access, peer-reviewed online journal that encompasses all aspects of molecular signaling. Molecular signaling is an exponentially growing field that encompasses different molecular aspects of cell signaling underlying normal and pathological conditions. Specifically, the research area of the journal is on the normal or aberrant molecular mechanisms involving receptors, G-proteins, kinases, phosphatases, and transcription factors in regulating cell proliferation, differentiation, apoptosis, and oncogenesis in mammalian cells. This area also covers the genetic and epigenetic changes that modulate the signaling properties of cells and the resultant physiological conditions.