核 WWOX/TRAF2 开关的分离使紫外线/冷休克介导的核气泡细胞在低温下死亡。

IF 8.2 2区 生物学 Q1 CELL BIOLOGY Cell Communication and Signaling Pub Date : 2024-10-17 DOI:10.1186/s12964-024-01866-6
Szu-Jung Chen, Cheng-Chang Tsai, Sing-Ru Lin, Ming-Hui Lee, Shenq-Shyang Huang, Han-Yan Zeng, Lu-Hai Wang, Ming-Fu Chiang, Hamm-Ming Sheu, Nan-Shan Chang
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引用次数: 0

摘要

背景:正常细胞表达功能性肿瘤抑制因子含WW结构域氧化还原酶(WWOX),即WWOXf。紫外线照射会诱导 WWOXf 细胞发生气泡细胞死亡(BCD)--在室温(22 °C)及以下温度条件下,由于核内一氧化氮(NO)气体的积累,会强行推动核膜和细胞膜形成一个或两个气泡。相反,当WWOX缺陷或功能障碍(WWOXd)细胞暴露于紫外线和/或冷冲击时,细胞会发生核弹出爆炸死亡(POD)。我们的目的是确定 WWOXf 细胞在 BCD 与凋亡过程中的形态和生化变化:方法:将 WWOXf 和 WWOXd 细胞暴露于紫外线下,然后在 4、22 或 37 °C下通过延时显微镜和/或延时全息显微镜测量 BCD 或 POD,以观察形态变化。活细胞染色用于测量一氧化氮(NO)产生和 Ca2+ 流入的动力学。细胞死亡的程度通过碘化丙啶的吸收和琼脂糖凝胶电泳的核糖体DNA片段来测量:结果:WWOXf细胞先暴露于紫外线,然后受到冷休克,或先受到冷休克,然后受到紫外线,并分别在4、10和22 °C下培养。最初,紫外线诱导钙离子流入和氮氧化物产生,导致细胞核起泡并最终死亡。在 37 °C下,冷休克预处理完全抑制了紫外线介导的起泡,因此紫外线/冷休克处理的细胞凋亡。在没有冷休克的情况下,紫外线只能在所有温度下诱导起泡,而在 37 ℃ 下起泡的效率降低了 50%以上。从形态上看,在细胞分裂或凋亡过程中,WWOXf 细胞高度或厚度明显增加,但在 BCD 中没有发生这种情况。相比之下,当 WWOXd 癌细胞接受紫外线或紫外线/冷休克时,这些细胞会发生与 NO 无关的 POD。在 WWOXf COS7 细胞中,紫外线/冷休克有效下调了许多蛋白质的表达,如管家蛋白 α-tubulin(> 70%)和 β-actin(70%)。紫外线/冷休克诱导α-微管蛋白迁移到细胞核,并在受损细胞中产生核气泡。紫外线诱导 WWOX/TRAF2 复合物共同转移到细胞核中,其中促凋亡的 TRAF2 通过其锌指结构域阻断了促凋亡的 WWOX。没有 WWOX,TRAF2 不会转移到细胞核。冷休克导致细胞核中的 WWOX/TRAF2 复合物解离,这是 BCD 所必需的。与此相反,37 °C时,细胞凋亡所需的WWOX/TRAF2复合物加上p53的形成得到了加强:结论:对温度敏感的核WWOX/TRAF2复合物就像一个分子开关,其解离有利于低温下的BCD,而在37 °C时的结合则支持紫外线处理的WWOXf细胞的凋亡。
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Dissociation of the nuclear WWOX/TRAF2 switch renders UV/cold shock-mediated nuclear bubbling cell death at low temperatures.

Background: Normal cells express functional tumor suppressor WW domain-containing oxidoreductase (WWOX), designated WWOXf. UV irradiation induces WWOXf cells to undergo bubbling cell death (BCD) - an event due to the accumulation of nuclear nitric oxide (NO) gas that forcefully pushes the nuclear and cell membranes to form one or two bubbles at room temperature (22 °C) and below. In contrast, when WWOX-deficient or -dysfunctional (WWOXd) cells are exposed to UV and/or cold shock, the cells undergo nuclear pop-out explosion death (POD). We aimed to determine the morphological and biochemical changes in WWOXf cells during BCD versus apoptosis.

Methods: WWOXf and WWOXd cells were exposed to UV followed by measuring BCD or POD by time-lapse microscopy and/or time-lapse holographic microscopy at 4, 22, or 37 °C to visualize morphological changes. Live cell stains were used to measure the kinetics of nitric oxide (NO) production and Ca2+ influx. Extent of cell death was measured by uptake of propidium iodide and by internucleosomal DNA fragmentation using agarose gel electrophoresis.

Results: WWOXf cells were exposed to UV and then cold shock, or cold shock and then UV, and cultured at 4, 10, and 22 °C, respectively. Initially, UV induced calcium influx and NO production, which led to nuclear bubbling and final death. Cold shock pretreatment completely suppressed UV-mediated bubbling at 37 °C, so the UV/cold shock-treated cells underwent apoptosis. Without cold shock, UV only induced bubbling at all temperatures, whereas the efficiency of bubbling at 37 °C was reduced by greater than 50%. Morphologically, the WWOXf cell height or thickness was significantly increased during cell division or apoptosis, but the event did not occur in BCD. In comparison, when WWOXd cancer cells received UV or UV/cold shock, these cells underwent NO-independent POD. UV/cold shock effectively downregulated the expression of many proteins such as the housekeeping α-tubulin (> 70%) and β-actin (< 50%), and cortactin (> 70%) in WWOXf COS7 cells. UV/cold shock induced relocation of α-tubulin to the nucleus and nuclear bubbles in damaged cells. UV induced co-translocation of the WWOX/TRAF2 complex to the nuclei, in which the prosurvival TRAF2 blocked the proapoptotic WWOX via its zinc finger domain. Without WWOX, TRAF2 did not relocate to the nuclei. Cold shock caused the dissociation of the WWOX/TRAF2 complex in the nucleus needed for BCD. In contrast, the formation of the WWOX/TRAF2 complex, plus p53, was strengthened at 37 °C required for apoptosis.

Conclusions: The temperature-sensitive nuclear WWOX/TRAF2 complex acts as a molecular switch, whose dissociation favors BCD at low temperatures, and the association supports apoptosis at 37 °C in UV-treated WWOXf cells.

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来源期刊
CiteScore
11.00
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180
期刊介绍: Cell Communication and Signaling (CCS) is a peer-reviewed, open-access scientific journal that focuses on cellular signaling pathways in both normal and pathological conditions. It publishes original research, reviews, and commentaries, welcoming studies that utilize molecular, morphological, biochemical, structural, and cell biology approaches. CCS also encourages interdisciplinary work and innovative models, including in silico, in vitro, and in vivo approaches, to facilitate investigations of cell signaling pathways, networks, and behavior. Starting from January 2019, CCS is proud to announce its affiliation with the International Cell Death Society. The journal now encourages submissions covering all aspects of cell death, including apoptotic and non-apoptotic mechanisms, cell death in model systems, autophagy, clearance of dying cells, and the immunological and pathological consequences of dying cells in the tissue microenvironment.
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