School of Life Sciences, University of Nottingham, Queen's Medical Centre, Nottingham, United Kingdom.
Deep-Seq Unit, School of Life Sciences, University of Nottingham, Queen's Medical Centre, Nottingham, United Kingdom.
PLoS One. 2020 Dec 17;15(12):e0244255. doi: 10.1371/journal.pone.0244255. eCollection 2020.
Reactive oxygen species are bona fide intracellular second messengers that influence cell metabolism and aging by mechanisms that are incompletely resolved. Mitochondria generate superoxide that is dis-mutated to hydrogen peroxide, which in turn oxidises cysteine-based enzymes such as phosphatases, peroxiredoxins and redox-sensitive transcription factors to modulate their activity. Signal Transducer and Activator of Transcription 3 (Stat3) has been shown to participate in an oxidative relay with peroxiredoxin II but the impact of Stat3 oxidation on target gene expression and its biological consequences remain to be established. Thus, we created murine embryonic fibroblasts (MEFs) that express either WT-Stat3 or a redox-insensitive mutant of Stat3 (Stat3-C3S). The Stat3-C3S cells differed from WT-Stat3 cells in morphology, proliferation and resistance to oxidative stress; in response to cytokine stimulation, they displayed elevated Stat3 tyrosine phosphorylation and Socs3 expression, implying that Stat3-C3S is insensitive to oxidative inhibition. Comparative analysis of global gene expression in WT-Stat3 and Stat3-C3S cells revealed differential expression (DE) of genes both under basal conditions and during oxidative stress. Using differential gene regulation pattern analysis, we identified 199 genes clustered into 10 distinct patterns that were selectively responsive to Stat3 oxidation. GO term analysis identified down-regulated genes to be enriched for tissue/organ development and morphogenesis and up-regulated genes to be enriched for cell-cell adhesion, immune responses and transport related processes. Although most DE gene promoters contain consensus Stat3 inducible elements (SIEs), our chromatin immunoprecipitation (ChIP) and ChIP-seq analyses did not detect Stat3 binding at these sites in control or oxidant-stimulated cells, suggesting that oxidised Stat3 regulates these genes indirectly. Our further computational analysis revealed enrichment of hypoxia response elements (HREs) within DE gene promoters, implying a role for Hif-1. Experimental validation revealed that efficient stabilisation of Hif-1α in response to oxidative stress or hypoxia required an oxidation-competent Stat3 and that depletion of Hif-1α suppressed the inducible expression of Kcnb1, a representative DE gene. Our data suggest that Stat3 and Hif-1α cooperate to regulate genes involved in immune functions and developmental processes in response to oxidative stress.
活性氧是真正的细胞内第二信使,通过尚未完全阐明的机制影响细胞代谢和衰老。线粒体产生超氧阴离子,然后被歧化为过氧化氢,后者继而氧化基于半胱氨酸的酶,如磷酸酶、过氧化物酶和氧化还原敏感的转录因子,以调节它们的活性。已经表明信号转导和转录激活因子 3(Stat3)参与过氧化物酶 II 的氧化接力,但 Stat3 氧化对靶基因表达及其生物学后果的影响仍有待确定。因此,我们创建了表达 WT-Stat3 或 Stat3 氧化还原不敏感突变体(Stat3-C3S)的小鼠胚胎成纤维细胞(MEFs)。Stat3-C3S 细胞在形态、增殖和对氧化应激的抵抗力方面与 WT-Stat3 细胞不同;在细胞因子刺激下,它们显示出 Stat3 酪氨酸磷酸化和 Socs3 表达升高,表明 Stat3-C3S 对氧化抑制不敏感。WT-Stat3 和 Stat3-C3S 细胞的全局基因表达比较分析显示,在基础条件和氧化应激下,基因表达存在差异(DE)。使用差异基因调控模式分析,我们鉴定出 199 个基因簇,分为 10 个不同的模式,这些模式选择性地对 Stat3 氧化有反应。GO 术语分析表明,下调基因富集于组织/器官发育和形态发生,而上调基因富集于细胞-细胞粘附、免疫反应和运输相关过程。尽管大多数 DE 基因启动子含有公认的 Stat3 诱导元件(SIEs),但我们的染色质免疫沉淀(ChIP)和 ChIP-seq 分析未在对照或氧化剂刺激的细胞中检测到这些位点的 Stat3 结合,表明氧化的 Stat3 间接调节这些基因。我们进一步的计算分析显示,DE 基因启动子中富含缺氧反应元件(HREs),暗示了 Hif-1 的作用。实验验证表明,氧化应激或缺氧下 Hif-1α 的有效稳定需要一个有氧化能力的 Stat3,并且 Hif-1α 的耗竭抑制了 DE 基因的代表性基因 Kcnb1 的诱导表达。我们的数据表明,Stat3 和 Hif-1α 合作调节参与免疫功能和发育过程的基因,以应对氧化应激。
