低氧诱导因子-1的转录活性调控及其信号传导

低氧诱导因子-1(hypoxia-inducible factor-1,HIF-1)是氧平衡调控相关的转录因子.依赖HIF-1的基因表达调控系统广泛影响葡萄糖代谢、细胞增殖、凋亡和血管发生,与机体低氧适应、胚胎发育、各种缺血性疾病及肿瘤相关.HIF-1自身活性调节是低氧应答基因表达调控的中心环节.调控主要发生在源于Ras的两条信号途径：Ras/Raf/MEK介导的HIF-1反式激活功能调控,PI(3)K/Akt依赖的HIF-1alpha蛋白稳定性调控.这两个信号传导途径分别独立又协调地调控着HIF-1的转录活性.     

自噬发生中的ROS调节机制

活性氧是细胞代谢中产生的有很强反应活性的分子,易将邻近分子氧化,并参与细胞内多种信号转导途径,对相关生理过程进行调控．自噬是真核细胞通过溶酶体机制对自身组分进行降解再利用的过程,在细胞应激及疾病发生等过程中发挥重要作用．本文对活性氧和自噬相关调节进行分类介绍,根据新近研究进展,从活性氧参与的自噬性死亡、自噬性存活以及线粒体自噬3方面探讨了相关信号转导机制,对活性氧作为信号分子参与的自噬调控途径做一总结和介绍．     

ROS 的信息分子功能

ROS在机体内主要由NADPH氧化酶系统产生,ROS作为信息分子对细胞功能如细胞生长,转化,凋亡,转录和衰老的调节及相关信息传递等方面的研究,在90年代后期有了明显的进展。并从细胞内环境的氧化还原状态变化和蛋白质的氧化修饰角度初步探讨了ROS参与信息传递的机理。     

The Role of Reactive Oxygen Species in Mitochondrial Permeability Transition

We have provided evidence that mitochondrial membrane permeability transition induced by inorganic phosphate, uncouplers or prooxidants such as t-butyl hydroperoxide and diamide is caused by a Ca²⁺-stimulated production of reactive oxygen species (ROS) by the respiratory chain, at the level of the coenzyme Q. The ROS attack to membrane protein thiols produces cross-linkage reactions, that may open membrane pores upon Ca²⁺ binding. Studies with submitochondrial particles have demonstrated that the binding of Ca²⁺ to these particles (possibly to cardiolipin) induces lipid lateral phase separation detected by electron paramagnetic resonance experiments exploying stearic acids spin labels. This condition leads to a disorganization of respiratory chain components, favoring ROS production and consequent protein and lipid oxidation.     

Reactive Oxygen Species Regulate a Slingshot-Cofilin Activation Pathway

Cellular stimuli generate reactive oxygen species (ROS) via the local action of NADPH oxidases (Nox) to modulate cytoskeletal organization and cell migration through unknown mechanisms. Cofilin is a major regulator of cellular actin dynamics whose activity is controlled by phosphorylation/dephosphorylation at Ser3. Here we show that Slingshot-1L (SSH-1L), a selective cofilin regulatory phosphatase, is involved in H₂O₂-induced cofilin dephosphorylation and activation. SSH-1L is activated by its release from a regulatory complex with 14-3-3ζ protein through the redox-mediated oxidation of 14-3-3ζ by H₂O₂. The ROS-dependent activation of the SSH-1L-cofilin pathway stimulates the SSH-1L–dependent formation of cofilin-actin rods in cofilin-GFP–expressing HeLa cells. Similarly, the formation of endogenous ROS stimulated by angiotensin II (AngII) also activates the SSH-1L-cofilin pathway via oxidation of 14-3-3ζ to increase AngII-induced membrane ruffling and cell motility. These results suggest that the formation of ROS by NADPH oxidases engages a SSH-1L-cofilin pathway to regulate cytoskeletal organization and cell migration.     

Reactive Oxygen Species as Essential Components of Ambient Air

In this review evidence for the presence of the anion radical in atmospheric air is considered, and the biological activity of superoxide and negative air ions is compared. Various aspects of the biological effect of superoxide and other reactive oxygen species contained in air at the cell, tissue, and organism levels are discussed. The results of the therapeutic use of exogenous gaseous superoxide and low doses of H₂O₂ for the treatment of bronchial asthma, pain, and Parkinson's disease are reported. A hypothesis on the mechanism of physiological action of exogenous reactive oxygen species is discussed.     

Role of Focal Adhesion Tyrosine Kinases in GPVI-Dependent Platelet Activation and Reactive Oxygen Species Formation

Background

We have previously shown the presence of a TRAF4/p47^phox/Hic5/Pyk2 complex associated with the platelet collagen receptor, GPVI, consistent with a potential role of this complex in GPVI-dependent ROS formation. In other cell systems, NOX-dependent ROS formation is facilitated by Pyk2, which along with its closely related homologue FAK are known to be activated and phosphorylated downstream of ligand binding to GPVI.

Aims

To evaluate the relative roles of Pyk2 and FAK in GPVI-dependent ROS formation and to determine their location within the GPVI signaling pathway.

Methods and Results

Human and mouse washed platelets (from WT or Pyk2 KO mice) were pre-treated with pharmacological inhibitors targeting FAK or Pyk2 (PF-228 and Tyrphostin A9, respectively) and stimulated with the GPVI-specific agonist, CRP. FAK, but not Pyk2, was found to be essential for GPVI-dependent ROS production and aggregation. Subsequent human platelet studies with PF-228 confirmed FAK is essential for GPVI-mediated phosphatidylserine exposure, α-granule secretion (P-selectin (CD62P) surface expression) and integrin α_IIbβ₃ activation. To determine the precise location of FAK within the GPVI pathway, we analyzed the effect of PF-228 inhibition in CRP-stimulated platelets in conjunction with immunoprecipitation and pulldown analysis to show that FAK is downstream of Lyn, Spleen tyrosine kinase (Syk), PI3-K and Bruton''s tyrosine kinase (Btk) and upstream of Rac1, PLCγ2, Ca²⁺ release, PKC, Hic-5, NOX1 and α_IIbβ₃ activation.

Conclusion

Overall, these data suggest a novel role for FAK in GPVI-dependent ROS formation and platelet activation and elucidate a proximal signaling role for FAK within the GPVI pathway.     

The Role of Reactive Oxygen Species in Inflammatory Disease: Evaluation of Methodology

The production of reactive oxidants has been implicated in the pathology of a number of inflammatory conditions, including inflamed arthritic joints. Many assays for the detection of these oxidants in diseased states have been described, but there are a number of potential pitfalls in both experimental design and the interpretation of results obtained with these techniques. Here, we describe a number of commonly used assays to detect the production of reactive oxidants and critically discuss their usefulness and limitations. We focus on the role of xanthine oxidase in reactive oxidant production in inflammatory disease.     

活性氧在创伤愈合中作用的研究

：创伤愈合是一个复杂的生物学过程,包括出血与凝血、炎症渗出、血管和肉芽组织的形成、再上皮化、纤维化和瘢痕改建等,在这一系列的生物学活动过程中都需要能量支持;高等动物使用氧气作为终端氧化剂,通过对碳水化合物的氧化作用为愈合过程中的各种生命活动提供能量,但该过程却可以产生大量的活性氧,这些活性氧在创伤愈合的过程中扮演着重要的角色,在低浓度情况下可以促进伤口的愈合,而在高浓度时会抑制伤口愈合,而活性量浓度的过高过低都会影响创口的正常愈合过程。     

低氧诱导因子-1：细胞适应氧供应改变的关键蛋白

2019年诺贝尔生理学或医学奖授予威廉·凯林(William Kaelin Jr)、彼得·拉特克里夫爵士(Sir Peter Ratcliffe)和格雷格·赛门扎(Gregg Semenza),以表彰他们在细胞感知和适应缺氧机制上做出的重要贡献.低氧诱导因子-1 (hypoxiainducible factor-1,HIF-1)在细胞适应氧供应改变中起关键作用,可作为转录因子改变基因表达,通过提高机体携氧能力、增加血液供应、改变代谢方式等途径来适应缺氧环境.而HIF-1的功能也受到各种机制调控:泛素化-蛋白酶体途径降解和转录因子活性抑制. HIF-1与抑癌蛋白(protein von Hippel-Lindau,pVHL)、脯氨酸羟化酶(proline hydroxylase,PHD)、HIF抑制因子(factor inhibiting HIF,FIH)等构成了严密有序的调节网络.本文总结了3位诺贝尔奖获得者的研究成果,并结合最新的研究进展,系统阐述了HIF-1表达量调节机制和HIF-1介导的细胞适应缺氧环境机制.     

活性氧的信号分子作用

活性氧 (ＲＯＳ)包括过氧化氢 (Ｈ2 Ｏ2 )、超氧阴离子 (Ｏ·-2 )、羟自由基 (·ＯＨ)等。过量的活性氧可引起细胞大分子的氧化损伤。另外 ,微量活性氧在某些生理现象的调控中也发挥重要的作用 ,特别是在细胞内信号转导方面。在配体与受体的相互作用及激动剂处理细胞的过程中 ,发现酶及转录因子的激活 ,基因的表达 ,细胞凋亡等过程的发生均与活性氧有一定关系。因此 ,活性氧被认为是一种新的第二信使。1 .酶的激活酶的活化是信号转导过程中的重要环节。最近几年的研究表明 ,某些酶的活化与ＲＯＳ参与有密切关系。当血小板源生长因子(ＰＤＧ…     

Role of Auxin-Induced Reactive Oxygen Species in Root Gravitropism

We report our studies on root gravitropism indicating that reactive oxygen species (ROS) may function as a downstream component in auxin-mediated signal transduction. A transient increase in the intracellular concentration of ROS in the convex endodermis resulted from either gravistimulation or unilateral application of auxin to vertical roots. Root bending was also brought about by unilateral application of ROS to vertical roots pretreated with the auxin transport inhibitor N-1-naphthylphthalamic acid. Furthermore, the scavenging of ROS by antioxidants (N-acetylcysteine, ascorbic acid, and Trolox) inhibited root gravitropism. These results indicate that the generation of ROS plays a role in root gravitropism.     

植物乙烯生物合成过程中活性氧的作用

大量的研究结果表明,活性氧参与植物乙烯生物合成过程具有明显的普遍性,超氧阴离子自由基是参与乙烯生物合成过程的主要活性氧。近年来研究的焦点主要从乙烯生物合成的关键调控酶ACC合酶及ACC氧化酶的酶活性、酶动力学特性、酶蛋白空间结构、酶基因表达水平等方面来阐明活性氧调控植物乙烯生物合成的机制。最新的研究表明：植物在各种正常或应激的生长条件下首先诱导了活性氧产生水平的变化,活性氧在基因或蛋白质水平上影响ACC合酶和ACC氧化酶的活性水平,从而调节乙烯的生物合成。本文首次综述了活性氧影响植物乙烯生物合成过程的最新研究进展,并对活性氧在植物乙烯生物合成中具有诱导与抑制并存的“双重性”作用进行了探讨。     

The Role of Reactive Oxygen Species in the Antitumor Activity of Bleomycin

Calf thymus DNA was incubated with bleomycin and FeCl₃, in the presence of isolated rat liver microsomal NADH-cytochrome b₅ reductase, cytochrome b₅ and NADH which catalyze redox cycling of the bleomycin-Fe-complex. Furthermore, isolated rat liver nuclei were incubated with bleomycin, FeCl₃ and NADH, a system in which redox cycling of bleomycin-Fe leads to DNA damage. In both systems free bases from DNA were released. Furthermore, 8-hydroxy-guanine was also found in the supernatant. On the other hand, 8-hydroxy-deoxyguanosine was detected in DNA of cell nuclei indicating that hydroxylation of the guanine molecule occurred in intact DNA. The release of bases correlated with the release of malondialydehyde as well as with NADH and oxygen consumption. These results indicate that NADH-cytochrome b₅ reductase catalyzes redox cycling of the bleomycin-Fe-complex which results in the formation of reactive oxygen species which oxidize deoxyribose as well as bases of DNA. Both mechanisms may contribute to the cytotoxic and cytostatic effects of bleomycin observed in intact cells.     

Oxygen Sensitivity of Mitochondrial Reactive Oxygen Species Generation Depends on Metabolic Conditions

The mitochondrial generation of reactive oxygen species (ROS) plays a central role in many cell signaling pathways, but debate still surrounds its regulation by factors, such as substrate availability, [O₂] and metabolic state. Previously, we showed that in isolated mitochondria respiring on succinate, ROS generation was a hyperbolic function of [O₂]. In the current study, we used a wide variety of substrates and inhibitors to probe the O₂ sensitivity of mitochondrial ROS generation under different metabolic conditions. From such data, the apparent K_m for O₂ of putative ROS-generating sites within mitochondria was estimated as follows: 0.2, 0.9, 2.0, and 5.0 μm O₂ for the complex I flavin site, complex I electron backflow, complex III Q_O site, and electron transfer flavoprotein quinone oxidoreductase of β-oxidation, respectively. Differential effects of respiratory inhibitors on ROS generation were also observed at varying [O₂]. Based on these data, we hypothesize that at physiological [O₂], complex I is a significant source of ROS, whereas the electron transfer flavoprotein quinone oxidoreductase may only contribute to ROS generation at very high [O₂]. Furthermore, we suggest that previous discrepancies in the assignment of effects of inhibitors on ROS may be due to differences in experimental [O₂]. Finally, the data set (see supplemental material) may be useful in the mathematical modeling of mitochondrial metabolism.The production of reactive oxygen species (ROS)² by mitochondria has been implicated in numerous disease states, including but not limited to sepsis, solid state tumor survival, and diabetes (1). In addition, mitochondrial ROS (mtROS) play key roles in cell signaling (reviewed in Refs. 2 and 3). There exist within mitochondria several sites for the generation of ROS, with the most widely studied being complexes I and III of the electron transport chain (ETC). However, there is currently some debate regarding the relative contribution of these complexes to overall ROS production (4–9) and the factors that may alter this distribution. One such factor considered herein is [O₂]. Estimates of physiological [O₂] within tissues (i.e. interstitial [O₂]) range from 37 down to 6 μm at 5–40 μm away from a blood vessel (10). More recently, EPR oximetry has estimated tissue [O₂] to be in the 12–60 μm range (11). In addition, elegant studies with hepatocytes have shown that O₂ gradients exist within cells, such that an extracellular [O₂] of 6–10 μm yields an [O₂] of ∼5 μm close to the plasma membrane, dropping to 1–2 μm close to mitochondria deep within the cell (12). In cardiomyocytes, at an extracellular [O₂] of 29 μm, intracellular [O₂] varied in the range 6–25 μm (13). Clearly, different tissues consume O₂ at different rates, so these gradients can vary considerably between tissue and cell types.By definition, the generation of reactive oxygen species by any mechanism, is an O₂-dependent process. However, measurements in intact cells have indicated that mtROS generation increases at lower O₂ levels (1–5% O₂) (14). Proponents of an increase in mtROS in response to hypoxia suggest that under such conditions, reduction of the ETC results in increased leakage of electrons to O₂ at the Q_O site of complex III (14). Such a model posits that increased hypoxic ROS is a mitochondria-autonomous signaling mechanism (i.e. it is an inherent property of the mitochondrial ETC). Therefore, mtROS generation should increase in hypoxia regardless of the experimental system being studied, including isolated mitochondria. In contrast to this hypothesis, we and others have demonstrated that ROS generation by mitochondria is a positive function of [O₂] across a wide range of values (0.1–1000 μm O₂) (15–18), suggesting that signaling mechanisms external to mitochondria may be required to facilitate the increased hypoxic mtROS production observed in cells.One limitation of our previous work (15) was that only a single respiratory condition was studied, namely succinate as respiratory substrate (feeding electrons into complex II) plus rotenone to inhibit backflow of electrons through complex I (5, 7). The possibility exists that under different metabolic conditions, which may lead to differential redox states between the cytochromes in the ETC (19, 20), ROS generation may exhibit a different response to [O₂]. Thus, in the current study, we examined the response of mtROS generation to [O₂] under 11 different conditions, using a variety of respiratory substrates and inhibitors (for a thorough review of electron entry points to the ETC under various substrate/inhibitor combinations, see Ref. 21). Fig. 1 shows a schematic of the mitochondrial ETC, highlighting sites of electron entry resulting from various substrates, binding sites of inhibitors, and major sites of ROS generation. Fig. 2 shows the specific details of each experimental condition, indicating the predicted sites of ROS generation resulting from the use of each substrate/inhibitor combination. The legend to Fig. 2 provides an explanation of each condition.Open in a separate windowFIGURE 1.Mitochondrial pathways of electron flow resulting from the substrates and inhibitors used in this study. Substrates used were glutamate/malate (which generates NADH via the tricarboxylic acid cycle, feeding into complex I), succinate (which feeds electrons directly into complex II), and palmitoyl-carnitine (which feeds electrons into the ETC via acyl-CoA dehydrogenase as well as through the β-oxidation pathway). (For a more thorough explanation, refer to Ref. 21.) Inhibitors used were rotenone (which inhibits at the downstream Q binding site of complex I (9)), malonate (a competitive inhibitor of complex II (25, 26)), and antimycin A (a complex III inhibitor that prevents electron flow to the Q_I site of complex III, thus stabilizing QH^˙ at the Q_O site (6, 28)).Open in a separate windowFIGURE 2.Pathways of electron flow for the substrate/inhibitor combinations used in conditions A–L. Each panel includes the respective maximal respiration rate (VO_{2 max}; nmol of O₂/min/mg of protein) measured under each condition. A, glutamate/malate/malonate. Electrons enter through complex I, whereas electron entry at complex II is inhibited by malonate. ROS generation occurs at the FMN site of complex I as well as the Q_O site of complex III. B, glutamate/malate/malonate/rotenone. Electrons enter through complex I. Electron passage through complex I is inhibited by rotenone binding at the downstream Q site, resulting in maximal ROS production at the FMN site of complex I. ROS production at the Q_O site of complex III is prevented due to no electrons reaching the complex from either complexes I or II, both of which are inhibited. C, glutamate/malate/malonate/antimycin A. Electrons enter through complex I only, since complex II is blocked. Flow of electrons is inhibited by the complex III inhibitor antimycin A, resulting in ROS production at the Q_O site of complex III, as well as the FMN site of complex I. D, succinate. Electrons enter at complex II. ROS is generated by the flow of electrons though the Q_O site of complex III as well as the backflow of electrons through complex I. E, succinate/rotenone. Electrons enter at complex II, and ROS is generated at the Q_O site of complex III, because rotenone is present to inhibit backflow of electrons through complex I. F, succinate/antimycin A. Electrons enter through complex II. ROS is generated at both complex I via backflow and complex III Q_O, with an increased rate at the latter due to inhibition by antimycin A. G, succinate/rotenone/antimycin A. Electrons enter through complex II. Backflow of electrons through complex I is inhibited by rotenone, whereas ROS generation at complex III Q_O is augmented due to the presence of antimycin A. H, glutamate/malate/succinate. Electrons enter at both complexes I and II. ROS is generated from the complex I FMN site and the complex III Q_O site. J, glutamate/malate/succinate/antimycin A. Electrons enter at complexes I and II. ROS generation occurs at the complex I FMN and is augmented at the complex III Q_O site by antimycin A. K, palmitoyl-carnitine. Electrons enter at the ETFQOR. ROS is generated at the ETFQOR as well as complex I via backflow and at the complex III Q_O site. L, palmitoyl-carnitine/rotenone. Electron entry is at the ETFQOR. ROS is generated at the ETFQOR as well as at the complex III Q_O site, whereas ROS due to complex I backflow is blocked by rotenone. Glu, glutamate; Mal, malate; Suc, succinate; PC, palmitoyl-carnitine; Rot, rotenone; AntiA, antimycin A; Malon, malonate.The results of these studies indicated that although ROS generation under all experimental conditions exhibited the same overall response to [O₂] (i.e. hyperbolic, with decreased ROS at low [O₂]), the apparent K_m for O₂ varied widely between metabolic states.     

Diabetic Peripheral Neuropathy: Role of Reactive Oxygen and Nitrogen Species

The prevalence of diabetes has reached epidemic proportions. There are two forms of diabetes: type 1 diabetes mellitus is due to auto-immune-mediated destruction of pancreatic β-cells resulting in absolute insulin deficiency and type 2 diabetes mellitus is due to reduced insulin secretion and or insulin resistance. Both forms of diabetes are characterized by chronic hyperglycemia, leading to the development of diabetic peripheral neuropathy (DPN) and microvascular pathology. DPN is characterized by enhanced or reduced thermal, chemical, and mechanical pain sensitivities. In the long-term, DPN results in peripheral nerve damage and accounts for a substantial number of non-traumatic lower-limb amputations. This review will address the mechanisms, especially the role of reactive oxygen and nitrogen species in the development and progression of DPN.     

缺氧诱导因子-1降解的调控

缺氧是引起细胞损伤的重要原因,而缺氧诱导因子-1(hypoxia-inducible factor,HIF-1)是细胞对氧浓度改变的一系列自适应反应中重要的调节因子,也在肿瘤的发生和组织缺血中起到重要的作用。林希病肿瘤因子(product of von Hippel-lindau disease,pVHL)和缺氧诱导因子抑制因子(factor inhibiting hypoxia-inducible factor-1,FIH-1)是被公认的缺氧诱导因子诱导转录的抑制因子,与HIF-1有着复杂的相互作用,并调控其降解。研究它们的相互作用将为肿瘤及缺血性疾病的治疗提供一条崭新的途径。     

Reactive Oxygen Species: Beyond Their Reactive Behavior

Cellular homeostasis plays a critical role in how an organism will develop and age. Disruption of this fragile equilibrium is often associated with health degradation and ultimately, death. Reactive oxygen species (ROS) have been closely associated with health decline and neurological disorders, such as Alzheimer’s disease or Parkinson’s disease. ROS were first identified as by-products of the cellular activity, mainly mitochondrial respiration, and their high reactivity is linked to a disruption of macromolecules such as proteins, lipids and DNA. More recent research suggests more complex function of ROS, reaching far beyond the cellular dysfunction. ROS are active actors in most of the signaling cascades involved in cell development, proliferation and survival, constituting important second messengers. In the brain, their impact on neurons and astrocytes has been associated with synaptic plasticity and neuron survival. This review provides an overview of ROS function in cell signaling in the context of aging and degeneration in the brain and guarding the fragile balance between health and disease.

     

The Molecular Mechanism Underlying Morphine-Induced Akt Activation: Roles of Protein Phosphatases and Reactive Oxygen Species

Although Akt is reported to play a role in morphine’s cardioprotection, little is known about the mechanism underlying morphine-induced Akt activation. This study aimed to define the molecular mechanism underlying morphine-induced Akt activation and to determine if the mechanism contributes to the protective effect of morphine on ischemia/reperfusion injury. In cardiac H9c2 cells, morphine increased Akt phosphorylation at Ser⁴⁷³, indicating that morphine upregulates Akt activity. Phosphatase and tensin homolog deleted on chromosome 10 (PTEN), a major regulator of the phosphatidylinositol 3-kinase (PI3K)/Akt signaling, was not involved in the action of morphine on Akt activity. Morphine decreased the activity of PP2A, a major protein Ser/Thr phosphatase, and inhibition of PP2A with okadaic acid (OA) mimicked the effect of morphine on Akt activity. The effects of morphine on PP2A and Akt activities were inhibited by the reactive oxygen species (ROS) scavenger N-(2-mercaptopropionyl)glycine (MPG) and the mitochondrial K_ATP channel closer 5-hydroxydecanoate (5HD). In support, morphine could produce ROS and this was reversed by 5HD. Finally, the cardioprotective effect of morphine on ischemia–reperfusion injury was mimicked by OA but was suppressed by 5HD or MPG, indicating that protein phosphatases and ROS are involved in morphine’s protection. In conclusion, morphine upregulates Akt activity by inactivating protein Ser/Thr phosphatases via ROS, which may contribute to the cardioprotective effect of morphine.