Iron-dependent vs. iron-independent cold-induced injury to cultured rat hepatocytes: a comparative study in physiological media and organ preservation solutions

We previously described the entity of cold-induced apoptosis to rat hepatocytes and characterized its major, iron-dependent pathway. However, after cold incubation in some solutions, e.g. cell culture medium, hepatocytes show an additional, yet uncharacterized component of cold-induced injury. We here assessed the effects of organ preservation solutions on both components of cold-induced injury and tried to further characterize the iron-independent component. None of the preservation solutions (University of Wisconsin, histidine-tryptophan-ketoglutarate, Euro-Collins, histidine-lactobionate, sodium-lactobionate-sucrose and Celsior solutions) provided significant protection against cold-induced cell injury (LDH release after 24-h cold incubation/3h rewarming >65% for all solutions); three solutions even enhanced cold-induced injury. However, when the predominant iron-dependent mechanism was eliminated by the addition of iron chelators, all preservation solutions yielded hepatocyte protection that was clearly superior to the one obtainable in cell culture medium or Krebs-Henseleit buffer with iron chelators (LDH release after 24-h cold incubation/3h rewarming 相似文献   

Heterologous ferredoxin reductase and flavodoxin protect Cos-7 cells from oxidative stress

Background

Ferredoxin-NADP(H) reductase (FNR) from Pisum sativum and Flavodoxin (Fld) from Anabaena PCC 7119 have been reported to protect a variety of cells and organisms from oxidative insults. In this work, these two proteins were expressed in mitochondria of Cos-7 cells and tested for their efficacy to protect these cells from oxidative stress in vitro.

Principal Findings

Cos-7/pFNR and Cos-7/pFld cell lines expressing FNR and Fld, respectively, showed a significantly higher resistance to 24 h exposure to 300–600 µM hydrogen peroxide measured by LDH retention, MTT reduction, malondialdehyde (MDA) levels and lipid peroxide (LPO; FOX assay) levels. However, FNR and Fld did not exhibit any protection at shorter incubation times (2 h and 4 h) to 4 mM hydrogen peroxide or to a 48 h exposure to 300 µM methyl viologen. We found enhanced methyl viologen damage exerted by FNR that may be due to depletion of NADPH pools through NADPH-MV diaphorase activity as previously observed for other overexpressed enzymes.

Significance

The results presented are a first report of antioxidant function of these heterologous enzymes of vegetal and cyanobacterial origin in mammalian cells.     

Vitamin C modulation of H2O2-induced damage and iron homeostasis in human cells

Vitamin C (ascorbic acid, AA) is an important antioxidant in human plasma. It is clear, however, that AA has other important, nonantioxidant roles in cells. Of particular interest is its involvement in iron metabolism, since AA enhances dietary iron absorption, increases the activity of Fe(2+)-dependent cellular enzymes, promotes Fenton reactions in vitro, and was reported to have deleterious effects in individuals with iron overload. Nevertheless, the ability of AA to modulate iron metabolism and enhance iron-dependent damage in cells, tissues, and organisms has not been fully elucidated. Here we investigated the effect of AA on iron-mediated oxidative stress in normal human fibroblasts. Incubation with physiologically relevant concentrations of AA was not harmful but sensitised cells toward H(2)O(2)-induced, iron-dependent DNA strand breakage and cell death. We also report that AA increased the levels of intracellular catalytic iron and concomitantly modulated the expression of two well-established iron-regulated genes, ferritin and transferrin receptor. In summary, we present evidence of a novel, nonantioxidant role of AA in human cells, where it increases iron availability and enhances ROS-mediated, iron-dependent damage. We suggest that AA may exacerbate the deleterious effects of metals in vivo and promote normal tissue injury in situations associated with elevated ROS production.     

Hypothermic preconditioning of endothelial cells attenuates cold-induced injury by a ferritin-dependent process

Hypothermia for myocardial protection or storage of vascular grafts may damage the endothelium and impair vascular function upon reperfusion/rewarming. Catalytic iron pools and oxidative stress are important mediators of cold-induced endothelial injury. Because endothelial cells are highly adaptive, we hypothesized that hypothermic preconditioning (HPC) protects cells at 0°C by a heme oxygenase-1 (HO-1) and ferritin-dependent mechanism. Storage of human coronary artery endothelial cells at 0°C caused the release of lactate dehydrogenase, increases in bleomycin-detectible iron (BDI), and increases in the ratio of oxidized/reduced glutathione, signifying oxidative stress. Hypoxia increased injury at 0°C but did not increase BDI or oxidative stress further. HPC at 25°C for 15–72 h attenuated these changes by an amount achievable by pretreating cells with 10–20 μM deferoxamine, an iron chelator, and protected cell viability. Treating cells with hemin chloride at 37°C transiently increased intracellular heme, HO-1, BDI, and ferritin. Elevated heme/iron sensitized cells to 0°C but ferritin was protective. HPC increased iron maximally after 2 h at 25°C and ferritin levels peaked after 15 h. HO-1 was not induced. When HPC-mediated increases in ferritin were blocked by deferoxamine, protection at 0°C was diminished. We conclude that HPC-mediated endothelial protection from hypothermic injury is an iron- and ferritin-dependent process.     

Restored vulnerability of cultured endothelial cells to high glucose by iron replenishment.

High glucose (HG) concentrations are toxic to various cells in vivo, but cells become insensitive to HG toxicity when they are subcultured serially in vitro. Oxidative stress is involved in HG toxicity, and metal ions, especially iron, mediate some oxidative stress. To investigate mechanisms involved in the insensitiveness of cultured cells to HG toxicity, we focused on the level of intracellular iron. Freshly prepared human umbilical vein endothelial cells contained a substantial amount of iron, whereas its level decreased rapidly during the course of culture (to less than 10%). The iron content was restored by incubation of the cells with Fe(III)/8-hydroxyquinoline, and the iron-supplemented cells were more susceptible to both oxidant- and HG-induced injury. Under the HG conditions, the iron-loaded cells were subjected to higher levels of oxidative stress. The enhanced HG toxicity by iron was attenuated by the treatment with several antioxidants including catalase, ascorbic acid, and pyruvate. These data suggested that the insensitiveness of subcultured cells to HG toxicity is, at least in part, due to rapid and dramatic loss of intracellular iron. Supplementation with iron is useful to restore the vulnerability of cultured cells to HG that is normally observed in in vivo situations.     

Ferroptosis: the potential value target in atherosclerosis

In advanced atherosclerosis (AS), defective function-induced cell death leads to the formation of the characteristic necrotic core and vulnerable plaque. The forms and mechanisms of cell death in AS have recently been elucidated. Among them, ferroptosis, an iron-dependent form of necrosis that is characterized by oxidative damage to phospholipids, promotes AS by accelerating endothelial dysfunction in lipid peroxidation. Moreover, disordered intracellular iron causes damage to macrophages, vascular smooth muscle cells (VSMCs), vascular endothelial cells (VECs), and affects many risk factors or pathologic processes of AS such as disturbances in lipid peroxidation, oxidative stress, inflammation, and dyslipidemia. However, the mechanisms through which ferroptosis initiates the development and progression of AS have not been established. This review explains the possible correlations between AS and ferroptosis, and provides a reliable theoretical basis for future studies on its mechanism.Subject terms: Cell death, Cardiovascular diseases     

Iron homeostasis and oxidative stress: An intimate relationship

Iron is a transition metal and essential constituent of almost all living cells and organisms. As component of various metalloproteins it is involved in critical biochemical processes such as transport of oxygen in tissues, electron transfer reactions during respiration in mitochondria, synthesis and repair of DNA, metabolism of xenobiotics, etc. However, when present in excess within cells and tissues, iron disrupts redox homeostasis and catalyzes the propagation of reactive oxygen species (ROS), leading to oxidative stress. ROS are critical for physiological signaling pathways, but oxidative stress is associated with tissue injury and disease. At the cellular level, oxidative stress may lead to ferroptosis, an iron-dependent form of cell death. In this review, we focus on the intimate relationship between iron metabolism and oxidative stress in health and disease. We discuss aspects of redox- and iron-mediated signaling, toxicity, ferroptotic cell death, homeostatic pathways and pathophysiological implications.     

NMN recruits GSH to enhance GPX4-mediated ferroptosis defense in UV irradiation induced skin injury

Oxidative stress and lipid peroxidation are major causes of skin injury induced by ultraviolet (UV) irradiation. Ferroptosis is a form of regulated necrosis driven by iron-dependent peroxidation of phospholipids and contributes to kinds of tissue injuries. However, it remains unclear whether the accumulation of lipid peroxides in UV irradiation-induced skin injury could lead to ferroptosis. We generated UV irradiation-induced skin injury mice model to examine the accumulation of the lipid peroxides and iron. Lipid peroxides 4-HNE, the oxidative enzyme COX2, the oxidative DNA damage biomarker 8-OHdG, and the iron level were increased in UV irradiation-induced skin. The accumulation of iron and lipid peroxidation was also observed in UVB-irradiated epidermal keratinocytes without actual ongoing ferroptotic cell death. Ferroptosis was triggered in UV-irradiated keratinocytes stimulated with ferric ammonium citrate (FAC) to mimic the iron overload. Although GPX4 protected UVB-injured keratinocytes against ferroptotic cell death resulted from dysregulation of iron metabolism and the subsequent increase of lipid ROS, keratinocytes enduring constant UVB treatment were markedly sensitized to ferroptosis. Nicotinamide mononucleotide (NMN) which is a direct and potent NAD⁺ precursor supplement, rescued the imbalanced NAD⁺/NADH ratio, recruited the production of GSH and promoted resistance to lipid peroxidation in a GPX4-dependent manner. Taken together, our data suggest that NMN recruits GSH to enhance GPX4-mediated ferroptosis defense in UV irradiation-induced skin injury and inhibits oxidative skin damage. NMN or ferroptosis inhibitor might become promising therapeutic approaches for treating oxidative stress-induced skin diseases or disorders.     

Oxidative injury to isolated rat pancreatic acinar cells vs. isolated zymogen granules

This study compares the susceptibility of pancreatic acinar cells and zymogen granules against oxidative injury and analyzes the mechanisms involved. Zymogen granules and acinar cells, isolated from rat pancreas, were exposed to a reaction mixture containing xanthine oxidase, hypoxanthine, and chelated iron. Cell function and viability were assessed by various techniques. Trypsin activation was quantified by an Elisa for trypsinogen activating peptide. Integrity of granules was determined by release of amylase. The reaction mixture rapidly generated radicals as assessed by deoxyribose and luminol assays. This oxidative stress caused lysis of granules in a matter of minutes but significant cell death only after some hours. Nevertheless, radicals initiated intracellular vacuolization, morphological damage to zymogen granules and mitochondria, increase in trypsinogen activating peptide, and decrease in ATP already after 5–30 min. Supramaximal caerulein concentrations also caused rapid trypsin activation. Addition of cells but not of granules reduced deoxyribose oxidation, suggesting that intact cells act as scavengers. Caerulein pretreatment only slightly increased the susceptibility of cells but markedly that of granules. In conclusion, isolated zymogen granules are markedly more susceptible to oxidative injury than intact acinar cells, in particular, in early stages of caerulein pancreatitis. The results show that oxidative stress causes a rapid trypsin activation that may contribute to cell damage by triggering autodigestion. Zymogen granules and mitochondria appear to be important targets of oxidative damage inside acinar cells. The series of intracellular events initiated by oxidative stress was similar to changes seen in early stages of pancreatitis.     

Fatty acid-mediated intracellular iron translocation: a synergistic mechanism of oxidative injury

Fatty acid has been reported to be associated with cardiovascular diseases and cancer, but the possible mechanism remains unclear. Here, we reported a novel mechanism for the permissive role of fatty acid on iron intracellular translocation and subsequent oxidative injury. In vitro study from endothelial cells showed that iron alone had little effect, whereas in combination with PA (palmitic acid), iron-mediated toxicity was markedly potentiated, as reflected in mitochondrial dysfunction, cell death, apoptosis, and DNA mutation. We also showed that PA not only facilitated iron translocation into cells through a transferrin-receptor (TfR)-independent mechanism, but also translocated iron into mitochondria; the subsequent intracellular iron overload resulted in reactive oxygen species (ROS) overgeneration and lipid oxidation. Further investigation revealed that PA-facilitated iron translocation is due to Fe/PA-mediated extracellular oxidative stress and the subsequent membrane damage with increased membrane permeability. Fe/PA-mediated toxic effects were reduced in rho0 cells lacking mitochondrial DNA or by antioxidant enzyme SOD, especially mitochondrially localized MnSOD, suggesting a permissive role of PA for iron deposition on the vascular wall and its subsequent toxicity via mitochondrial oxidative stress. This observation was confirmed in vivo in mice, wherein higher vascular iron deposition and accompanying superoxide release were observed in the presence of a high-fat diet with iron administration.     

Oxidation-induced ferritin turnover in microglial cells: role of proteasome

Highly oxidized protein aggregates accumulating in the brain during neurodegenerative diseases are often surrounded by microglia. Most of the microglial cells surrounding these plaques are activated and release a high amount of oxidizing species. In order to develop their toxic effects numerous oxidizing species need iron. To prevent this iron-dependent oxidation an iron-sequestering apparatus exists, including the major iron storage protein ferritin. Microglial cells damage their own protein pool during activation and it is still unknown whether microglial cells are able to maintain their iron-sequestering function during oxidative stress. Therefore, we explored the microglial cell line RAW to test the maintenance of ferritin under oxidizing conditions. Our investigations revealed a half-life of both ferritin chains of 3-3.5 h and a reduced half-life due to oxidation. This was due to the removal of oxidized ferritin by the proteasomal system. Ferritin de novo synthesis was also severely affected by oxidation. This results in a decreased ferritin pool due to acute oxidative stress. These data let us conclude that microglial cells do not increase their ferritin amount after oxidative stress and an increase in the iron storage capacity in these cells after treatment might be achieved only by a high iron saturation of the existing ferritin molecules.     

The lipase LipA (PA2862) but not LipC (PA4813) from Pseudomonas aeruginosa influences regulation of pyoverdine production and expression of the sigma factor PvdS

A key element in iron-dependent regulation of iron metabolism and virulence-related functions for Pseudomonas aeruginosa is the sigma factor PvdS. PvdS expression itself is also influenced by iron-independent stimuli. We show that pyoverdine production and pvdS expression depend on one of the two lipases of P. aeruginosa.     

Iron, oxidative stress and human health

The amount of iron within the cell is carefully regulated in order to provide an adequate level of the micronutrient while preventing its accumulation to toxic levels. Iron excess is believed to generate oxidative stress, understood as an increase in the steady state concentration of oxygen radical intermediates. The main aspects of cellular metabolism of iron, with special emphasis on the role of iron with respect to oxidative damage to lipid membranes, are briefly reviewed here. Both in vitro and in vivo models are examined. Finally, a discussion of iron overload and its impact on human health is included. Overall, further studies are required to assess more effective means to limit iron-dependent damage, by minimizing the formation and release of free radicals in tissues when the cellular iron steady state concentration is increased either as a consequence of disease or by therapeutic iron supplementation.     

复方中药制剂在寒冷诱导机体损伤中作用及其机制

目的:研究寒冷所诱导的机体损伤作用,明确寒冷引发机体损伤的部分机制以及预防性药物对机体处于寒冷环境中的保护作用。方法:通过低温试验、ATP检测、电镜观察等确定寒冷对机体造成的损伤;通过总抗氧化能力、CAT含量、谷胱甘肽过氧化物酶含量、SOD水平、MDA水平等的检测确定氧化应激在寒冷暴露对机体损伤中的作用及机制;并确证复方中药制剂在寒冷损伤氧化应激状态下对机体的保护作用。结果:1.急性-15±1℃寒冷环境暴露可引起机体内肝脏组织能量代谢障碍,ATP生成减少,肝细胞线粒体损伤,溶酶体增多等机体损伤的现象;2.寒冷应激可导致机体的总抗氧化能力、CAT显著减少,而氧化应激终产物之一的丙二醛(malondialdehyde,MDA)显著增多(说明肝脏组织出现明显的氧化应激过程),并且出现抗氧化能力下降。3.预先给予药物干预后,机体抗氧化能力显著增加。结论:1.寒冷可以诱导机体肝脏明显损伤。2.氧化应激是寒冷诱导机体损伤的关键机制之一。3.复方中药制剂可以增加机体在寒冷应激条件下的抗氧化能力,从而产生保护作用。     

Impact of iron and vitamin C-containing supplements on preterm human milk: in vitro

Stress due to reactive oxygen species (ROS) may lead to neonatal diseases, such as necrotizing enterocolitis and respiratory distress. Enteral supplements for premature infants (PREM) added to human milk (HM) to increase nutrient content may induce lipid oxidation due to free radical formation via Fenton chemistry. We hypothesized that ferrous iron and vitamin C-containing supplements added to HM in vitro cause oxidation of milk fats, affect intracellular redox balance, and induce DNA damage. Lipid peroxidation in HM was measured by FOX-2 and TBARS assays; fatty acid composition of supplemented HM was measured by gas chromatography. Two cell culture bioassays were used for assessing either intracellular oxidative stress or DNA damage: the former involved Caco-2BBe cells, a secondary differentiated cell line, and the latter utilized FHS-74 Int cells, a primary fetal small intestinal culture. Lipid oxidation products of HM increased after the addition of iron alone, iron and vitamin C, or iron and a vitamin C-containing supplement (Trivisol, TVS). A reduced content of mono and polyunsaturated fatty acids in HM was also observed. Iron, not iron+vitamin C, but iron+TVS induced significant intracellular oxidative stress in FHS-74 Int cells. In contrast, iron, either alone or in combination with TVS or vitamin C, increased DNA damage in Caco-2BBE cells. Iron supplementation may increase oxidative stress in PREM infants and should be given separately from vitamin C-containing supplements.     

Green tea polyphenol epigallocatechin-3-gallate protects HepG2 cells against CYP2E1-dependent toxicity

Chronic ethanol consumption causes oxidative damage in the liver, and induction of cytochrome P450 2E1 (CYP2E1) is one pathway involved in oxidative stress produced by ethanol. The hepatic accumulation of iron and polyunsaturated fatty acids significantly contributes to ethanol hepatotoxicity in the intragastric infusion model of ethanol treatment. The objective of this study was to analyze the effect of the green tea flavanol epigallocatechin-3-gallate (EGCG), which has been shown to prevent alcohol-induced liver damage, on CYP2E1-mediated toxicity in HepG2 cells overexpressing CYP2E1 (E47 cells). Treatment of E47 cells with arachidonic acid plus iron (AA + Fe) was previously reported to produce synergistic toxicity in E47 cells by a mechanism dependent on CYP2E1 activity and involving oxidative stress and lipid peroxidation. EGCG protected E47 cells against toxicity and loss of viability induced by AA+Fe; EGCG had no effect on CYP2E1 activity. Prevention of this toxicity was associated with a reduction in oxidative damage as reflected by decreased generation of reactive oxygen species, a decrease in lipid peroxidation, and maintenance of intracellular glutathione in cells challenged by AA+Fe in the presence of EGCG. AA+Fe treatment caused a decline in the mitochondrial membrane potential, which was also blocked by EGCG. In conclusion, EGCG exerts a protective action on CYP2E1-dependent oxidative stress and toxicity that may contribute to preventing alcohol-induced liver injury, and may be useful in preventing toxicity by various hepatotoxins activated by CYP2E1 to reactive intermediates.     

Low Glutathione and High Iron Govern the Susceptibility of Oligodendroglial Precursors to Oxidative Stress

Abstract: We have previously shown, using qualitative approaches, that oligodendroglial precursors are more readily damaged by free radicals than are astrocytes. In the present investigation we quantified the oxidative stress experienced by the cells using oxidation of dichlorofluorescin diacetate to dichlorofluorescein as a measure of oxidative stress; furthermore, we have delineated the physiological bases of the difference in susceptibility to oxidative stress found between oligodendroglial precursors and astrocytes. We demonstrate that (a) oligodendroglial precursors under normal culture conditions are under six times as much oxidative stress as astrocytes, (b) oxidative stress experienced by oligodendroglial precursors increases sixfold when exposed to 140 mW/m² of blue light, whereas astrocytic oxidative stress only doubles, (c) astrocytes have a three times higher concentration of GSH than oligodendroglial precursors, (d) oligodendroglial precursors have >20 times higher iron content than do astrocytes, and (e) oxidative stress in oligodendroglial precursors can be prevented either by chelating intracellular free iron or by raising intracellular GSH levels to astrocytic values. We conclude that GSH plays a central role in preventing free radical-mediated damage in glia.     

Lipocalin 2 attenuates iron-related oxidative stress and prolongs the survival of ovarian clear cell carcinoma cells by up-regulating the CD44 variant

Ovarian clear cell carcinoma (CCC) arises from ovarian endometriosis. Intra-cystic fluid contains abundant amounts of free iron, which causes persistent oxidative stress, a factor that has been suggested to induce malignant transformation. However, the mechanisms linking oxidative stress and carcinogenesis in CCC currently remain unclear. Lipocalin 2 (LCN2), a multifunctional secretory protein, functions as an iron transporter as well as an antioxidant. Therefore, we herein examined the roles of LCN2 in the regulation of intracellular iron concentrations, oxidative stress, DNA damage, and antioxidative functions using LCN2-overexpressing (ES2), and LCN2-silenced (RMG-1) CCC cell lines. The results of calcein staining indicated that the up-regulated expression of LCN2 correlated with increases in intracellular iron concentrations. However, a DCFH-DA assay and 8OHdG staining revealed that LCN2 reduced intracellular levels of reactive oxygen species and DNA damage. Furthermore, the expression of LCN2 suppressed hydrogen peroxide-induced apoptosis and prolonged cell survival, suggesting an antioxidative role for LCN2. The expression of mRNAs and proteins for various oxidative stress-catalyzing enzymes, such as heme oxygenase (HO), superoxide dismutase (SOD), and glutathione peroxidase, was not affected by LCN2, whereas the intracellular concentration of the potent antioxidant, glutathione (GSH), was increased by LCN2. Furthermore, the expression of xCT, a cystine transporter protein, and CD44 variant 8-10 (CD44v), a stem cell marker, was up-regulated by LCN2. Although LCN2 increased intracellular iron concentrations, LCN2-induced GSH may catalyze and override oxidative stress via CD44v and xCT, and subsequently enhance the survival of CCC cells in oxidative stress-rich endometriosis.     

Hypothermia causes a marked injury to rat proximal tubular cells that is aggravated by all currently used preservation solutions

Cold preservation results in cell death via iron-dependent formation of reactive oxygen species, leading to apoptosis during rewarming. We aimed to study cold-induced damage (i.e., injury as a consequence of hypothermia itself and not cold ischemia) in proximal tubular cells (PTC) in various preservation solutions presently applied and to clarify the role of mitochondria in this injury. Primary cultures of rat PTC were incubated at 4 degrees C for 24 h in culture medium, UW, Euro-Collins or HTK solution with and without the iron chelator desferal and rewarmed at 37 degrees C in culture medium. Cell damage, morphology, and apoptosis were studied and mitochondrial membrane potential was assessed by fluorescence microscopy. Cold incubation of PTC in culture medium followed by rewarming caused marked cell damage compared to warm incubation alone (LDH release 39+/-10% vs. 1.6+/-0.3%). Cold-induced damage was aggravated in all preservation solutions (LDH release 85+/-2% for UW; similar in Euro-Collins and HTK). After rewarming, cells showed features suggestive for apoptosis. Desferal prevented cell injury in all solutions (e.g., 8+/-2% for UW). Mitochondrial membrane potential was lost during rewarming and this loss could also be inhibited by desferal. Trifluoperazine, which is known to inhibit mitochondrial permeability transition (MPT), was able to prevent cold-induced injury (LDH 85+/-5% vs. 12+/-2%). We conclude that cold-induced injury occurs in PTC and is aggravated by UW, Euro-Collins, and HTK solution. Iron-dependent MPT is suggested to play a role in this damage. Strategies to prevent cold-induced injury should aim at reducing the availability of "free" iron.