Partial conservation of functions between eukaryotic frataxin and the Escherichia coli frataxin homolog CyaY

Frataxin is a mitochondrial protein structurally conserved from bacteria to humans. Eukaryotic frataxins are known to be involved in the maintenance of mitochondrial iron balance via roles in iron delivery and iron detoxification. The prokaryotic frataxin homolog, CyaY, has been shown to bind and donate iron for the assembly of [2Fe-2S] clusters in vitro. However, in contrast to the severe phenotypes associated with the partial or complete loss of frataxin in humans and other eukaryotes, deletion of the cyaY gene does not cause any obvious alteration of iron balance in bacterial cells, an effect that probably reflects functional redundancy between CyaY and other bacterial proteins. To study CyaY function in a nonredundant setting, we have expressed a mitochondria-targeted form of CyaY in a Saccharomyces cerevisiae strain depleted of the endogenous yeast frataxin protein (yfh1Delta). We show that in this strain CyaY complements to a large extent the loss of iron-sulfur cluster enzyme activities and heme synthesis, and thereby maintains a nearly normal respiratory growth. In addition, CyaY effectively protects yfh1Delta from oxidative damage during treatment with hydrogen peroxide but is less efficient in detoxifying excess labile iron during aerobic growth.     

Iron-activated iron uptake: A positive feedback loop mediated by iron regulatory protein 1

The love-hate relationship between iron and living matter has generated mechanisms to maintain iron concentration in a narrow range, above and below which deleterious effects occur. At the cellular level, iron homeostasis is accomplished by the activity of the IRP proteins, which, under conditions of iron depletion, up-regulate the expression of the iron acquisition proteins TfR and DMT1. It has been shown that hydrogen peroxide activates IRP1 and that this activation mediates a potentially harmful increase in cell iron uptake. Here we show that IRP1 activity is also induced by iron-mediated oxidative stress. When cells were incubated with up to 20 M of iron, a typical decrease in IRP1 and IRP2 activity was observed. Interestingly, when iron was further increased to 40 or 80 M, IRP1 was reactivated in three of the four different cell lines tested, i.e., Caco-2 cells, N2A cells and HepG2 cells. In the fourth cell line (K562) IRP1 activity did not increase, but neither did it decrease. This response to iron was largely abrogated when the antioxidant N-acetyl cysteine was added along with iron to the culture medium. Thus, the effect of iron was mediated by oxidative stress. Increases in IRP1 activity were accompanied by increases in cell iron uptake, an indication that the activated IRP1 was functional in the activation of iron uptake. Hence, this iron-induced iron uptake feedback loop results in the increase of intracellular iron and increased oxidative stress.     

Iron accumulation, iron-mediated toxicity and altered levels of ferritin and transferrin receptor in cultured astrocytes during incubation with ferric ammonium citrate

The cellular uptake and storage of iron have to be tightly regulated in order to provide iron for essential cellular functions while preventing the iron-catalysed generation of reactive oxygen species (ROS). In contrast to cells in other organs, little is known about the regulation of iron metabolism in brain cells, particularly in astrocytes. To investigate the regulation of iron metabolism in astrocytes we have used primary astrocyte cultures from the brains of newborn rats. After application of ferric ammonium citrate (FAC), cultured astrocytes accumulated iron in a time- (0-48 h) and concentration-dependent (0.01-1 mm) manner. This accumulation was prevented if FAC was applied in combination with the iron-chelator deferoxamine (DFX). Application of FAC to astrocyte cultures caused a strong increase in the cellular content of the iron storage protein ferritin and a decrease in the amount of transferrin receptor (TfR), which is involved in the transferrin-mediated uptake of iron into cells. In contrast, application of DFX strongly increased the level of TfR. Both up-regulation of ferritin content by iron application and up-regulation of TfR content by DFX were prevented by the protein synthesis inhibitor cycloheximide (CHX). During incubation of astrocytes with FAC, a mild and transient increase in the extracellular activity of the cytosolic enzyme lactate dehydrogenase and in the concentration of intracellular ROS was observed. In contrast, prevention of protein synthesis by CHX during incubation with FAC resulted in significantly more cell loss and a persistent and intense increase in the production of intracellular ROS. These results demonstrate that both iron accumulation and deprivation modulate the synthesis of ferritin and TfR in astrocytes and that protein synthesis is required to prevent iron-mediated toxicity in astrocytes.     

妊娠期糖尿病患者体内铁负荷状态及氧化应激水平的研究

为了探讨铁代谢在妊娠期糖尿病(GDM)发病中的作用,对GDM患者体内铁负荷状态、氧化应激水平及抗氧化状态进行分析研究.在912例孕24～28周产前检查的孕妇中,按血糖筛查和糖耐量试验筛选出GDM孕妇32例为实验组,随机选择糖耐量正常孕妇26例作为对照组,分别测定两组孕妇的血红蛋白(Hb)等指标,以评价机体铁代谢状况;测...     

Hypothiocyanite and host–microbe interactions

The pseudohypohalous acid hypothiocyanite/hypothiocyanous acid (OSCN⁻/HOSCN) has been known to play an antimicrobial role in mammalian immunity for decades. It is a potent oxidant that kills bacteria but is non-toxic to human cells. Produced from thiocyanate (SCN⁻) and hydrogen peroxide (H₂O₂) in a variety of body sites by peroxidase enzymes, HOSCN has been explored as an agent of food preservation, pathogen killing, and even improved toothpaste. However, despite the well-recognized antibacterial role HOSCN plays in host–pathogen interactions, little is known about how bacteria sense and respond to this oxidant. In this work, we will summarize what is known and unknown about HOSCN in innate immunity and recent advances in understanding the responses that both pathogenic and non-pathogenic bacteria mount against this antimicrobial agent, highlighting studies done with three model organisms, Escherichia coli, Streptococcus spp., and Pseudomonas aeruginosa.     

Effect of iron supplementation on oxidative stress and antioxidant status in iron-deficiency anemia

This study was designed to measure the effect of iron supplementation on antioxidant status in iron-deficient anemia, including the time for hemoglobin normalization and at the time of filling of iron body stores. The extent of plasma lipid peroxidation was evaluated by measuring the levels of malondialdehyde and glutathione peroxidase (GSH-Px), and the activities of superoxide dismutase (SOD) and catalase in 63 patients with iron-deficiency anemia before and after 6 wk of iron supplementation and at the time when body iron stores are saturated. After 6 wk of iron supplementation, a significant decrease of oxidative stress was observed in the treated subjects relative to controls (p<0.05). No significant differences existed between treated patients at 6 wk and at the end of the study. The erythrocyte levels of catalase, SOD, and GSH-Px were significantly lower in treated patients relative to controls (p<0.05). These levels increased after 6 wk of supplementation (p<0.05) and showed no significant differences with those at the end of the study.     

Ironing out Parkinson's disease: is therapeutic treatment with iron chelators a real possibility?

Levels of iron are increased in the brains of Parkinson's disease (PD) patients compared to age-matched controls. This has been postulated to contribute to progression of the disease via several mechanisms including exacerbation of oxidative stress, initiation of inflammatory responses and triggering of Lewy body formation. In this minireview, we examine the putative role of iron in PD and its pharmacological chelation as a prospective therapeutic for the disease.     

布氏柠檬酸杆菌JPG1的SoxR对好氧/厌氧-甲萘醌胁迫生理响应的调控

SoxR是细菌应答氧化胁迫的转录调控因子之一,在细菌逆境非生物胁迫防御中发挥着至关重要的作用。目前对细菌应答氧化胁迫的认知主要来自包括大肠杆菌在内的少数模式菌,为了研究非模式细菌应答氧化胁迫的方式,本研究以肠杆菌科中常见的布氏柠檬酸杆菌(Citrobacter braakii)为模型,基于全基因组背景分析SoxR进化关系,构建soxR基因缺失菌株(ΔsoxR),并以氧化还原循环化合物甲萘醌为诱导剂,通过细胞存活能力测定,探究转录因子Sox R在应答好氧/厌氧-甲萘醌胁迫中的作用。好氧条件下,低浓度甲萘醌(0.1 mmol/L)胁迫24 h后,野生型细胞数量比0 h增加了4.2倍,Δsox R仅增加了1.3倍;高浓度甲萘醌(0.3 mmol/L)胁迫的野生型和Δsox R细胞数量分别为0 h时的29%和0.2%。厌氧条件下,甲萘醌不影响野生型和Δsox R细胞的生长,与对照组(0 mmol/L)相比无显著差异(P>0.05)。结果表明,C. braakii JPG1的SoxR仅在好氧条件下响应氧化还原循环化合物甲萘醌的胁迫并增强了菌株的抗氧化能力,对厌氧-甲萘醌无响应。本研究为探究细菌在不同氧条件下转录调控因子SoxR对甲萘醌胁迫响应的调控作用提供了理论基础。     

Oxygen metabolism,oxidative stress and acid-base physiology of dental plaque biofilms

Dental plaque is a natural biofilm which has been a focus of attention for many years because of its known roles in caries and periodontal diseases. Acid production by plaque bacteria leads to the erosion of tooth mineral in caries, and the cariogenicity of plaque is related to population levels of acid-tolerant organisms such as mutants streptococci. However, the biofilm character of plaque allows for survival of a diverse flora, including less acid-tolerant organisms, some of which can produce ammonia from arginine or urea to counter acidification. Plaque is often considered to be relatively anaerobic. However, evidence is presented here that both supragingival and subgingival plaque have active oxygen metabolism and that plaque bacteria, including anaerobes, have developed defenses against oxidative stress. Even in subgingival plaque associated with periodontitis, measured residual oxygen levels are sufficient to allow for oxygen metabolism by organisms considered to be extremely anaerobic such asTreponema denticola, which metabolizes oxygen by means of NADH oxidases and produces the protective enzymes superoxide dismutase and NADH peroxidase. The finding that plaque bacteria produce a variety of protective enzymes is a good indicator that oxidative stress is a part of their everyday life. The biofilm character of plaque allows for population diversity and coexistence of aerobes, anaerobes and microaerophiles. Overall, agents that affect oxidative metabolism offer possibilities for reducing the pathogenic activities of plaque.     

Retinol supplementation induces DNA damage and modulates iron turnover in rat Sertoli cells

Recent intervention studies revealed that supplementation with retinoids resulted in a higher incidence of lung cancer. Recently the causal mechanism has begun to be clarified. We report here that retinol caused cellular DNA damage probably involving cellular iron accumulation. Retinol (7μM) significantly induced DNA single strands breaks, DNA fragmentation and production of 8-oxo-7, 8-dihydro-2′-deoxyguanosine in cultured Sertoli cells. In contrast, lower doses seemed not to induce single-strands break in this experimental model. The breaks in DNA were inhibited by an iron scavenger; and 7μM retinol treatment modulated iron turnover leading to iron accumulation, suggesting that iron ions were required for the retinol cellular effects. These findings suggest that retinol-induced DNA damage was associated with the modulation of iron turnover, and these characteristics could be responsible for the increased incidence of lung cancer associated with retinoids supplementation.     

Induction of interleukin-6 by coal containing bioavailable iron is through both hydroxyl radical and ferryl species

Coal mining causes health problems, such as pneumoconiosis. We have previously shown that prevalence of pneumoconiosis in workers from various coalmine regions positively correlates with levels of bioavailable iron (BAI) in the coals from that region. In the present study, the nature of reactive oxygen species formed by BAI in the coals and its mechanisms of the induction of biological responses were investigated. Human lung epithelial cell line, A549 cells, were used to examine the induction of interleukin-6 (IL-6), a pro-inflammatory cytokine, which is known to play a crucial role in the development of pneumoconiosis. We found that levels of IL-6 protein as well as its mRNA were significantly increased in the cells treated for 24 h with 20 microg/cm2 of the BAI-containing Pennsylvania (PA) coal; for example we observed 6.7-fold increase in IL-6 protein. Levels of IL-6 protein in cells treated with the Utah (UT) coal containing low-BAI were only 1.9-fold of the control levels. The enhancing effect on the IL-6 by the PA coal was similar to that caused by hydrogen peroxide. Superoxide dismutase (SOD), catalase (CAT), and N-acetyl-L-cysteine (NAC) all had inhibitory effects on the PA coal-induced IL-6 formation. However, CAT had the least protective effect as compared to SOD and NAC. Our results indicate that BAI in the PA coal may induce IL-6 through both ferryl species (via iron autoxidation) and hydroxyl radicals (via the Fenton/Haber Weiss reactions).     

Unique iron binding and oxidation properties of human mitochondrial ferritin: a comparative analysis with Human H-chain ferritin

Ferritins are ubiquitous iron mineralizing and storage proteins that play an important role in iron homeostasis. Although excess iron is stored in the cytoplasm, most of the metabolically active iron is processed in the mitochondria of the cell. Little is known about how these organelles regulate iron homeostasis and toxicity. The recently discovered human mitochondrial ferritin (MtF), unlike other mammalian ferritins, is a homopolymer of 24 subunits that has a high degree of sequence homology with human H-chain ferritin (HuHF). Parallel experiments with MtF and HuHF reported here reveal striking differences in their iron oxidation and hydrolysis chemistry despite their similar diFe ferroxidase centers. In contrast to HuHF, MtF does not regenerate its ferroxidase activity after oxidation of its initial complement of Fe(II) and generally has considerably slower ferroxidation and mineralization activities as well. MtF exhibits sigmoidal kinetics of mineralization more characteristic of an L-chain than an H-chain ferritin. Site-directed mutagenesis reveals that serine 144, a residue situated near the ferroxidase center in MtF but absent from HuHF, is one player in this impairment of activity. Additionally only one-half of the 24 ferroxidase centers of MtF are functional, further contributing to its lower activity. Stopped-flow absorption spectrometry of Fe(II) oxidation by O(2) in MtF shows the formation of a transient diiron(III) mu-peroxo species (lambda(max) = 650 nm) as observed in HuHF. Also, as for HuHF, minimal hydroxyl radical is produced during the oxidative deposition of iron in MtF using O(2) as the oxidant. However, the 2Fe(II) + H(2)O(2) detoxification reaction found in HuHF does not occur in MtF. The structural differences and the physiological implications of the unique iron oxidation properties of MtF are discussed in light of these results.