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Regulation of inflammation by selenium and selenoproteins: impact on eicosanoid biosynthesis

Published online by Cambridge University Press:  29 August 2013

S. A. Mattmiller
Affiliation:
College of Veterinary Medicine, Michigan State University, East Lansing, MI 48824, USA
Bradley A. Carlson
Affiliation:
Section on the Molecular Biology of Selenium, Laboratory of Cancer Prevention, National Cancer Institute, National Institutes of Health, Bethesda, MD 20892, USA
L. M. Sordillo*
Affiliation:
College of Veterinary Medicine, Michigan State University, East Lansing, MI 48824, USA
*
*Corresponding author: Dr Lorraine M. Sordillo, fax +1 517 432 8823, email [email protected]

Abstract

Uncontrolled inflammation is a contributing factor to many leading causes of human morbidity and mortality including atherosclerosis, cancer and diabetes. Se is an essential nutrient in the mammalian diet that has some anti-inflammatory properties and, at sufficient amounts in the diet, has been shown to be protective in various inflammatory-based disease models. More recently, Se has been shown to alter the expression of eicosanoids that orchestrate the initiation, magnitude and resolution of inflammation. Many of the health benefits of Se are thought to be due to antioxidant and redox-regulating properties of certain selenoproteins. The present review will discuss the existing evidence that supports the concept that optimal Se intake can mitigate dysfunctional inflammatory responses, in part, through the regulation of eicosanoid metabolism. The ability of selenoproteins to alter the biosynthesis of eicosanoids by reducing oxidative stress and/or by modifying redox-regulated signalling pathways also will be discussed. Based on the current literature, however, it is clear that more research is necessary to uncover the specific beneficial mechanisms behind the anti-inflammatory properties of selenoproteins and other Se metabolites, especially as related to eicosanoid biosynthesis. A better understanding of the mechanisms involved in Se-mediated regulation of host inflammatory responses may lead to the development of dietary intervention strategies that take optimal advantage of its biological potency.

Type
Nutritional Immunology
Creative Commons
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Copyright
Copyright © The Author(s) 2013

Uncontrolled inflammatory responses can contribute to the pathogenesis of many health disorders. Dysfunctional or uncontrolled inflammation can be characterised as a chronic low-grade inflammation such as that observed in diabetes, obesity and atherosclerosis( Reference Lloyd-Jones, Adams and Carnethon 1 , Reference Boosalis 2 ). Alternatively, uncontrolled inflammation also may manifest as an exacerbated acute inflammation as observed in diseases such as sepsis and mastitis( Reference Sordillo, Contreras and Aitken 3 ). Eicosanoids are a class of lipid mediators that constitute one of the several pathways that regulate the inflammatory response and are biosynthesised by many cell types including endothelial cells and leucocytes. During uncontrolled inflammation, a combination of the overproduction of pro-inflammatory eicosanoids and a diminished synthesis of anti-inflammatory eicosanoids can contribute to an improper and incomplete resolution process. Current non-steroidal anti-inflammatory drug therapies that target specific enzymes involved in eicosanoid biosynthesis have limited efficacy in controlling some inflammatory-based diseases and can cause adverse side effects in both humans and veterinary species( Reference Van der Linden, Van der Bij and Welsing 4 ). Therefore, there is a growing interest to identify alternative therapeutic strategies to regulate uncontrolled inflammation through dietary intervention. The potential of optimising host inflammatory responses by modifying Se dietary intake has been explored in several inflammatory-based disease models such as cancer( Reference Banning, Florian and Deubel 5 ), CVD( Reference Flores-Mateo, Navas-Acien and Pastor-Barriuso 6 ), mastitis( Reference Aitken, Karcher and Rezamand 7 ) and osteoporosis( Reference Cheng, Stabler and Bolognesi 8 ). Although Se nutritional status was often associated with the magnitude and duration of inflammation, the underlying beneficial mechanisms ascribed to this micronutrient are not fully described. The aim of the present review is to assess how the antioxidant and redox-regulating properties of certain selenoproteins can contribute to the beneficial properties of Se nutrition in controlling inflammatory-based diseases. The ability of selenoproteins to regulate eicosanoid biosynthetic pathways in both whole-animal models of disease and in individual cell types will be critically evaluated as potential anti-inflammatory mechanisms resulting from optimal Se intake. A greater understanding of the factors that can regulate the delicate balance between the initiation and resolution of inflammatory responses is needed in order to help diminish the morbidity and mortality associated with the pathology of inflammatory-based diseases.

Selenium: an essential micronutrient with anti-inflammatory properties

Selenium and inflammatory diseases

Se was once considered a toxin when livestock and poultry suffered from alkali disease after consuming grass containing 10–20 parts per million (ppm) Se. Subsequent studies confirmed the potential for Se poisoning when laboratory rodents supplemented with 5–15 ppm of dietary Se displayed varying degrees of pathology( Reference Moxon and Rhian 9 ). In contrast, others found that Se deficiency (diets containing less than 0·1 ppm Se) caused diseases such as white muscle disease in cattle and lambs( Reference Muth, Oldfield and Remmert 10 ) and Keshan disease in human subjects( Reference Chen, Yang and Chen 11 ). Based on these earlier studies, Se is now understood to be an essential micronutrient in the mammalian diet and our knowledge of its metabolism (Fig. 1) and beneficial functions has grown immensely. Current recommendations indicate that the upper tolerable intake of Se is between 90 and 400 µg/d (recommended daily intake between 30 and 55 µg/d) for humans( Reference Monsen 12 ) and 0·4 mg/kg body weight in rodents( Reference Abdo 13 ). In a review and meta-analysis of the literature, Huang et al. ( Reference Huang, Shyu and Chen 14 ) found that supplementation with Se (between 500 and 2000 µg/d for various durations) in critically ill patients decreased mortality rates associated with sepsis. Additionally, women with normal pregnancies exhibited significantly higher blood Se concentrations compared with women with pre-eclampsia, the leading cause of perinatal and maternal mortality globally( Reference Ghaemi, Forouhari and Dabbaghmanesh 15 ). In a model of inflammatory bowel disease, rats fed a high-Se diet (2 µg/g body weight) for 21 d exhibited decreased colonic tissue necrosis( Reference Tirosh, Levy and Reifen 16 ). It is important to note, however, that not all clinical trials involving Se supplementation improved health outcomes in a significant way. Recently published results from The Selenium and Vitamin E Cancer Prevention Trial (SELECT) showed that Se supplementation (200 µg/d), alone or with vitamin E for a period between 7 and 12 years, did not prevent diseases such as prostate, lung or colon cancers and there were no significant differences in cardiovascular events or diabetes between treatment groups in men( Reference Lippman, Klein and Goodman 17 ). Based on these equivocal findings, it is now clear that more research is required to better understand the underlying mechanisms of Se's beneficial health properties in order to design nutritional intervention strategies that yield more consistent and positive results across a range of human health disorders.

Fig. 1. Selenium metabolism from different dietary sources. Dietary intake sources of selenium include the inorganic selenate and selenite (depicted in the green stars), whereas organic sources (depicted in the red stars) are obtained from animal and plant sources that provide selenium in the form of selenocysteine (Sec), selenomethionine and selenium-methylselenocysteine (Se-methyl-Sec). Inorganic forms of selenium are reduced by thioredoxin reductase (TrxR) and thioredoxin (Trx) or converted to selenodiglutathione (GS-Se-SG) by glutathione disulfide (GSSG), reduced by glutathione reductase to glutathioselenol (GS-SeH), then converted to hydrogen selenide (H2Se) in a reaction with GSSG. Selenoproteins are broken down by lyases to form H2Se in intestinal enterocytes. H2Se can then be converted into selenophosphate by selenophosphate synthase and Sec by selenocysteine synthase for incorporation of Sec into selenoproteins. H2Se can also be converted into methylated metabolites by methyltransferases which are primarily excreted through exhalation, urine and faeces. GSH, glutathione.

Selenium functions as an antioxidant through the activity of selenoproteins

Although the importance of Se to health is not fully understood, one well-characterised function of Se is its ability to mitigate oxidative stress through antioxidant-functioning selenoproteins (Table 1), including the well-studied glutathione peroxidase (GPx) and thioredoxin reductase (TrxR) families( Reference Hamilton and Tappel 18 , Reference Sordillo and Aitken 19 ). Oxidative stress occurs when the production of free radicals, including reactive oxygen species (ROS), reactive nitrogen species (RNS), oxidised proteins and oxidised lipids, outweighs an organism's antioxidant capabilities resulting in cellular/tissue damage( Reference Sies 20 ). The GPx and TrxR selenoproteins contain a selenocysteine in their active site making them suitable for oxidation/reduction reactions (Fig. 2). Whereas GPx1 can reduce ROS in the cytoplasm, glutathione peroxidase-4 (GPx4) has the ability to reduce fatty acid hydroperoxides (FAHP) and phospholipid hydroperoxides within cellular membranes (Fig. 2(a))( Reference Kernstock and Girotti 21 , Reference Thomas, Maiorino and Ursini 22 ). A longer, alternative transcript of GPx4 also was localised to mitochondrial membranes( Reference Pushpa-Rekha, Burdsall and Oleksa 23 ) and shown to maintain ATP production during oxidative stress which could have implications on cellular activity and function during disease( Reference Liang, Remmen and Frohlich 24 ). Thioredoxin (Trx) reduces a variety of radicals including lipid hydroperoxides, protein thiols and ROS/RNS. Oxidised Trx is then restored to its reduced form by TrxR selenoproteins (Fig. 2(b)). Selenoproteins W, K and P (Sepw1, Selk, Sepp1) also have been suggested to have antioxidant capabilities, but mechanisms are less understood( Reference Fairweather-Tait, Bao and Broadley 25 , Reference Jeong, Kim and Chung 26 ).

Fig. 2. General reaction mechanisms for antioxidant glutathione peroxidase (GPx) and thioredoxin reductase (TrxR). (a) GPx catalyses the chemical reduction of lipid peroxides or H2O2 to respective alcohols and water by glutathione (GSH) which forms glutathione disulfide (GSSG). Glutathione reductase catalyses the reduction of GSSG back to GSH in the presence of NADPH. (b) Oxidised protein disulfides and other free radicals are reduced to their corresponding thiols by thioredoxin (Trx). TrxR then catalyses the reduction of oxidised Trx in the presence of NADPH.

Table 1. Summary of mammalian selenoproteins with characterised functions*

GPx, glutathione peroxidase; TrxR, thioredoxin reductase; Sepw1, selenoprotein W1; Selk, selenoprotein K; Sepp1, selenoprotein P plasma 1; FAHP, fatty acid hydroperoxide; SelR, selenoprotein R; Sephs2, selenoprotein HS2; Sep15, selenoprotein 15; Selm; selenoprotein M; Seln, selenoprotein N; Sels, selenoprotein S; ER, endoplasmic reticulum; SelH, selenoprotein H; SelI, selenoprotein I; Sepn1, selenoprotein N1; DIO, deiodinase; SelO, selenoprotein O; SelV, selenoprotein V.

†GPx6 contains a selenocysteine (Sec) in man and a cysteine (Cys) in rodents.

Oxidative stress is a contributing factor in inflammatory disease pathologies including atherosclerosis( Reference Praticò, Tangirala and Rader 27 ), diabetes( Reference Monnier, Mas and Ginet 28 ) and mastitis( Reference Ranjan, Swarup and Naresh 29 ) among others. There is ample evidence to indicate that selenoproteins can interrupt disease pathogenesis through antioxidant-dependent mechanisms. Numerous studies in human subjects, food-animal species and rodent models demonstrated a negative correlation between measures of selenoprotein activity and disease severity due to oxidative stress( Reference Bellinger, Raman and Reeves 30 Reference Sordillo 32 ). Direct evidence of the importance of selenoproteins in mitigating oxidative stress was demonstrated in transgenic studies where overexpression of GPx4 significantly reduced lipid peroxidation in atherosclerosis and ischaemia–reperfusion mouse models( Reference Guo, Ran and Roberts 33 , Reference Dabkowski, Williamson and Hollander 34 ). Several in vitro studies also demonstrated that TrxR1 and selenoprotein P could directly reduce the lipid hydroperoxide, 15-hydroperoxyeicosatetraenoic acid (15-HPETE), to its corresponding hydroxyl (15(S)-hydroxy-(5Z,8Z,11Z,13E)-eicosatetraenoic acid; 15-HETE)( Reference Björnstedt, Hamberg and Kumar 35 Reference Rock and Moos 37 ), thus having implications in reducing atherosclerotic lesion formation as a consequence of oxidative stress( Reference George, Afek and Shaish 38 ). Collectively, these studies support the contention that optimally functioning antioxidant selenoproteins may be crucial for reducing excess free radical accumulation and preventing oxidative tissue damage during acute or chronic inflammation.

Role of selenoproteins in cellular redox signalling

Another way in which selenoproteins may protect against immunopathology associated with uncontrolled inflammatory responses is through redox regulation of inflammatory signalling. The redox state of cells or tissues can be defined as the ratio of oxidised and reduced forms of specific redox couples( Reference Schafer and Buettner 39 ). Some redox couples relevant to inflammation include NADP+:NADPH, glutathione disulfide:2 glutathiones (GSH), and oxidised thioredoxin (Trx(SS)):reduced thioredoxin (Trx(SH)2). Thioredoxin and glutathione redox couples function with the help of TrxR and GPx selenoproteins, respectively. Into et al. ( Reference Into, Inomata and Nakashima 40 ) found that GSH was capable of modifying nitrosylated forms of the myeloid differentiation factor 88 (MyD88) adaptor protein which enhanced signalling through the toll-like receptor (TLR4) pathway during acute inflammation and resulted in altered IL-8 and IL-6 expression( Reference Into, Inomata and Nakashima 40 ). Mitogen-activated protein kinase (MAPK) signalling also can be affected by redox tone. Apoptosis signal-regulating kinase 1 (ASK-1) is a MAPK intermediate that activates downstream pro-inflammatory and pro-apoptotic signalling cascades( Reference Al-Gayyar, Abdelsaid and Matragoon 41 , Reference Kataoka, Tokutomi and Yamamoto 42 ). Mammalian Trx is a direct inhibitor of ASK-1 kinase activity and a negative regulator of ASK-1-dependent gene expression( Reference Al-Gayyar, Abdelsaid and Matragoon 41 ). The interaction between ASK-1 and Trx was found to be highly dependent on redox status since oxidation of Trx by ROS results in ASK-1 activation. In contrast, the reduced Trx blocked ASK-1 dependent signalling, indicating a protective role of selenoproteins in regulation of apoptosis during oxidative stress( Reference Saitoh, Nishitoh and Fujii 43 ).

Known as the central regulator of inflammatory gene expression, NF-κB similarly can be redox regulated at several levels. Vunta et al. ( Reference Vunta, Davis and Palempalli 44 , Reference Vunta, Belda and Arner 45 ) reported an association between increased pro-inflammatory NF-κB activation, increased TNFα production and decreased GPx1 activity when macrophages were cultured in Se-deficient media that contained only 6 pmol/ml of Se when compared with cells cultures with 2 nmol/ml of Se( Reference Vunta, Davis and Palempalli 44 , Reference Vunta, Belda and Arner 45 ). Decreased plasma Se (0·37 (se 0·05) compared with 0·85 (se 0·09) µmol/l)( Reference Allard, Aghdassi and Chau 46 ) and decreased selenoprotein synthesis( Reference Gladyshev, Stadtman and Hatfield 47 ) in HIV patients were associated with enhanced oxidative stress-induced activation of NF-κB which promoted HIV viral transcription. In the cytoplasm, ROS-mediated activation of NF-κB can be facilitated through activation of protein kinase A (PKAc) which results in release of NF-κB from inhibitor of κB (IKβ)( Reference Jamaluddin, Wang and Boldogh 48 ), and overexpression of Trx caused a decrease in ROS-mediated NF-κB activity( Reference Meyer, Schreck and Baeuerle 49 ). In the nucleus, however, Trx can enhance NF-κB DNA binding by reducing oxidised cysteine resides on NF-κB( Reference Matthews, Wakasugi and Virelizier 50 ). Hirota et al. ( Reference Hirota, Murata and Sachi 51 ) showed that reduced Trx is primarily found within the cytoplasm of cells; however, upon oxidant stimulation, Trx migrates to the nucleus to enhance NF-κB-DNA binding. These few examples demonstrate how selenoproteins can both positively and negatively control cell signalling depending on the inflammatory pathway and/or cellular location. Overall, Se nutrition and selenoprotein activity have the potential to improve inflammatory response outcomes in several ways including combating oxidative stress in cells/tissues and through the redox regulation of inflammatory signalling pathways that lead to cytokine/chemokine production. However, another potentially important but less studied mechanism underlying the health benefits of Se may involve the biosynthesis of bioactive lipid mediators that include the eicosanoids (Fig. 3).

Fig. 3. Selenium's potential impact on the regulation of inflammation. Some of the several ways in which inflammation is mediated through selenoproteins include modifying cellular redox tone which has implications on signalling through the NF-κB, mitogen-activated protein kinase (MAPK) and PPARγ pathways, controlling the expression of inflammatory mediators such as cytokines, chemokines, and cyclo-oxygenase (COX) and lipoxygenase (LOX) enzymes. Selenoproteins also combat oxidative stress which could potentially make an impact on COX/LOX enzyme activity and the production of lipid peroxides oxidised non-enzymically by free radicals. Non-enzymic lipid oxidation, COX/LOX expression and COX/LOX activity have been shown to regulate eicosanoid biosynthesis. Selenium has been studied in the context of each of these regulators and the present review focuses specifically on selenium's impact on eicosanoid biosynthesis. ROS, reactive oxygen species.

Can selemium and selenoproteins have an impact on inflammation through eicosanoid biosynthesis?

Regulation of inflammation by eicosanoids

Eicosanoids are a class of lipid mediators that contribute to the orchestration of inflammatory responses. Eicosanoids are synthesised from PUFA substrates primarily found in the cellular membrane including the n-6 arachidonic acid (AA) and linoleic acid (LA) or the n-3 EPA and DHA( Reference Schmitz and Ecker 52 ). These fatty acid substrates are oxidised non-enzymically by free radicals or through different enzymic pathways including the cyclo-oxygenases (COX), lipoxygenases (LOX) and cytochrome P450 pathways to produce both pro-inflammatory and resolving eicosanoids (Fig. 4). Non-enzymic oxidation of AA produces the isoprostane series of PG-like eicosanoids. These lipid mediators have been characterised as biomarkers for oxidative stress( Reference Roberts and Morrow 53 ). As such, they have been quantified in models of inflammatory disease, like atherosclerosis, to identify relationships between disease progression and oxidative damage( Reference Lakshmi, Padmaja and Kuppusamy 54 ). In addition to the isoprostanes, non-enzymic oxidation of AA or LA can also produce hydroperoxide metabolites HPETE or hydroperoxyoctadecadienoic acid (HPODE), respectively, that are enhanced during oxidative stress( Reference Spiteller and Spiteller 55 ). Two isoforms of COX enzymes are involved in the enzymic oxidation pathways. Whereas COX-1 is constitutively expressed in cells, COX-2 expression is inducible during inflammation( Reference Xie, Chipman and Robertson 56 , Reference Kurumbail, Kiefer and Marnett 57 ). COX catalyse the oxidation of n-6 AA to PGG2 and PGH2 ( Reference Dubois, Abramson and Crofford 58 ). From PGH2, downstream PG synthases produce PGE2, PGD2, PGI2, PGF, among others. Alternatively, thromboxane (TX) synthases convert PGH2 to thromboxane A2 (TXA2) and thromboxane B2 (TXB2). Similar to the COX family, there are several isoforms of LOX involved in the enzymic oxidation of fatty acids. For example, 5-LOX catalyses the oxidation of n-6 AA to 5-HPETE which can be further metabolised to produce leukotrienes (LT). Both 15-LOX-1 (12-LOX in mice) and 15-LOX-2 (8-LOX in mice) oxidise AA to 12/15-HPETE( Reference Kuhn and Thiele 59 ). More recent studies have led to the discovery of anti-inflammatory lipoxins (LX) that are produced from the metabolism of 12/15-HPETE intermediates by the 5-LOX pathway( Reference Chiang, Arita and Serhan 60 ). Likewise, 12/15-LOX-1 can oxidise the n-6 LA into 9-hydroperoxy-10E,12Z-octadecadienoic acid (9-HPODE) and 13S-hydroperoxy-9Z,11E-octadecadienoic acid (13-HPODE)( Reference Kuhn and O'Donnell 61 ). Hydroperoxides can then be reduced to form hydroxyl intermediates (HETE and hydroxy-octadecadienoic acid (HODE)) and further dehydrogenated to form ketone intermediates (oxo-eicosatetraenoic acid (oxoETE) and oxo-octadecadienoic acid (oxoODE))( Reference Yuan, Rapoport and Soldin 62 ). n-3 Fatty acids also can be oxidised by COX and LOX to produce eicosanoids with more anti-inflammatory or resolving properties( Reference Schmitz and Ecker 52 ). EPA is metabolised by 5-LOX and modified forms of COX-2 to produce E-series resolvins (Rv)( Reference Oh, Dona and Fredman 63 ), whereas 12/15-LOX converts DHA to the D-series Rv, protectins (PD1) and the macrophage-specific maresin (MaR1). During uncontrolled inflammation, a combination of exacerbated production of pro-inflammatory eicosanoids and diminished production of anti-inflammatory eicosanoids prevents full resolution and restoration of homeostasis( Reference Merched, Ko and Gotlinger 64 ). Therefore, the balance between production of pro- and anti-inflammatory eicosanoids is one factor that determines the inflammatory phenotype of a cell/surrounding microenvironment( Reference Serhan and Savill 65 ).

Fig. 4. Eicosanoid biosynthesis pathways. n-3 and n-6 Fatty acids are released from the cellular membrane by phospholipase enzymes. Long-chain PUFA are oxidised either non-enzymically by free radicals or by cyclo-oxygenase-1/2 (COX-1/2), 15-lipoxygenase (15-LOX) and 5-LOX enzymes to produce eicosanoid signalling metabolites. AA, arachidonic acid; AcCOX, aspirin-acetylated cyclo-oxygenase; 15-epi LXA4, 15-epi lipoxin A4; Rv, resolvin; F2-IsoP, PG-like F2 isoprostanes; TX, thromboxane; 15d-PGJ2, 15-deoxy-Δ12,14PGJ2; LA, linoleic acid; HPETE, hydroperoxyeicosatetraenoic acid; 15-oxoETE, 15-oxo-eicosatetraenoic acid; HETE, hydroxy-eicosatetraenoic acid; MaR1, maresin; PD, protectin; HODE, hydroxy-octadecadienoic acid; 5-oxoETE, 5-oxo-eicosatetraenoic acid; LT, leukotriene.

Eicosanoid abundance and timing of their production are crucial to successfully initiate and resolve inflammation. Eicosanoid biosynthesis is regulated at several levels and both Se and selenoproteins have been studied in the context of: (1) altering eicosanoid profiles as a function of manipulating dietary Se; (2) feedback loops from other eicosanoids; (3) chemically reducing lipid hydroperoxides; and (4) modifying expression and activity of COX/LOX enzymes (Table 2 and Fig. 5). However, research has just begun to uncover the underlying mechanisms of how Se can influence eicosanoid biosynthesis at each level of regulation.

Fig. 5. Proposed interactions of selenium with eicosanoid biosynthesis pathways. (a) Selenium and selenoproteins interfere with eicosanoid feedback loops. While glutathione peroxidase (GPx)-1 and -4 can reduce fatty acid hydroperoxides (FAHP) to decrease cyclo-oxygenase-2 (COX-2) activity, a buildup of FAHP, when GPx activity is lacking, can also inhibit COX-2. GPx-2 and -4 diminish PGE2-dependent expression of COX-2. Selenium enhances 15-deoxy-Δ12,14PGJ2 (15d-PGJ2) production which is a ligand for PPARγ. PPARγ signalling enhances haematopoietic PGD2 synthase (H-PGDS), which synthesises PGD2, an upstream metabolite of 15d-PGJ2. AA, arachidonic acid; mPGES-1, microsomal PGE2 synthase-1. (b) Antioxidant selenoproteins can affect different signalling pathways leading to activation of NF-κB and activator protein-1 (AP-1) and expression of COX, lipoxygenase (LOX) and other inflammatory mediators such as TNFα and macrophage chemoattractant protein-1 (MCP-1). GPx can alter the redox state of the myeloid differentiation factor 88 (MyD88) adaptor protein, when MyD88 is denitrosylated by GPx with glutathione (GSH), signalling is enhanced. Reactive oxygen species (ROS)-mediated phosphorylation of inhibitor of κB (IKβ) can be dampened when antioxidant selenoproteins are present to scavenge ROS. The mitogen-activated protein kinases (MAPK) can also be affected; ROS-mediated oxidation of thioredoxin (Trx) causes its dissociation from apoptosis signal-regulating kinase 1 (ASK-1), enhancing signalling activity. In the nucleus, Trx can reduce oxidised cysteine residues on NF-κB, enhancing DNA binding and transcription. TLR4, toll-like receptor; TrxR, thioredoxin reductase; IKK, IκB kinase; Trx(SS), oxidised Trx; JNK, c-Jun N-terminal protein kinase.

Table 2. The impact of selenium and selenoproteins on eicosanoid biosynthesis

↓, Decrease; ↑, increase; H-PGDS, haematopoietic PGD2 synthase; mPGES-1, microsomal PGE2 synthase-1; PGIS, prostacyclin synthase; TXAS, thromboxane A2 synthase; LTA4H, leukotriene A4 hydrolase; COX-2, cyclo-oxygenase-2; 15-LOX, 15-lipoxygenase; GPx4, glutathione peroxidase-4; TXB2, thromboxane B2; LTB4, leukotriene B4; HPETE, hydroperoxyeicosatetraenoic acid; HETE, hydroxyeicosatetraenoic acid; HPODE, hydroperoxyoctadecadienoic acid; HODE, hydroxy-octadecadienoic acid.

Selenium and eicosanoid profiles

Previous studies have documented how dietary Se has an impact on the biosynthesis of eicosanoids in several different species. Following 2 years of supplementation, increased Se in the diet of human subjects (100 µg/d) was correlated with a decreased ratio of urinary 11-dehydro TXB2:2,3 dinor 6-keto PGF. Increased ratios of TXB2:6-keto PGF are an indicative biomarker for thrombosis and atherosclerosis( Reference Arnaud, Bost and Vitoux 66 ). Previous research by Meydani( Reference Meydani 67 ) and then Haberland et al. ( Reference Haberland, Neubert and Kruse 68 ) confirmed that adequate Se intake (300 µg Se/kg and 0·2 ppm, respectively) in rats can decrease the ratio of TXB2:PGF following short-term (2 months) and long-term (eight generations) of dietary modulation, respectively. In dairy cattle with mastitis, Se-sufficient diets (0·05 mg Se/kg) were associated with decreased pro-inflammatory TXB2, PGE2 and LTB4 eicosanoid production and secretion in milk compared with cows with deficient Se intake after 1 year of dietary interventions( Reference Maddox, Reddy and Eberhart 69 ). Taken together, these results indicate that dietary Se could potentially diminish pro-inflammatory eicosanoid biosynthesis during inflammatory diseases.

Se can also alter feedback loops involved with eicosanoid biosynthesis. One example was reported on the positive feedback loop involving the ability of 15-deoxy-Δ12 , 14PGJ2 (15d-PGJ2) to perpetuate anti-inflammatory eicosanoid production by enhancing the expression of its upstream synthesis enzyme in macrophages. Compared with Se deficiency (6 pmol/ml of Se from media FBS (fetal bovine serum) compared with cells supplemented with 250 nm), culturing murine macrophages with Se to maximise GPx activity enhanced 15d-PGJ2 production; 15d-PGJ2 is a ligand for PPARγ that, once activated, enhanced H-PGDS (haematopoietic PGD2 synthase) expression. H-PGDS converts PGH2 to PGD2, which is an upstream metabolite of 15d-PGJ2 ( Reference Gandhi, Kaushal and Ravindra 70 ). Thus, depending on the level of regulation, Se could potentially dampen pro-inflammatory eicosanoid biosynthesis and enhance more anti-inflammatory eicosanoid production; however, more research is needed to determine the specific mechanisms involved at different levels of regulation of eicosanoid biosynthesis and which selenoproteins could have an effect.

Antioxidant-dependent regulation of eicosanoid biosynthesis

There is evidence that certain selenoproteins are at least partially responsible for the ability of Se to modify eicosanoid biosynthesis. A direct cause-and-effect relationship between GPx4 and LT production in cancer cells was previously explored by Imai et al. ( Reference Imai, Narashima and Arai 71 ). At the metabolite level, GPx4 overexpression was shown to reduce FAHP from the 5-LOX pathway (5-HPETE to 5-HETE), thus preventing the production of LTB4 and C4 in the leukaemia cell line( Reference Imai, Narashima and Arai 71 ). The proposed mechanism was the antioxidant capabilities of GPx4 and the ability to reduce FAHP to hydroxyl derivatives. Others found that GPx4 reduced 15-HPETE to 15-HETE and pre-incubation of endothelial cells with GPx4 could prevent peroxide formation( Reference Schnurr, Belkner and Ursini 72 ). Both TrxR and Sepp1 also were shown to have lipid hydryperoxidase activity for 15-HPETE, thus supporting the contention that these selenoproteins can function as antioxidant enzymes against highly reactive hydroperoxy intermediates formed during eicosanoid metabolism( Reference Björnstedt, Hamberg and Kumar 35 , Reference Rock and Moos 37 ). Collectively, these studies suggest that selenoproteins have an important role in protecting cells against oxidative damage caused by lipid hydroperoxides found in the eicosanoid network.

Individual selenoproteins also can modify eicosanoid biosynthesis through controlling the activity of COX/LOX enzymes. Walther et al. described how the Se-containing compound ebselen inhibited 15-LOX activity by altering the oxidation status of the active-site Fe molecule( Reference Walther, Holzhutter and Kuban 73 ). The activation of COX enzymes also requires oxidation of their active site haeme Fe to form a tyrosyl radical that is then capable of oxidising AA and other fatty acid substrates( Reference Marnett, Rowlinson and Goodwin 74 ). GPx1 can inhibit COX enzyme activity by chemically reducing hydroperoxides that could otherwise activate enzymic oxidation( Reference Cook and Lands 75 ). An abundance of eicosanoid metabolites and other radicals, however, can also inhibit the activity of eicosanoid enzymes through what is known as ‘suicide inactivation’, as described for COX( Reference Smith and Lands 76 ), PGI synthase( Reference Wade, Voelkel and Fitzpatrick 77 ) and thromboxane A2 synthase (TXAS)( Reference Jones and Fitzpatrick 78 ). A decrease in COX activity was described in human endothelial cells due to a buildup of peroxides during diminished GPx1 activity( Reference Hampel, Watanabe and Weksler 79 ). These findings suggest that cellular levels of FAHP are critical in COX enzyme activity; both an excess of FAHP or absence of these radicals can result in COX inhibition. This is interesting because GPx-mediated reduction of FAHP could have different effects on COX or LOX activity depending on the accumulation of FAHP. FAHP generated by the 15-LOX pathway were shown to be affected by another selenoprotein in vitro. Sepp1, a selenoprotein present in plasma, was shown to chemically reduce 15-HPETE into 15-HETE( Reference Rock and Moos 37 ). Additionally, Sepp1 decreased the production of free radicals following stimulation with 15-HPETE in vitro ( Reference Rock and Moos 37 ). This study highlighted the antioxidant properties of the plasma selenoprotein, Sepp1, which could have significant implications in preventing oxidative stress associated with vascular inflammatory diseases, such as atherosclerosis.

Redox regulation of eicosanoid biosynthesis

Another way that Se can affect eicosanoid profiles is through the redox regulation of eicosanoid enzyme expression. Pre-treating chondrocytes with physiological levels of selenomethionine (Se-Met) (0·5 µm) for 24 h, for example, decreased IL-1β-induced gene expression of COX-2 and consequent synthesis of PGE2 ( Reference Cheng, Stabler and Bolognesi 8 ). Hwang et al. showed in mice that supplementation with 30 µg selenate per g body weight for 2 weeks decreased tumour size and COX-2 expression in a model of colon cancer( Reference Hwang, Kim and Surh 80 ). Addition of various supraphysiological doses of Se (250–500 µm) to cultured HT-29 cells dampened extracellular signal-regulated kinase (ERK) signalling following stimulation with a tumour-promoting agent, 12-O-tetradecanoylphorbol-13-acetate (TPA), and increased MAPK signalling; both of which decreased COX-2 expression( Reference Hwang, Kim and Surh 80 ). In another model, prostate cancer cells (PC3) pre-treated with sodium selenite (0·5–5 µm) for 24 or 48 h had significantly decreased NF-κB activity, which is another pathway known to control COX-2 expression( Reference Pei, Li and Guo 81 ). As described earlier, the redox control of these signalling pathways can occur at several signalling intermediates. Collectively, these studies support the concept that Se can decrease COX-2 expression, at least in part, through the regulation of various redox-dependent signalling pathways. More research is needed, however, to characterise cause-and-effect relationships identifying where specific selenoproteins could be regulating COX-2 expression through other redox-regulated signalling pathways.

Selenium can affect eicosanoid biosynthesis in cancer models

Inflammatory pathways can play an important role in cancer development through regulation of cell proliferation and migration( Reference Coussens, Zitvogel and Palucka 82 ). For example, eicosanoids can play an important role in tumorigenesis by regulating apoptosis and proliferation of cancer cells( Reference Sheng, Shao and Morrow 83 , Reference Avis, Hong and Martínez 84 ) and Se may exert anti-cancerous properties through the manipulation of eicosanoid signalling. For example, Ghosh et al. ( Reference Ghosh 85 ) reported that supplementation with various Se doses (0–3 µm) for 72 h induced apoptosis of LNCaP human prostate cancer cells but not of normal PrEC prostate cells( Reference Ghosh 85 ). Additionally, they noted that stimulation of LNCaP with 5-LOX-derived eicosanoids, 5-HETE and 5-oxoETE (5-oxo-eicosatetraenoic acid), reversed Se's apoptotic effect and enhanced growth of cancerous cells, thus indicating that 5-LOX-derived eicosanoids may play a role in promoting cancerous cell growth in prostate cancer( Reference Ghosh 85 ). Other researchers explored the relationship between specific selenoproteins and eicosanoid regulation in models of colon cancer. In GPx2-silenced HT-29 colon cancer cells, an increase in COX-2 and microsomal PGE2 synthase-1 enzyme expression with a concomitant increase in PGE2 production was reported( Reference Banning, Florian and Deubel 5 ). The authors proposed that GPx2 disrupted the positive feedback loop of PGE2-dependent expression of COX-2, representing a unique role specific for GPx2 in the colon cancer model( Reference Banning, Florian and Deubel 5 ). This same feedback loop also was studied in the context of GPx4 and a fibrosarcoma cancer model. In L29 fibrosarcoma tumour cells, overexpression of GPx4 prevented tumour growth, decreased COX-2 expression and PGE2 production, and abrogated PGE2-dependent COX-2 expression( Reference Heirman, Ginneberge and Brigelius-Flohé 86 ). These studies provide examples in cancer models that the redox-regulating properties of certain selenoproteins could decrease pro-inflammatory eicosanoid production and reduce inflammatory-dependent tumour progression.

Selenium's effect on eicosanoid biosynthesis in CVD models

Atherosclerosis is another inflammatory-based disease that remains the leading cause of death in the developed world( Reference Lloyd-Jones, Adams and Carnethon 1 ). As such, interest is growing in understanding how Se may be beneficial in CVD models. Oxidative stress plays a significant role in the aetiology of cardiovascular lesion development by promoting the production of oxidised lipoproteins (oxLDL) and lipids such as the non-enzymically oxidised eicosanoids, PG-like F2 isoprostanes (F2-IsoP)( Reference Lakshmi, Padmaja and Kuppusamy 54 ). These radicals, oxLDL in particular, are recognised and internalised by circulating monocytes which initiate foam cell development and macrophage infiltration into blood vessels( Reference Quinn, Parthasarathy and Fong 87 ). The lipid hydroperoxide scavenging GPx4 was overexpressed in a mouse model of atherosclerosis (ApoE−/– mice) which resulted in decreased overall atherosclerotic lesion development( Reference Guo, Ran and Roberts 33 ). The mechanisms behind the protective effect of GPx4 in this study were thought to be enhanced through GPx4's antioxidant capabilities to decrease the accumulation of hydroperoxide radicals and diminish oxidative stress. In support of this theory, both F2-IsoP production and accumulation of intercellular and secreted hydroperoxides were significantly decreased in GPx4-overexpressing mouse aortic endothelial cells compared with atherosclerotic cells( Reference Guo, Ran and Roberts 33 ). When mitochondrial GPx4 was overexpressed in a mouse ischaemia–reperfusion model, researchers documented significantly increased cardiac function and decreased lipid peroxidation( Reference Dabkowski, Williamson and Hollander 34 ). In another atherosclerosis model, ApoE−/– and GPx1 double knockout mice exhibited significantly increased atherosclerotic lesion development, suggesting that GPx1 may also play a role in disease progression( Reference Lewis, Stefanovic and Pete 88 ). Taken together, these data suggest that GPx could be a potential therapeutic target during heart disease due to their antioxidant properties and their capability to reduce lipid hydroperoxides and other radicals to less reactive lipid alcohols.

In addition to the antioxidant properties of selenoproteins, other possible mechanisms to explain Se's protective effects in an atherosclerosis disease model were examined. For example, Paniker et al. explored the impact of fatty acid substrate availability and downstream eicosanoid enzymic expression( Reference Panicker, Swathy and John 89 ). In their study, sodium selenite (8 µg/100 g body weight) supplementation for 30 d in isoproterenol-induced myocardial infarction in rats decreased LOX activity, leukotriene A4 hydrolase (LTA4H) expression, and LTB4 production in monocytes( Reference Panicker, Swathy and John 89 ). Se supplementation also decreased the amount of NEFA in the heart which can serve as substrates for LOX enzymic pathways. The expression of LTA4H was diminished and resulted in decreased LTB4 concentrations. By diminishing the expression of LTA4H, the intermediate lipid metabolite LTA4 is prevented from being metabolised to the more pro-inflammatory eicosanoid LTB4, and preserved for the biosynthesis of resolving eicosanoids, such as LXA4. Although the mechanism behind the decrease in LTA4H in Se-treated animals was not explored, evidence suggests that specific enzymic pathways are potential target for Se-mediated treatment of uncontrolled inflammation. The current findings support the concept that antioxidant selenoproteins could play a role in controlling both non-enzymic and COX/LOX-mediated oxidation of lipid mediators during CVD. Further research is needed, however, to determine which antioxidant selenoproteins are most critical for regulating eicosanoid biosynthesis and lipid peroxide-mediated disease progression.

Selenium's impact on eicosanoids in specific cell-types: endothelial cells

Since many different cell types function in concert during inflammation, studies have focused on characterising the effects of Se on single-cell cultures to determine their role in inflammatory disease. Endothelial cells are an important component of the immune system. They are the barrier between the blood and tissue, regulate immune cell trafficking, and have been the focus of a number of studies on Se nutrition and eicosanoid biosynthesis. Confirmation that selenoprotein expression within endothelial cells is essential to survival was demonstrated when targeted knock out of selenoproteins in murine endothelial cells resulted in embryonic death due to haemorrhaging and erythrocyte immaturity( Reference Shrimali, Weaver and Miller 90 ). The ability of Se to reduce lipid radical accumulation in endothelial cells was explored in early studies by Cao et al. ( Reference Cao, Reddy and Sordillo 91 ). Se-deficient bovine aortic endothelial cells cultured in the presence of only 0·01 ppm Se were characterised by a significant decrease in GPx1 activity with concomitant increases in 15-HPETE and TXB2 compared with cells supplemented with 10 ng/ml sodium selenite( Reference Cao, Reddy and Sordillo 91 ). The same group then explored the association between diminished Se status of endothelial cells and the ability of 15-HPETE to elicit signs of oxidative stress( Reference Trigona, Mullarky and Cao 36 ), enhanced adhesion molecule expression( Reference Sordillo, Streicher and Mullarky 92 ), higher rates of apoptosis( Reference Sordillo, Weaver and Cao 93 ) and dampened expression of PGI2 ( Reference Weaver, Maddox and Cao 94 ). Collectively, these studies support the concept that the antioxidant ability of selenoproteins is necessary to mitigate the pro-inflammatory effects of 15-HPETE and reduce endothelial cell death as a consequence of oxidative stress. Evidence also supports a direct effect of TrxR in controlling oxidative stress and inflammation in vascular endothelial cells. Trigona et al. examined the role that TrxR activity may have on the differential regulation of the antioxidant enzyme haeme oxygenase-1 (HO-1) in 15-HPETE-challenged endothelial cells( Reference Trigona, Mullarky and Cao 36 ). Silencing TrxR expression and activity prevented the compensatory increase in HO-1 when endothelial cells were stimulated with 15-HPETE. Additional experiments demonstrated that HO-1 induction was dependent on the TrxR redox activity since restoring intracellular levels of reduced Trx was sufficient to increase HO-1 expression when endothelial cells were cultured in Se-deficient media (less than 0·1 ppm Se)( Reference Trigona, Mullarky and Cao 36 ). This area requires more attention in future research, especially in the context of 15-LOX activity and redox-regulation of signalling that controls 15-LOX-derived metabolite formation as there are some conflicting reports of the role of this pathway in disease progression. Whereas some researchers have found that enhancing 15-LOX enzyme activity leads to resolving eicosanoid production( Reference Serhan and Savill 65 ), others have found enhanced pro-inflammatory effects( Reference Rydberg, Krettek and Ullström 95 ). It will be necessary to identify how selenoproteins, such as TrxR1, affect the balance of pro- and anti-inflammatory eicosanoids as a function of 15-LOX activity in endothelial cells to better understand their role in inflammatory responses.

Impact of selenium on eicosanoids in specific cell-types: leucocyte function

Lymphocytes are critical responders to inflammatory stimuli. They play a major role in inflammatory-based diseases including CVD by producing chemoattractants such as macrophage chemoattractant protein-1 (MCP-1) to enhance macrophage infiltration( Reference Takahashi, Takeya and Sakashita 96 ). Lymphocytes are also important sources of eicosanoids and were studied in the context of Se nutrition. One group found significant decreases in eicosanoid production from lymphocytes obtained from rats fed a Se-deficient diet containing only <0·05 mg Se/kg( Reference Cao, Weaver and Chana Reddy 97 ). The underlying mechanism behind the decrease in eicosanoid biosynthesis was proposed to be that Se-deficient lymphocytes had significantly diminished phospholipase D activation which is responsible for liberating fatty acid substrates from cellular membranes. Future studies should focus on determining how antioxidant selenoproteins can specifically affect the expression and activity of phospholipases, potentially through redox regulation, and how this may affect the eicosanoids produced during inflammation.

Macrophages are especially crucial in pathogen recognition and orchestration of inflammation. Since macrophages synthesise copious amount of ROS to aid in pathogen destruction, they rely on selenoprotein antioxidants to reduce excess radicals that have the potential to cause self-damage( Reference Carlson, Yoo and Sano 98 ). Macrophages were acknowledged as a key cell type in the early development of atherosclerosis because they are responsible for recognising and ingesting oxidised lipoproteins (oxLDL)( Reference Quinn, Parthasarathy and Fong 87 ). Macrophages were the focus of several reports characterising eicosanoid regulation as a function of Se status. Prabhu et al. were interested in exploring the relationship between Se nutrition and the pro-inflammatory signalling pathway, NF-κB( Reference Prabhu, Zamamiri-Davis and Stewart 99 ). These investigators described an association between enhanced NF-κB activity in macrophages cultured in media containing only 6 pmol/ml of Se when compared with cells supplemented with 2 nmol/ml of sodium selenite( Reference Prabhu, Zamamiri-Davis and Stewart 99 ). Additional studies proved that a significant increase in COX-2 enzyme expression during Se deficiency was mediated through increased NF-κB activity( Reference Zamamiri-Davis, Lu and Thompson 100 ). In contrast, Se supplementation (20–50 µm) was able to decreased NF-κB activation and COX-2 expression through the toll-like receptor (TLR4) pathway( Reference Youn, Lim and Choi 101 ). In microglial cells (macrophages specific to the central nervous system and brain), pre-treating cells with Se-containing compounds (0–10 µm) decreased lipopolysaccharide (LPS)-induced NF-κB activation, COX-2 expression and PGE2 production( Reference Nam, Koketsu and Lee 102 ). Collectively, these studies suggest that Se, through the activity of antioxidant selenoproteins, could mediate eicosanoid biosynthesis by controlling NF-κB-dependent COX-2 expression. Other signalling pathways also may be involved in regulating COX-2 expression and the subsequent metabolism of lipids through this pathway. For example, LPS-stimulated macrophages cultured in Se-supplemented media (0·1 µm-sodium selenite) led to a significant decrease in LPS-induced expression of COX-2 and TNF-α by inhibition of the MAPK signalling pathway( Reference Vunta, Belda and Arner 45 ). Additional experiments demonstrated that mice maintained on a Se-deficient diet had significant increases in LPS-mediated infiltration of lung macrophages when compared with animals maintained on a Se-adequate diet( Reference Vunta, Belda and Arner 45 ). One way that Se status was suggested to alter macrophage inflammatory properties was through changes in the profile of COX-derived eicosanoids. Macrophages cultured in Se-supplemented media (0·1 µm-sodium selenite) demonstrated a time-dependent increase in the production of 15d-PGJ2 which is an endogenous inhibitor of NF-κB activation( Reference Vunta, Davis and Palempalli 44 ). Recently, reports showed that downstream eicosanoid synthase enzymes also are affected by selenoproteins( Reference Gandhi, Kaushal and Ravindra 70 ). Se supplementation (0·1 µm) enhanced macrophage expression of H-PGDS and the subsequent increase in Δ12-PGJ2 and 15d-PGJ2 production. These effects where mediated by selenoproteins as confirmed by silencing selenoprotein expression through selenophosphate synthatase 2 in macrophages. On the other hand, microsomal PGE2 synthase and thromboxane A2 synthase (TXAS) were decreased during Se supplementation( Reference Gandhi, Kaushal and Ravindra 70 ). Together, these studies have begun to demonstrate the association between antioxidant selenoproteins and different levels of eicosanoid regulation in macrophages through several different mechanisms including modification of signalling (i.e. NF-κB, MAPK) to affect COX/LOX expression, manipulating downstream eicosanoid synthase expression, altering the production of specific eicosanoids, and disrupting eicosanoid feedback loops. However, more research is warranted to determine which specific selenoproteins are responsible for these effects in order to gain a better understanding of where in the eicosanoid cascade that Se nutritional intervention may be possible.

Conclusions

Uncontrolled inflammation, governed in part by eicosanoids, is recognised to play a prominent role in the major life-threatening diseases of the developed world. Although the beneficial anti-inflammatory properties of Se have been appreciated for many years, the underlying mechanisms of action are not fully understood. There is ample evidence to suggest that optimal Se nutrition can combat uncontrolled inflammation, at least in part, because of the antioxidant and redox-regulating capabilities of selenoproteins. Considerably less is known, however, about the specific selenoproteins that are responsible for these regulatory mechanisms and dynamic changes in their activity that occur during inflammatory processes. More recently, there is a growing body of evidence that further highlights the importance of selenoprotein-dependent regulation of eicosanoid biosynthesis in controlling inflammatory responses. Antioxidant selenoproteins can reduce FAHP and lipid radicals directly, affecting eicosanoid stability as well as phospholipase and COX/LOX activity. Certain selenoproteins also can regulate cellular redox tone which has implications on cell signalling through NF-κB and MAPK pathways, all of which can control expression of COX/LOX enzymes. A major gap in the existing literature, however, is knowledge of how specific selenoproteins can modify eicosanoid networks in such a way as to switch from a pro-inflammatory to resolution state and thereby mitigate uncontrolled inflammatory responses that lead to disease pathogenesis. With the advent of new lipidomic analytical techniques( Reference Serhan and Chiang 103 ), it should now be possible to conduct more detailed investigations of how specific selenoproteins, acting individually or in concert with others, can alter the global expression of eicosanoids relevant to specific disease models. Genomic-based approaches also will be necessary to evaluate the differential expression of selenoproteins in various tissues and how selenoprotein activity can affect eicosanoid biosynthesis in different cells involved in the inflammatory response. Some of the equivocal findings from existing clinical studies involving Se nutritional status can be attributed to the lack of information that links dietary intakes of Se-rich foods with tissue levels of selenoproteins that are needed to modify specific inflammatory-regulating biological responses. More precise details of how selenoproteins can modify eicosanoid metabolism may not only identify relevant therapeutic targets, but also provide accurate biomarkers for assessing optimal Se intake. A better understanding of the mechanisms involved in Se-mediated regulation of host inflammatory responses will lead to more efficient and consistent nutritional intervention strategies than what has been achieved to date.

Acknowledgements

The present study was supported, in part, by the Agriculture and Food Research Initiative Competitive Grants Program (no. 2011-67015-30179 and no. 2012-67011-19944) from the US Department of Agriculture National Institute for Food and Agriculture and by an endowment from the Matilda R. Wilson Fund (Detroit, MI, USA).

Authors contributed as follows: S. A. M. prepared and wrote the manuscript, B. A. C. and L. M. S. contributed to the writing and editing of the manuscript. All authors proofread and approved the final draft.

There are no conflicts of interest to declare.

References

1. Lloyd-Jones, D, Adams, R, Carnethon, M, et al. (2009) Heart disease and stroke statistics – 2009 update. Circulation 119, e21–e181.Google ScholarPubMed
2. Boosalis, MG (2008) The role of selenium in chronic disease. Nutr Clin Pract 23, 152160.Google Scholar
3. Sordillo, LM, Contreras, GA & Aitken, SL (2009) Metabolic factors affecting the inflammatory response of periparturient dairy cows. Anim Health Res Rev 10, 5363.CrossRefGoogle ScholarPubMed
4. Van der Linden, MW, Van der Bij, S, Welsing, P, et al. (2009) The balance between severe cardiovascular and gastrointestinal events among users of selective and non-selective non-steroidal anti-inflammatory drugs. Ann Rheum Dis 68, 668673.CrossRefGoogle ScholarPubMed
5. Banning, A, Florian, S, Deubel, S, et al. (2008) GPx2 counteracts PGE2 production by dampening COX-2 and mPGES-1 expression in human colon cancer cells. Antioxid Redox Signal 10, 14911500.CrossRefGoogle ScholarPubMed
6. Flores-Mateo, G, Navas-Acien, A, Pastor-Barriuso, R, et al. (2006) Selenium and coronary heart disease: a meta-analysis. Am J Clin Nutr 84, 762773.Google Scholar
7. Aitken, SL, Karcher, EL, Rezamand, P, et al. (2009) Evaluation of antioxidant and proinflammatory gene expression in bovine mammary tissue during the periparturient period. J Dairy Sci 92, 589598.Google Scholar
8. Cheng, AWM, Stabler, TV, Bolognesi, M, et al. (2011) Selenomethionine inhibits IL-1β inducible nitric oxide synthase (iNOS) and cyclooxygenase 2 (COX2) expression in primary human chondrocytes. Osteoarthritis Cartilage 19, 118125.CrossRefGoogle ScholarPubMed
9. Moxon, AL & Rhian, M (1943) Selenium poisoning. Physiol Rev 23, 305337.Google Scholar
10. Muth, O, Oldfield, J, Remmert, L, et al. (1958) Effects of selenium and vitamin E on white muscle disease. Science 128, 10901091.Google Scholar
11. Chen, X, Yang, G, Chen, J, et al. (1980) Studies on the relations of selenium and Keshan disease. Biol Trace Elem Res 2, 91107.Google Scholar
12. Monsen, ER (2000) Dietary reference intakes for the antioxidant nutrients: vitamin C, vitamin E, selenium, and carotenoids. J Am Diet Assoc 100, 637640.CrossRefGoogle ScholarPubMed
13. Abdo, KM (1994) NTP Technical Report on Toxicity Studies of Sodium Selenate and Sodium Selenite (CAS Nos. 13410-01-0 and 10102-18-8) Administered in Drinking Water to F344/N Rats and B6C3F1 Mice. Research Triangle Park: NTP Central Data Management.Google Scholar
14. Huang, T-S, Shyu, Y-C, Chen, H-Y, et al. (2013) Effect of parenteral selenium supplementation in critically ill patients: a systematic review and meta-analysis. PLOS ONE 8, e54431.Google Scholar
15. Ghaemi, S, Forouhari, S, Dabbaghmanesh, M, et al. (2013) A prospective study of selenium concentration and risk of preeclampsia in pregnant Iranian women: a nested case–control study. Biol Trace Elem Res 152, 174179.CrossRefGoogle ScholarPubMed
16. Tirosh, O, Levy, E & Reifen, R (2007) High selenium diet protects against TNBS-induced acute inflammation, mitochondrial dysfunction, and secondary necrosis in rat colon. Nutrition 23, 878886.Google Scholar
17. Lippman, SM, Klein, EA, Goodman, PJ, et al. (2009) Effect of selenium and vitamin E on risk of prostate cancer and other cancers: the Selenium and Vitamin E Cancer Prevention Trial (SELECT). JAMA 301, 3951.Google Scholar
18. Hamilton, JW & Tappel, AL (1963) Lipid antioxidant activity in tissues and proteins of selenium-fed animals. J Nutr 79, 493502.Google Scholar
19. Sordillo, LM & Aitken, SL (2009) Impact of oxidative stress on the health and immune function of dairy cattle. Vet Immunol Immunopathol 128, 104109.CrossRefGoogle ScholarPubMed
20. Sies, H (1986) Biochemistry of oxidative stress. Angew Chemie Int Edit 25, 10581071.Google Scholar
21. Kernstock, RM & Girotti, AW (2008) New strategies for the isolation and activity determination of naturally occurring type-4 glutathione peroxidase. Protein Express Purif 62, 216222.CrossRefGoogle ScholarPubMed
22. Thomas, JP, Maiorino, M, Ursini, F, et al. (1990) Protective action of phospholipid hydroperoxide glutathione peroxidase against membrane-damaging lipid peroxidation. In situ reduction of phospholipid and cholesterol hydroperoxides. J Biol Chem 265, 454461.Google Scholar
23. Pushpa-Rekha, TR, Burdsall, AL, Oleksa, LM, et al. (1995) Rat phospholipid-hydroperoxide glutathione peroxidase: cDNA cloning and identification of multiple transcription and translation start sites. J Biol Chem 270, 2699326999.Google Scholar
24. Liang, H, Remmen, HV, Frohlich, V, et al. (2007) Gpx4 protects mitochondrial ATP generation against oxidative damage. Biochem Biophys Res Commun 356, 893898.Google Scholar
25. Fairweather-Tait, SJ, Bao, Y, Broadley, MR, et al. (2011) Selenium in human health and disease. Antioxid Redox Signal 14, 13371383.Google Scholar
26. Jeong, D-W, Kim, TS, Chung, YW, et al. (2002) Selenoprotein W is a glutathione-dependent antioxidant in vivo . FEBS Lett 517, 225228.Google Scholar
27. Praticò, D, Tangirala, RK, Rader, DJ, et al. (1998) Vitamin E suppresses isoprostane generation in vivo and reduces atherosclerosis in apoE-deficient mice. Nat Med 4, 11891192.CrossRefGoogle ScholarPubMed
28. Monnier, L, Mas, E, Ginet, C, et al. (2006) Activation of oxidative stress by acute glucose fluctuations compared with sustained chronic hyperglycemia in patients with type 2 diabetes. JAMA 295, 16811687.Google Scholar
29. Ranjan, R, Swarup, D, Naresh, R, et al. (2005) Enhanced erythrocytic lipid peroxides and reduced plasma ascorbic acid, and alteration in blood trace elements level in dairy cows with mastitis. Vet Res Comm 29, 2734.CrossRefGoogle ScholarPubMed
30. Bellinger, FP, Raman, AV, Reeves, MA, et al. (2009) Regulation and function of selenoproteins in human disease. Biochem J 422, 1122.Google Scholar
31. Lu, J & Holmgren, A (2009) Selenoproteins. J Biol Chem 284, 723727.Google Scholar
32. Sordillo, LM (2013) Selenium-dependent regulation of oxidative stress and immunity in periparturient dairy cattle. Vet Med Int 2013, 154045.Google Scholar
33. Guo, Z, Ran, Q, Roberts, LJ II, et al. (2008) Suppression of atherogenesis by overexpression of glutathione peroxidase-4 in apolipoprotein E-deficient mice. Free Radic Biol Med 44, 343352.Google Scholar
34. Dabkowski, ER, Williamson, CL & Hollander, JM (2008) Mitochondria-specific transgenic overexpression of phospholipid hydroperoxide glutathione peroxidase (GPx4) attenuates ischemia/reperfusion-associated cardiac dysfunction. Free Radic Biol Med 45, 855865.Google Scholar
35. Björnstedt, M, Hamberg, M, Kumar, S, et al. (1995) Human thioredoxin reductase directly reduces lipid hydroperoxides by NADPH and selenocystine strongly stimulates the reaction via catalytically generated selenols. J Biol Chem 270, 1176111764.Google Scholar
36. Trigona, WL, Mullarky, IK, Cao, Y, et al. (2006) Thioredoxin reductase regulates the induction of haem oxygenase-1 expression in aortic endothelial cells. Biochem J 394, 207216.CrossRefGoogle ScholarPubMed
37. Rock, C & Moos, PJ (2010) Selenoprotein P protects cells from lipid hydroperoxides generated by 15-LOX-1. Prostaglandins Leukot Essent Fatty Acids 83, 203210.CrossRefGoogle ScholarPubMed
38. George, J, Afek, A, Shaish, A, et al. (2001) 12/15-Lipoxygenase gene disruption attenuates atherogenesis in LDL receptor-deficient mice. Circulation 104, 16461650.Google Scholar
39. Schafer, FQ & Buettner, GR (2001) Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple. Free Radic Biol Med 30, 11911212.Google Scholar
40. Into, T, Inomata, M, Nakashima, M, et al. (2008) Regulation of MyD88-dependent signaling events by S nitrosylation retards toll-like receptor signal transduction and initiation of acute-phase immune responses. Mol Cell Biol 28, 13381347.Google Scholar
41. Al-Gayyar, MM, Abdelsaid, MA, Matragoon, S, et al. (2011) Thioredoxin interacting protein is a novel mediator of retinal inflammation and neurotoxicity. Br J Pharmacol 164, 170180.Google Scholar
42. Kataoka, K, Tokutomi, Y, Yamamoto, E, et al. (2011) Apoptosis signal-regulating kinase 1 deficiency eliminates cardiovascular injuries induced by high-salt diet. J Hypertens 29, 7684.Google Scholar
43. Saitoh, M, Nishitoh, H, Fujii, M, et al. (1998) Mammalian thioredoxin is a direct inhibitor of apoptosis signal-regulating kinase (ASK) 1. EMBO J 17, 25962606.CrossRefGoogle ScholarPubMed
44. Vunta, H, Davis, F, Palempalli, UD, et al. (2007) The anti-inflammatory effects of selenium are mediated through 15-deoxy-12,14-prostaglandin J2 in macrophages. J Biol Chem 282, 1796417973.Google Scholar
45. Vunta, H, Belda, BJ, Arner, RJ, et al. (2008) Selenium attenuates pro-inflammatory gene expression in macrophages. Mol Nutr Food Res 52, 13161323.Google Scholar
46. Allard, JP, Aghdassi, E, Chau, J, et al. (1998) Oxidative stress and plasma antioxidant micronutrients in humans with HIV infection. Am J Clin Nutr 67, 143147.Google Scholar
47. Gladyshev, VN, Stadtman, TC, Hatfield, DL, et al. (1999) Levels of major selenoproteins in T cells decrease during HIV infection and low molecular mass selenium compounds increase. Proc Natl Acad Sci U S A 96, 835839.Google Scholar
48. Jamaluddin, M, Wang, S, Boldogh, I, et al. (2007) TNF-α-induced NF-κB/RelA Ser276 phosphorylation and enhanceosome formation is mediated by an ROS-dependent PKAc pathway. Cell Signal 19, 14191433.Google Scholar
49. Meyer, M, Schreck, R & Baeuerle, PA (1993) H2O2 and antioxidants have opposite effects on activation of NF-κB and AP-1 in intact cells: AP-1 as secondary antioxidant-responsive factor. EMBO J 12, 20052015.Google Scholar
50. Matthews, JR, Wakasugi, N, Virelizier, JL, et al. (1992) Thioredoxin regulates the DNA binding activity of NF-κB by reduction of a disulphide bond involving cysteine 62. Nucleic Acids Res 20, 38213830.CrossRefGoogle ScholarPubMed
51. Hirota, K, Murata, M, Sachi, Y, et al. (1999) Distinct roles of thioredoxin in the cytoplasm and in the nucleus: a two-step mechanism of redox regulation of transcription factor NF-κB. J Biol Chem 274, 2789127897.CrossRefGoogle ScholarPubMed
52. Schmitz, G & Ecker, J (2008) The opposing effects of n-3 and n-6 fatty acids. Prog Lipid Res 47, 147155.CrossRefGoogle ScholarPubMed
53. Roberts, LJ II & Morrow, JD (2000) Measurement of F2-isoprostanes as an index of oxidative stress in vivo . Free Radic Biol Med 28, 505513.Google Scholar
54. Lakshmi, S, Padmaja, G, Kuppusamy, P, et al. (2009) Oxidative stress in cardiovascular disease. Indian J Biochem Biophys 46, 421440.Google Scholar
55. Spiteller, P & Spiteller, G (1997) 9-Hydroxy-10,12-octadecadienoic acid (9-HODE) and 13-hydroxy-9,11-octadecadienoic acid (13-HODE): excellent markers for lipid peroxidation. Chem Phys Lipids 89, 131139.Google Scholar
56. Xie, WL, Chipman, JG, Robertson, DL, et al. (1991) Expression of a mitogen-responsive gene encoding prostaglandin synthase is regulated by mRNA splicing. Proc Natl Acad Sci U S A 88, 26922696.CrossRefGoogle ScholarPubMed
57. Kurumbail, RG, Kiefer, JR & Marnett, LJ (2001) Cyclooxygenase enzymes: catalysis and inhibition. Curr Opin Struct Biol 11, 752760.CrossRefGoogle ScholarPubMed
58. Dubois, RN, Abramson, SB, Crofford, L, et al. (1998) Cyclooxygenase in biology and disease. FASEB J 12, 10631073.Google Scholar
59. Kuhn, H & Thiele, BJ (1999) The diversity of the lipoxygenase family: many sequence data but little information on biological significance. FEBS Lett 449, 711.Google Scholar
60. Chiang, N, Arita, M & Serhan, CN (2005) Anti-inflammatory circuitry: lipoxin, aspirin-triggered lipoxins and their receptor ALX. Prostaglandins Leukot Essent Fatty Acids 73, 163177.Google Scholar
61. Kuhn, H & O'Donnell, VB (2006) Inflammation and immune regulation by 12/15-lipoxygenases. Prog Lipid Res 45, 334356.Google Scholar
62. Yuan, ZX, Rapoport, SI, Soldin, SJ, et al. (2013) Identification and profiling of targeted oxidized linoleic acid metabolites in rat plasma by quadrupole time-of-flight mass spectrometry. Biomed Chromatogr 27, 422432.CrossRefGoogle ScholarPubMed
63. Oh, SF, Dona, M, Fredman, G, et al. (2012) Resolvin E2 formation and impact in inflammation resolution. J Immunol 188, 45274534.Google Scholar
64. Merched, AJ, Ko, K, Gotlinger, KH, et al. (2008) Atherosclerosis: evidence for impairment of resolution of vascular inflammation governed by specific lipid mediators. FASEB J 22, 35953606.Google Scholar
65. Serhan, CN & Savill, J (2005) Resolution of inflammation: the beginning programs the end. Nat Immunol 6, 11911197.Google Scholar
66. Arnaud, J, Bost, M, Vitoux, D, et al. (2007) Effect of low dose antioxidant vitamin and trace element supplementation on the urinary concentrations of thromboxane and prostacyclin metabolites. J Am Coll Nutr 26, 405411.CrossRefGoogle ScholarPubMed
67. Meydani, M (1992) Modulation of the platelet thromboxane A2 and aortic prostacyclin synthesis by dietary selenium and vitamin E. Biol Trace Elem Res 33, 7986.Google Scholar
68. Haberland, A, Neubert, K, Kruse, I, et al. (2001) Consequences of long-term selenium-deficient diet on the prostacyclin and thromboxane release from rat aorta. Biol Trace Elem Res 81, 7178.Google Scholar
69. Maddox, JF, Reddy, CC, Eberhart, RJ, et al. (1991) Dietary selenium effects on milk eicosanoid concentration in dairy cows during coliform mastitis. Prostaglandins 42, 369378.Google Scholar
70. Gandhi, UH, Kaushal, N, Ravindra, KC, et al. (2011) Selenoprotein-dependent upregulation of hematopoietic prostaglandin D2 synthase in macrophages is mediated through the activation of peroxisome proliferator-activated receptor (PPAR)γ. J Biol Chem 286, 2747127482.Google Scholar
71. Imai, H, Narashima, K, Arai, M, et al. (1998) Suppression of leukotriene formation in RBL-2H3 cells that overexpressed phospholipid hydroperoxide glutathione peroxidase. J Biol Chem 273, 19901997.Google Scholar
72. Schnurr, K, Belkner, J, Ursini, F, et al. (1996) The selenoenzyme phospholipid hydroperoxide glutathione peroxidase controls the activity of the 15-lipoxygenase with complex substrates and preserves the specificity of the oxygenation products. J Biol Chem 271, 46534658.Google Scholar
73. Walther, M, Holzhutter, H-G, Kuban, RJ, et al. (1999) The inhibition of mammalian 15-lipoxygenases by the anti-inflammatory drug ebselen: dual-type mechanism involving covalent linkage and alteration of the iron ligand sphere. Mol Pharmacol 56, 196203.Google Scholar
74. Marnett, LJ, Rowlinson, SW, Goodwin, DC, et al. (1999) Arachidonic acid oxygenation by COX-1 and COX-2. J Biol Chem 274, 2290322906.Google Scholar
75. Cook, H & Lands, WEM (1976) Mechanism for suppression of cellular biosynthesis of prostaglandins. Nature 260, 630632.Google Scholar
76. Smith, WL & Lands, WEM (1972) Oxygenation of polyunsaturated fatty acids during prostaglandin biosynthesis by sheep vesicular glands. Biochemistry 11, 32763285.Google Scholar
77. Wade, ML, Voelkel, NF & Fitzpatrick, FA (1995) “Suicide” inactivation of prostaglandin I2 synthase: characterization of mechanism-based inactivation with isolated enzyme and endothelial cells. Arch Biochem Biophys 321, 453458.Google Scholar
78. Jones, DA & Fitzpatrick, FA (1990) “Suicide” inactivation of thromboxane A2 synthase. Characteristics of mechanism-based inactivation with isolated enzyme and intact platelets. J Biol Chem 265, 2016620171.Google Scholar
79. Hampel, G, Watanabe, K, Weksler, BB, et al. (1989) Selenium deficiency inhibits prostacyclin release and enhances production of platelet activating factor by human endothelial cells. Biochim Biophys Acta 1006, 151158.Google Scholar
80. Hwang, J-T, Kim, YM, Surh, Y-J, et al. (2006) Selenium regulates cyclooxygenase-2 and extracellular signal-regulated kinase signaling pathways by activating AMP-activated protein kinase in colon cancer cells. Cancer Res 66, 1005710063.CrossRefGoogle ScholarPubMed
81. Pei, Z, Li, H, Guo, Y, et al. (2010) Sodium selenite inhibits the expression of VEGF, TGFβ1 and IL-6 induced by LPS in human PC3 cells via TLR4-NF-KB signaling blockage. Int Immunopharmacol 10, 5056.Google Scholar
82. Coussens, LM, Zitvogel, L & Palucka, AK (2013) Neutralizing tumor-promoting chronic inflammation: a magic bullet? Science 339, 286291.CrossRefGoogle ScholarPubMed
83. Sheng, H, Shao, J, Morrow, JD, et al. (1998) Modulation of apoptosis and Bcl-2 expression by prostaglandin E2 in human colon cancer cells. Cancer Res 58, 362366.Google Scholar
84. Avis, I, Hong, SH, Martínez, A, et al. (2001) Five-lipoxygenase inhibitors can mediate apoptosis in human breast cancer cell lines through complex eicosanoid interactions. FASEB J 15, 20072009.Google Scholar
85. Ghosh, J (2004) Rapid induction of apoptosis in prostate cancer cells by selenium: reversal by metabolites of arachidonate 5-lipoxygenase. Biochem Biophys Res Commun 315, 624635.Google Scholar
86. Heirman, I, Ginneberge, D, Brigelius-Flohé, R, et al. (2006) Blocking tumor cell eicosanoid synthesis by GPx4 impedes tumor growth and malignancy. Free Radic Biol Med 40, 285294.Google Scholar
87. Quinn, MT, Parthasarathy, S, Fong, LG, et al. (1987) Oxidatively modified low density lipoproteins: a potential role in recruitment and retention of monocyte/macrophages during atherogenesis. Proc Natl Acad Sci U S A 84, 29952998.Google Scholar
88. Lewis, P, Stefanovic, N, Pete, J, et al. (2007) Lack of the antioxidant enzyme glutathione peroxidase-1 accelerates atherosclerosis in diabetic apolipoprotein E-deficient mice. Circulation 115, 21782187.Google Scholar
89. Panicker, S, Swathy, S & John, F (2012) Impact of selenium on the leukotriene B4 synthesis pathway during isoproterenol-induced myocardial infarction in experimental rats. Inflammation 35, 7480.Google Scholar
90. Shrimali, RK, Weaver, JA, Miller, GF, et al. (2007) Selenoprotein expression is essential in endothelial cell development and cardiac muscle function. Neuromuscul Disord 17, 135142.Google Scholar
91. Cao, Y-Z, Reddy, CC & Sordillo, LM (2000) Altered eicosanoid biosynthesis in selenium-deficient endothelial cells. Free Radic Biol Med 28, 381389.Google Scholar
92. Sordillo, LM, Streicher, KL, Mullarky, IK, et al. (2008) Selenium inhibits 15-hydroperoxyoctadecadienoic acid-induced intracellular adhesion molecule expression in aortic endothelial cells. Free Radic Biol Med 44, 3443.CrossRefGoogle ScholarPubMed
93. Sordillo, LM, Weaver, JA, Cao, Y-Z, et al. (2005) Enhanced 15-HPETE production during oxidant stress induces apoptosis of endothelial cells. Prostaglandins Other Lipid Mediat 76, 1934.Google Scholar
94. Weaver, JA, Maddox, JF, Cao, YZ, et al. (2001) Increased 15-HPETE production decreases prostacyclin synthase activity during oxidant stress in aortic endothelial cells. Free Radic Biol Med 30, 299308.Google Scholar
95. Rydberg, EK, Krettek, A, Ullström, C, et al. (2004) Hypoxia increases LDL oxidation and expression of 15-lipoxygenase-2 in human macrophages. Arterioscler Thromb Vasc Biol 24, 20402045.Google Scholar
96. Takahashi, K, Takeya, M & Sakashita, N (2002) Multifunctional roles of macrophages in the development and progression of atherosclerosis in humans and experimental animals. Med Electron Microsc 35, 179203.CrossRefGoogle ScholarPubMed
97. Cao, Y-Z, Weaver, JA, Chana Reddy, C, et al. (2002) Selenium deficiency alters the formation of eicosanoids and signal transduction in rat lymphocytes. Prostaglandins Other Lipid Mediat 70, 131143.Google Scholar
98. Carlson, B, Yoo, M-H, Sano, Y, et al. (2009) Selenoproteins regulate macrophage invasiveness and extracellular matrix-related gene expression. BMC Immunol 10, 57.Google Scholar
99. Prabhu, KS, Zamamiri-Davis, F, Stewart, JB, et al. (2002) Selenium deficiency increases the expression of inducible nitric oxide synthase in RAW 264.7 macrophages: role of nuclear factor-κB in up-regulation. Biochem J 366, 203209.Google Scholar
100. Zamamiri-Davis, F, Lu, Y, Thompson, JT, et al. (2002) Nuclear factor-κB mediates over-expression of cyclooxygenase-2 during activation of RAW 264.7 macrophages in selenium deficiency. Free Radic Biol Med 32, 890897.Google Scholar
101. Youn, H-S, Lim, HJ, Choi, YJ, et al. (2008) Selenium suppresses the activation of transcription factor NF-κB and IRF3 induced by TLR3 or TLR4 agonists. Int Immunopharmacol 8, 495501.Google Scholar
102. Nam, KN, Koketsu, M & Lee, EH (2008) 5-Chloroacetyl-2-amino-1,3-selenazoles attenuate microglial inflammatory responses through NF-κB inhibition. Eur J Pharmacol 589, 5357.Google Scholar
103. Serhan, CN & Chiang, N (2008) Endogenous pro-resolving and anti-inflammatory lipid mediators: a new pharmacologic genus. Br J Pharmacol 153, Suppl. 1, S200S215.CrossRefGoogle ScholarPubMed
104. Heras, IL, Palomo, M & Madrid, Y (2011) Selenoproteins: the key factor in selenium essentiality. State of the art analytical techniques for selenoprotein studies. Anal Bioanal Chem 400, 17171727.CrossRefGoogle Scholar
105. Kryukov, GV, Castellano, S, Novoselov, SV, et al. (2003) Characterization of mammalian selenoproteomes. Science 300, 14391443.Google Scholar
Figure 0

Fig. 1. Selenium metabolism from different dietary sources. Dietary intake sources of selenium include the inorganic selenate and selenite (depicted in the green stars), whereas organic sources (depicted in the red stars) are obtained from animal and plant sources that provide selenium in the form of selenocysteine (Sec), selenomethionine and selenium-methylselenocysteine (Se-methyl-Sec). Inorganic forms of selenium are reduced by thioredoxin reductase (TrxR) and thioredoxin (Trx) or converted to selenodiglutathione (GS-Se-SG) by glutathione disulfide (GSSG), reduced by glutathione reductase to glutathioselenol (GS-SeH), then converted to hydrogen selenide (H2Se) in a reaction with GSSG. Selenoproteins are broken down by lyases to form H2Se in intestinal enterocytes. H2Se can then be converted into selenophosphate by selenophosphate synthase and Sec by selenocysteine synthase for incorporation of Sec into selenoproteins. H2Se can also be converted into methylated metabolites by methyltransferases which are primarily excreted through exhalation, urine and faeces. GSH, glutathione.

Figure 1

Fig. 2. General reaction mechanisms for antioxidant glutathione peroxidase (GPx) and thioredoxin reductase (TrxR). (a) GPx catalyses the chemical reduction of lipid peroxides or H2O2 to respective alcohols and water by glutathione (GSH) which forms glutathione disulfide (GSSG). Glutathione reductase catalyses the reduction of GSSG back to GSH in the presence of NADPH. (b) Oxidised protein disulfides and other free radicals are reduced to their corresponding thiols by thioredoxin (Trx). TrxR then catalyses the reduction of oxidised Trx in the presence of NADPH.

Figure 2

Table 1. Summary of mammalian selenoproteins with characterised functions*

Figure 3

Fig. 3. Selenium's potential impact on the regulation of inflammation. Some of the several ways in which inflammation is mediated through selenoproteins include modifying cellular redox tone which has implications on signalling through the NF-κB, mitogen-activated protein kinase (MAPK) and PPARγ pathways, controlling the expression of inflammatory mediators such as cytokines, chemokines, and cyclo-oxygenase (COX) and lipoxygenase (LOX) enzymes. Selenoproteins also combat oxidative stress which could potentially make an impact on COX/LOX enzyme activity and the production of lipid peroxides oxidised non-enzymically by free radicals. Non-enzymic lipid oxidation, COX/LOX expression and COX/LOX activity have been shown to regulate eicosanoid biosynthesis. Selenium has been studied in the context of each of these regulators and the present review focuses specifically on selenium's impact on eicosanoid biosynthesis. ROS, reactive oxygen species.

Figure 4

Fig. 4. Eicosanoid biosynthesis pathways. n-3 and n-6 Fatty acids are released from the cellular membrane by phospholipase enzymes. Long-chain PUFA are oxidised either non-enzymically by free radicals or by cyclo-oxygenase-1/2 (COX-1/2), 15-lipoxygenase (15-LOX) and 5-LOX enzymes to produce eicosanoid signalling metabolites. AA, arachidonic acid; AcCOX, aspirin-acetylated cyclo-oxygenase; 15-epi LXA4, 15-epi lipoxin A4; Rv, resolvin; F2-IsoP, PG-like F2 isoprostanes; TX, thromboxane; 15d-PGJ2, 15-deoxy-Δ12,14PGJ2; LA, linoleic acid; HPETE, hydroperoxyeicosatetraenoic acid; 15-oxoETE, 15-oxo-eicosatetraenoic acid; HETE, hydroxy-eicosatetraenoic acid; MaR1, maresin; PD, protectin; HODE, hydroxy-octadecadienoic acid; 5-oxoETE, 5-oxo-eicosatetraenoic acid; LT, leukotriene.

Figure 5

Fig. 5. Proposed interactions of selenium with eicosanoid biosynthesis pathways. (a) Selenium and selenoproteins interfere with eicosanoid feedback loops. While glutathione peroxidase (GPx)-1 and -4 can reduce fatty acid hydroperoxides (FAHP) to decrease cyclo-oxygenase-2 (COX-2) activity, a buildup of FAHP, when GPx activity is lacking, can also inhibit COX-2. GPx-2 and -4 diminish PGE2-dependent expression of COX-2. Selenium enhances 15-deoxy-Δ12,14PGJ2 (15d-PGJ2) production which is a ligand for PPARγ. PPARγ signalling enhances haematopoietic PGD2 synthase (H-PGDS), which synthesises PGD2, an upstream metabolite of 15d-PGJ2. AA, arachidonic acid; mPGES-1, microsomal PGE2 synthase-1. (b) Antioxidant selenoproteins can affect different signalling pathways leading to activation of NF-κB and activator protein-1 (AP-1) and expression of COX, lipoxygenase (LOX) and other inflammatory mediators such as TNFα and macrophage chemoattractant protein-1 (MCP-1). GPx can alter the redox state of the myeloid differentiation factor 88 (MyD88) adaptor protein, when MyD88 is denitrosylated by GPx with glutathione (GSH), signalling is enhanced. Reactive oxygen species (ROS)-mediated phosphorylation of inhibitor of κB (IKβ) can be dampened when antioxidant selenoproteins are present to scavenge ROS. The mitogen-activated protein kinases (MAPK) can also be affected; ROS-mediated oxidation of thioredoxin (Trx) causes its dissociation from apoptosis signal-regulating kinase 1 (ASK-1), enhancing signalling activity. In the nucleus, Trx can reduce oxidised cysteine residues on NF-κB, enhancing DNA binding and transcription. TLR4, toll-like receptor; TrxR, thioredoxin reductase; IKK, IκB kinase; Trx(SS), oxidised Trx; JNK, c-Jun N-terminal protein kinase.

Figure 6

Table 2. The impact of selenium and selenoproteins on eicosanoid biosynthesis