Abstract
Reactive oxygen and nitrogen species can be generated endogenously (by mitochondria, peroxisomes, and phagocytic cells) and exogenously (by pollutions, UV exposure, xenobiotic compounds, and cigarette smoke). The negative effects of free radicals are neutralized by antioxidant molecules synthesized in our body, like glutathione, uric acid, or ubiquinone, and those obtained from the diet, such as vitamins C, E, and A, and flavonoids. Different microelements like selenium and zinc have no antioxidant action themselves but are required for the activity of many antioxidant enzymes. Furthermore, circulating blood proteins are suggested to account for more than 50% of the combined antioxidant effects of urate, ascorbate, and vitamin E. Antioxidants together constitute a mutually supportive defense against reactive oxygen and nitrogen species to maintain the oxidant/antioxidant balance. This article outlines the oxidative and anti-oxidative molecules involved in the pathogenesis of chronic obstructive lung disease. The role of albumin and alpha-1 antitrypsin in antioxidant defense is also discussed.
Keywords: inflammation, alpha-1 antitrypsin, oxidative stress, reactive oxygen species, antioxidants, lung disease
Reactive Oxygen Species
Cellular respiration consists of 3 main processes—glycolysis, the citric acid cycle, and oxidative phosphorylation—which require free oxygen. The conversion of oxygen (O2) into cellular energy involves its reduction to H2O by accepting 4 electrons. Oxygen by itself has low reactivity; however, it can undergo a series of one electron reductions and produce reactive intermediates. Approximately 5% of the inhaled O2 is converted to reactive oxygen molecules with an unpaired number of electrons such as hydroxyl (OH·), superoxide anion (O2-·), hydrogen peroxide (H2O2), oxygen singlet (O2), hypochlorite (OCI-), nitric oxide (NO), and peroxynitrite (ONOO-) radicals.1 The external sources of reactive oxygen species (ROS) are cigarette smoke, environmental pollutants, radiation, certain drugs, pesticides, industrial solvents, and ozone. The endogenous sources of oxidants include cellular systems localized on the plasma membrane, in the cytosol, in the peroxisomes, and on membranes of mitochondria and endoplasmic reticulum.2 The main sources of cellular ROS are mitochondria and nicotinamide adenine dinucleotide phosphate (NADPH) oxidases, and peroxisomes containing xanthine oxidase and the inducible form of nitric oxide synthase, which produce superoxide anion and nitric oxide, respectively.3 In addition, the activation of phagocyte heme peroxidases, like myeloperoxidase, results in the formation of the potent oxidants. Cellular thiols, hydroquinones and catecholamines can undergo redox reactions and contribute to intracellular ROS production as well. Pathogens, such as Pseudomonas aeruginosa that release pyocyanin, a nitrogen-containing aromatic compound, can also increase intracellular levels of superoxide and hydrogen peroxide.4
The chemically reactive radicals are generated internally by oxidant enzymes, phagocytic cells, arachidonate pathways, and exercise. Low levels of ROS play essential roles in microbe killing and act as secondary messengers for intracellular signaling pathways involved in host immune responses.5,6 For example, free radicals play a role in detoxification of xenobiotics by oxidizing enzymes, in killing of microorganisms by macrophages and cytotoxic lymphocytes, and in the generation of prostaglandins and leukotrienes, which activate oxygenases (e.g., cyclooxygenases and lipoxygenase) and thus act as modulators of the inflammatory response.
Among the ROS, hydroxyl is the most reactive radical, which reacts with lipids, proteins, nucleic acids, and carbohydrates. The hydroxyl radical induces the formation of DNA-protein cross-links, single- and double-stranded breaks, lipid peroxidation, and protein fragmentation.7 For example, polyunsaturated fatty acids are among the most susceptible targets of hydroxyl radicals.8
Nitric oxide (NO·) normally activates soluble guanylate cyclase, to act as a neurotransmitter and blood pressure regulator. Nitric oxide also plays a role in iron trafficking because it mimics the consequences of iron starvation and triggers iron uptake by cells.9 During pathological states, reaction between nitric oxide and superoxide can generate highly reactive peroxynitrite (ONOO-) radicals, which are implicated in lipid peroxidation. Another damaging nitrogen radical, nitrogen dioxide (NO2), is formed during atmospheric dioxide pollution and cigarette smoking.10 NO and its by-products, such as nitrate (NO3-), nitrite (NO2-), peroxynitrite (ONOO-), and 3-nitrotyrosine are called reactive nitrogen species (RNS). The RNS play a role in cellular signaling, vasodilatation, and immune response.11
Chronic Obstructive Pulmonary Disease and Reactive Oxygen Species
Lungs are particularly vulnerable to oxidative stress due to the high oxygen environment and exposure to environmental pathogens and oxidants. For example, a single puff of cigarette smoke estimated to have about 1 × 1015 oxidant molecules.12 Smoking and air pollution are the most significant risk factors for chronic obstructive pulmonary disease (COPD) development, which attribute to oxidative and carbonyl stress.13 The increased burden of reactive oxidants in patients with COPD also derives from leukocytes and macrophages involved in the inflammatory process in the lungs.14 The ROS and RNS can cause oxidative damage to DNA, lipids, carbohydrates and proteins, and thereby mediate an array of downstream processes that contribute to the development and progression of COPD. They also activate resident cells in the lung, particularly epithelial cells and alveolar macrophages, to generate chemotactic molecules that recruit neutrophils, monocytes and lymphocytes into the lung.15 Collectively, these events lead to a vicious cycle of persistent inflammation and chronic oxidative stress, which results in protease-anti-protease imbalance, defects in tissue repair mechanisms, accelerated apoptosis in lung cells and progression of COPD.16
Dysregulated mitochondrial ROS production is a feature of smokers with COPD17,18 that is not limited to the lungs. For example, Belchamber et al reported mitochondrial dysfunction in COPD macrophages.19 Other studies found that mitochondrial-targeted antioxidant treatment reduces proliferation and cytokine production of airway smooth muscle cells of patients with COPD.20 Oxidative stress involved in pathogenesis of COPD is not just the result of increased burden of oxidants but also a decreased anti-oxidative potential.21
Antioxidants and Oxidative Stress
To protect human cells and organ systems against free radicals, a complex antioxidant system exists. Dietary and endogenous enzymatic and nonenzymatic antioxidants counteract the damaging effects of free radicals by various mechanisms, such as electron donation, catalytic removal, or binding radicals and/or gene expression regulation.22 Together, antioxidants constitute an integrated defense against ROS (Figure 1). Only when the production of free radicals overwhelms the antioxidant defense and the oxidant/antioxidant imbalance shifts in favor of oxidants, does oxidative stress develop.
Oxidative stress is a part of many acute and chronic pathological processes in respiratory, cardiovascular, kidney, neurodegenerative, and biliary diseases, as well as in cancer. Oxidative stress is also associated with cellular senescence and aging.23 Age-related oxidative stress affects the nervous, endocrine, and immune systems and may create a vicious cycle involving chronic oxidative stress and inflammation, which support each other, and increase age-related morbidity and mortality.24
Dietary Antioxidants
Vitamins and Minerals
Fruits and vegetables contain antioxidant vitamins, including vitamin C, vitamin E, and pro-vitamin A carotenoids, activities of which have been well-studied. Antioxidant vitamins are present on the cell membrane, intracellularly, or extracellularly, and react with free radicals to either remove or inhibit them.25 Vitamin E is the major peroxyl radical scavenger,26 whereas carotenoids quench singlet oxygen and inhibit lipid peroxidation.27 Vitamin C acts as a ROS scavenger and thus can rescue vitamin E, which is anchored in the cell membrane and prevents lipid peroxidation.28,29 Koike et al reported that treatment with vitamin C prevented cigarette smoke-induced emphysema and restored lung tissue damage in protein-30 knockout (SMP30-KO) mice characterized by accelerated aging.30
Selenium, copper, manganese, and zinc are considered antioxidant minerals because they are required for the activity of antioxidant enzymes. For example, selenium is required for the activity of glutathione peroxidases, which are scavengers of hydrogen peroxide in subcellular compartments.31 Notably, lower levels of serum selenium were reported in an elderly Swedish population relative to other European regions. Furthermore, people in the lowest selenium quartile (< 57.2 μg/L) were found to have an increased mortality, suggesting the value of selenium supplementation.32
Zinc acts as a cofactor for enzymes of the antioxidant system, and inhibits the enzyme, nicotinamide adenine dinucleotide phosphate oxidase, a prooxidant enzyme, and induces metallothionein synthesis, which is important in the reduction of hydroxyl radicals.33
Manganese (Mn) is one of the required components for Mn superoxide dismutase (MnSOD), which is responsible for scavenging ROS during mitochondrial oxidative stress. In addition, Mn is involved in the synthesis and activation of many enzymes and in the regulation of glucose and lipid metabolism.34 It is important to note that the antioxidant properties of Mn are outcompeted by cellular iron binding to MnSOD, so iron may counteract the benefits of manganese antioxidants.35 Because a number of bacterial proteins are Mn dependent, host-mediated Mn sequestration has the potential to disrupt bacterial pathogenesis.36
The Effects of Dietary Vitamins and Minerals on Lung Function
Numerous experimental and epidemiological studies have supported the importance of vitamins and antioxidants in the prevention of inflammatory diseases, including COPD. Data from the cross-sectional MORGEN study, (the monitoring project on risk factors and health in the Netherlands) in a sample of 6555 adults in the Dutch population, showed that the intake of vitamin C and beta-carotene, but not vitamin E, had a positive effect on lung function, but had no effect on respiratory symptoms.37 A prospective cohort study in the United Kingdom confirmed that a high dietary intake of vitamin C or foods rich in this vitamin reduced the rate of lung function loss and thereby prevented development of COPD.38 Another 3-year study showed an improvement in lung function in a group of COPD patients consuming higher amounts of fruits and vegetables.39 In a similar manner, a study based on a random sample of adults from 3 European countries concluded that the intake of fruits, and particularly tomatoes, delayed declines in lung function.40 Tomatoes are very rich sources of lycopene, a carotenoid without vitamin A activity,41 which is believed to be responsible for the observed beneficial effects of tomatoes.
Broccoli is a vegetable having a high content of bioactive phytochemicals, such as glucosinolates, phenolic compounds, vitamin C, and minerals.42 For example, extract of sulforaphane, a sulfur-rich compound found in broccoli, has been shown to increase nuclear factor erythroid-2-related factor 2 (Nrf2) and its regulated antioxidants in upper airways, and to improve the ability of macrophages to remove bacteria.43 Several studies reported that Nrf2 and its transcriptional activity decline with increasing COPD severity44-46 allowing for the hypothesis that sulforaphane may decrease oxidative stress and inflammation in COPD patients. To test this hypothesis, the randomized, placebo-controlled clinical trial of sulforaphane supplementation in patients with COPD for four weeks at doses of 25 and 150 μM was initiated. Unfortunately, this therapy had no effect on the expression of Nrf2, and other antioxidants or markers of inflammation.47
Chalcones (1,2-diphenyl-2-propen-1-one) belonging to the flavonoid family, such as isoliquiritigenin (licorice roots) and xanthohumol (hops), have been shown to decrease pulmonary inflammation caused by lipopolysaccharide (LPS).48 However, no studies have been reported in COPD patients.
It is also important to mention, that the Beta-Carotene and Retinol Efficacy Trial (CARET) tested daily intake of the combination of 30 mg beta-carotene and 25,000 IU vitamin A against placebo in 18,314 men and women. However, the CARET trial was terminated because of substantial evidence of harm; there were 28% more lung cancers and 17% more deaths in the active intervention group.49 On the other hand, a population-based cross-sectional study including 21,148 Korean adults showed that participants with the highest intake of vitamin A, beta-carotene, and vitamin C had a significantly higher forced expiratory volume in 1 second (FEV1) than those with the lowest intake.50
A number of studies suggest that levels of specific microelements like selenium, manganese, and zinc are altered in patients with COPD.51-53 For example, some studies have shown that there is no effect of selenium on COPD,54 although other studies reported that selenium had therapeutic benefits. Indeed, COPD patients with acute upper respiratory tract infections receiving selenium with zinc, vitamin C, and Echinacea Purpurea showed less severe and shorter exacerbation episodes when compared with the placebo group.55 According to another study, intravenous administration of selenium with zinc and manganese significantly reduced the time COPD patients spent on mechanical ventilation.53 Likewise, a study based on data from 18,162 individuals has shown a direct relationship between serum levels of selenium and FEV1 in smokers.56
Taken together, the above-mentioned studies suggested that a high intake of fruits and vegetables rich in antioxidants is beneficial for the respiratory system and favorable for patients with COPD. However, future prospective randomized, controlled trials are needed to explore the role of natural bioactive compounds as well as their supplements on health status, lung function and risk of COPD development.
Endogenous Antioxidants
All cells contain antioxidant systems that specifically detoxify superoxide or hydrogen peroxide or contribute to the defense against ROS (Figure 2). Many antioxidant responses are controlled by the Nrf2, an evolutionary conserved transcription factor that is sequestered under basal conditions but upregulated acutely during oxidant attack. When activated, Nrf2 disassociates from its repressor protein KEAP1 that reacts with oxidative radicals, translocates to the nucleus, binds to antioxidant response element and induces the transcription of defensive genes. As mentioned above, decreased Nrf2 expression and protein levels, and concomitantly, a lower activity of antioxidant defense, are found in tissues from COPD patients.
Enzymatic Antioxidants
Enzymatic antioxidants function by converting oxidized metabolic products in a multi-step process to hydrogen peroxide and then to water using cofactors such as iron, zinc, copper, and manganese. Hydrogen peroxide may also be converted to the potent oxidant hypochlorous acid in the presence of the chloride ion. This transformation is catalyzed by myeloperoxidase (Figure 2).
Myeloperoxidase
Myeloperoxidase (MPO) is an iron-containing enzyme with antimicrobial activity carried by neutrophil azurophilic granules. Among the antimicrobial agents, MPO is the most abundant and constitutes about 25% of the azurophilic granular proteins.6 MPO uses peroxide as a substrate via peroxidation or chlorination reaction to produce hypochloric acid and other toxic substances that can kill different types of pathogens. Individuals deficient in MPO have an increased risk of infections and inflammatory diseases.57 Despite the beneficial anti-inflammatory effects of MPO, its excessive activity may cause protein nitrosylation, lipid peroxidation and tissue damage.58,59 In fact, levels of MPO in sputum and bronchoalveolar lavage are much greater in COPD patients than in controls.60,61 Moreover, MPO levels are elevated during exacerbations of COPD.62-64
The inhibition of MPO has been studied in a cigarette smoke-induced emphysema model, in guinea pigs. Animals treated with the MPO inhibitor showed protection against morphologic changes characteristic of emphysema.65 However, the potential consequences of chronic MPO inhibition in patients with COPD are unknown.
Superoxide Dismutases
Superoxide dismutases (SODs) are universal enzymes of aerobic organisms, which control the levels of reactive oxygen and nitrogen species by catalyzing the dismutation of superoxide to hydrogen peroxide and oxygen. Three isoforms of SOD exist: cytoplasmic Cu-ZnSOD (SOD1), mitochondrial MnSOD (SOD2), and extracellular Cu-ZnSOD3. The presence of specific SOD isoforms supports the importance of maintaining redox homeostasis between cellular compartments. The changes in SOD activity in a particular compartment may lead to the generation of a hydrogen peroxide concentration gradient and the subsequent activation of redox sensitive pathways.66
SOD1 is constitutively expressed and it is abundant in bronchial and alveolar epithelial cells, fibroblasts, and capillary endothelial cells.67 In contrast to SOD1, SOD2 is inducible by oxidative stress, hyperoxia, environmental pollutants such as cigarette smoke or ozone, and by inflammatory cytokines. Similar to SOD1, SOD2 expression is lower in lung tissue compared to other major organs; its expression is the highest in alveolar type II cells.68
Because SOD3 modulates O2·- levels in the vasculature, this SOD is linked to pathological conditions involving vascular dysfunctions. Polymorphisms in the SOD3 gene have been linked to type 2 diabetes, ischemic heart disease, acute lung injury and COPD.69 Through a direct binding property, SOD3 protects hyaluronic acid against oxidative fragmentation in models of asbestos-induced lung injury and cigarette smoke-induced emphysema.70,71 Moreover, experimental data have shown that SOD3 modulates neutrophil recruitment and function.72
Superoxide dismutase is also known to help carry NO into hair follicles. While the NO relaxes the blood vessels and allows more blood to circulate to the hair follicles, SOD helps to remove the free radicals. This is beneficial for people who are experiencing premature hair loss.73
Catalase
Catalase is a heme moiety-containing enzyme located in peroxisomes and responsible for the conversion of hydrogen peroxide molecules to oxygen and water. It is an extremely efficient enzyme because one catalase molecule can convert millions of hydrogen peroxide molecules each second.74 Because of this property, catalase is used in facial mask treatments combining catalase with hydrogen peroxide with the intent of increasing cellular oxygenation in the upper layers of the facial epidermis. This treatment is expected to lower oxidative stress, DNA damage, malignant transformation, and to protect against age-associated skin oxidative damage.75
In the lungs, catalase is expressed during the later stages of development and becomes constitutively expressed in airway and alveolar epithelial cells.76 A decrease in catalase activity is observed in patients with asthma77 and in smokers with COPD.78 The overall biological role of catalase in pulmonary diseases remains unclear. For example, some studies suggest that inhibition of catalase might be a beneficial therapy for acute lung injury because this would preserve an effect of hydrogen peroxide on neutrophil phagocytic ability.79
Glutathione Peroxidases
The family of glutathione peroxidases (GPXs) consists of 8 isoforms, and 4 of these are expressed in the lung. The GPXs mediate the same reaction as catalase, namely, the recycling of hydrogen peroxide into water. However, these 2 enzymes have specific characteristics. As previously mentioned, catalase is an enzyme located in peroxisomes, and is activated when cellular peroxide concentrations exceed physiological levels. In contrast, the GPXs are involved in the physiological adjustment of peroxide concentrations in the intracellular and extracellular compartments, and are more versatile, so they can also act as scavengers and as repair enzymes. In addition, peroxide GPXs can also recycle peroxidized free polyunsaturated fatty acids and phospholipid hydroperoxides.80
It has been assumed that GPX1 is responsible for approximately 95% of the overall GPX activity in lung tissue.81 GPX1 deficient mice develop normally but are more susceptible to lung inflammation by influenza infection or cigarette smoke exposure.82,83 GPX1 is shown to promote proinflammatory cytokine production and neutrophilia in response to endotoxin,84 and to contribute to the development of ovalbumin-induced allergic asthma.85
GPX2 is poorly expressed in healthy lungs, whereas GPX2 markedly increases in the airway epithelium in response to cigarette smoke exposure and inflammation.86,87 GPX3 was first identified in plasma and was found to be expressed by bronchial epithelial cells and alveolar macrophages.88,89 Different studies support a major role of GPX3 in extracellular antioxidant defense within the airway lumen. GPX4 is also known as phospholipid hydroperoxide and exists as cytosolic, mitochondrial, and nuclear isoforms.90 GPX4 is primarily involved in oxidative lipid metabolism,91 although the role of GPX4 in lung pathophysiology remains unclear.
A study by Vibhuti et al reported reduced levels of glutathione and low activities of catalase and GXP in COPD patients.92 However, this observation remains to be replicated by other studies.
Peroxiredoxins
Peroxiredoxins (Prxs) comprise a family of 6 mammalian cysteine-dependent peroxidase enzymes that are major regulators of the cellular redox environment, and impact protein cysteine oxidation. Over the past years, Prxs have become recognized not only as oxidative stress defense enzymes but also as regulators of phospholipid homeostasis.93,94 Despite the knowledge that redox perturbations accompany pulmonary diseases like cancer, pulmonary fibrosis, and acute lung injury, little is known about the role of Prxs in the etiology of these diseases.95
Endogenous Nonenzymatic Antioxidants
The nonenzymatic antioxidants are characterized by their ability to intercept and terminate free radical chain reactions, and inactivate radicals and oxidants.96 The major endogenous nonenzymatic low-molecular-mass antioxidants include N-acetylcysteine, glutathione, uric acid, melatonin, coenzyme Q and others. Among contributors to the antioxidant defense system are also human blood proteins like albumin, ferritin, transferrin, haptoglobin and ceruloplasmin. For example, ceruloplasmin is a copper-containing ferroxidase that possesses ferroxidase and antioxidant activity and inhibits iron-and copper-dependent lipid peroxidation and scavenging peroxide and superoxide anions.97 Moreover, ceruloplasmin is a physiologic inhibitor of MPO,98 a neutrophil enzyme that promotes oxidative stress in COPD. The antioxidant properties of serum albumin will be discussed in the following chapter.
N-acetylcysteine
N-acetylcysteine (NAC) possesses direct and indirect antioxidant properties. The free thiol group of NAC can directly interact with ROS to form NAC disulphide.99,100 However, as a glutathione precursor, NAC can exert an indirect antioxidant effect.
Both in vitro and in vivo studies have confirmed the protection of the alveolar epithelium from oxygen radical toxicity by treatment with NAC.101 Data on the NAC effects in COPD suggest that NAC reduces elastase activity,99 hinders the loss of pulmonary glutathione, abolishes the effects of cigarette smoke, prevents thickening of the airway wall, and reduces the risk of exacerbations.102 The results of clinical trials support the usefulness of oral administration of NAC, generally 600 mg/day, in chronic bronchitis and COPD patients to prevent exacerbations.103,104 Long-term therapy with NAC may reduce the risk of COPD exacerbation.105 Nevertheless, the available evidence is insufficient to recommend the routine use of NAC for the treatment of stable COPD patients.106 However, because of its antioxidant properties, NAC might be a potential add-on therapy in COPD patients.
Glutathione
Glutathione (GSH) is a low molecular weight thiol tripeptide (γ-glutamyl-cysteinyl-glycine) abundant in almost all cellular compartments (in the nucleus, mitochondria, and cytoplasm). In humans, GSH is present in a high concentration (1-10 mM)107 and it is involved in cell differentiation, senescence and death, detoxification of xenobiotics, regulation of enzymatic activity, and synthesis of proteins and nucleotides.108 As an antioxidant, GSH reduces ROS during the enzymatic and nonenzymatic reactions. It regenerates other oxidized antioxidants like vitamin C and vitamin E, is involved in the repair of peroxidized lipids and in the maintenance of sulfhydryl moieties of proteins in the reduced form. GSH functions in conjunction with 3e groups of enzymes glutathione peroxidase, glutathione reductase, and glutathione oxidase.
GSH homeostasis is regulated by its de novo synthesis but also by recycling and cellular export. The rate-limiting step in the de novo synthesis of the GSH is catalyzed by gamma-glutamyl-cysteine synthetase (also known as glutamine-cysteine ligase), which is a target gene of Nrf2.109 The Nrf2 coordinates the basal and stress-inducible activation of the glutamate-cysteine ligase complex110 and regulates the transcription of glutathione peroxidase 2 and glutathione S-transferases.111
The antioxidant function of GSH is accomplished mainly by GSH peroxidase reactions, which reduce hydrogen peroxide and lipid peroxide.112 When GSH is oxidized, it forms GSH disulphide, which can be reduced again to GSH with the help of glutathione reductases, another Nrf2 targets, in an NADPH-dependent manner.113 Thus, through the coordinated activation of GSH production, utilization, and regeneration, Nrf2 ensures maintenance of the intracellular levels of reduced GSH.114
The key role of GSH as an antioxidant is demonstrated by the experimental depletion of GSH using buthionine sulfoximine, an inhibitor of GSH synthesis. This depletion of GSH results in a worsening effect in many disease models. Conversely, recovering GSH levels with precursors of its synthesis, such as N-acetyl-cysteine or 2-oxothiazolidine-4-carboxylic acid, increase the protective effects.115
Glutathione deficiency is associated with chronic bronchitis, COPD, cystic fibrosis, idiopathic pulmonary fibrosis, bacterial and viral infections, and toxicity of various foreign compounds (smoke, pollutants, and drugs).116 However, clinical studies using GSH as a therapeutic agent have shown mixed results. In the older study, when GSH (600 mg twice daily for 3 days) was given by aerosol to 10 patients with idiopathic pulmonary fibrosis, a rise in epithelial lining fluid GSH and reduced superoxide release from macrophages was detected.117 Noticeably, GSH inhalation is not recommended for lung cancer patients because GSH may reduce cytotoxicity to chemotherapeutic compounds and repair drug-induced injury at the DNA level. For example, GSH was found to detoxify or inactivate platinum drugs, commonly used for the treatment of advanced stage lung cancer patients.116 Moreover, in a trial of 8 asthmatic patients who received nebulized GSH (600 mg with 4 ml of 0.9% sodium chloride) one week apart, adverse effects, such as bronchoconstriction, have occurred. Researchers assumed that this was probably due to the sulphite formation in the nebulized solution and/or the metabolism of GSH into leukotrienes, potent pro-inflammatory bronchoconstrictors.118 Taken together, GSH treatment might be capable of providing antioxidant protection to both the upper and lower respiratory airways however, additional research studies are necessary. So far, GSH is not recommended as a potential treatment for COPD and emphysema patients.119
Coenzyme Q10
Coenzyme Q (CoQ) is a benzoquinone derivative localized in the mitochondrial respiratory chain as well as in other internal membranes. The CoQ provides antioxidant protection to cell membranes and plasma lipoproteins.120
A significant reduction in the rate of CoQ biosynthesis occurs during aging and age-associated diseases.121-124 In patients with COPD, dietary supplementation with CoQ10 seems to improve functional performance and dyspnea.125
A recent meta-analysis summarized the efficacy of CoQ10 in patients with pathologies, in which inflammation is a common factor, like cardio-cerebral vascular disease, multiple sclerosis, obesity, renal failure, rheumatoid arthritis, diabetes, and fatty liver disease.126 Administration of CoQ10 in doses ranging from 60mg–500 mg/day significantly decreased production of inflammatory markers.126 Nevertheless, further experimental studies and clinical trials involving a greater number of participants are needed to definitively assess the benefits of CoQ10 treatment.127
Uric Acid
Uric acid (UA) is an intermediate product of the purine degradation pathway and provides approximately 60% of free radical scavenging capacity in plasma.128 Although the antioxidant effect of UA might have therapeutic benefits, high plasma concentrations of UA have been associated with obesity, insulin resistance, and hyperuricemia.129,130 It is possible that increases in circulating levels of UA reflect a protective response against oxidative stress that is linked to obesity-associated metabolic syndrome. Several studies have indicated a role of UA in exacerbations and lung function, and in the physical capacity of patients with COPD.131,132
Melatonin
Melatonin (N-acetyl-5-methoxytryptamine) is an endogenous hormone derived from tryptophan that is mainly released from the pineal gland in the dark. Melatonin expresses anti-inflammatory and antioxidant properties, and regulates different biological functions such as sleep, circadian rhythm, immunity, reproduction and blood pressure control.133 Melatonin protects lipids, proteins, and nuclear DNA from oxidative damage.134
Melatonin is not only endogenously generated but it is also widely available in fruits and vegetables. Numerous in vivo studies testing high doses of melatonin reported extremely low toxicities.135 Torres et al found that melatonin decreases the levels of oxidative stress markers and increased both enzymatic and nonenzymatic antioxidant capacities in the lung.136 Melatonin is also used to treat sleep disturbances and insomnias caused by aging, as well as pathological conditions including COPD.137
Blood Proteins as Antioxidants
Human blood proteins are vulnerable to oxidative damage because free radicals can cause alterations in the electrical charge of proteins, induce cross-linking of proteins, and increase their susceptibility to proteolysis.138 Proteins that have metals at their active sites are sensitive to metal catalyzed oxidation.139 Oxidation can generate protein hydroperoxides, which generate additional radicals upon interactions with metal ions. Some oxidized proteins become functionally inactive and are rapidly removed; others can gain novel biological activities and thereby contribute to the various pathophysiological processes.140
Specific blood proteins like albumin, ceruloplasmin, metallothionein, ferritin, myoglobin, transferrin, alpha-1-acid glycoprotein, and haptoglobin, may act as antioxidants. It has been proposed that proteins account for more than half of the antioxidant capacity in blood.141
Human Serum Albumin
Human serum albumin (HSA) is the main extracellular protein maintaining the plasma redox state.142 The sulphur-containing residues, methionine and cysteine, account for 40%–80% of the total antioxidant activity of HSA.143
Albumin is well known for its binding of various molecules; therefore, antioxidant activity may result from its ability to bind bilirubin, homocysteine, and lipids. For example, the binding of HSA to polyunsaturated fatty acids and sterols may prevent lipid peroxidation.144
Based on estimates, under physiological conditions, one-third of the HSA exists as disulfides mixed with cysteine, homocysteine, or glutathione (HSA-S-S-R), whereas the rest of the HSA is in a reduced form with a free thiol in the Cys-34 residue (HSA-SH).145 Under oxidative stress, Cys34 thiol shifts to a sulfenic acid (HSA-SOH), which can be irreversibly oxidized to the sulfinic (HSA-SO2H) and sulfonic (HSA-SO3H) acids or, through the reactions with glutathione, can be returned to the HSA-SH reduced form.146 Thus, an outcome of the oxidative process may depend on whether the sulfenic acid is further oxidized, or whether it is reduced, leading to the initial HSA-SH (Figure 3).
During pathological conditions like diabetes, COPD, and kidney disease, structural modifications of HSA induced by glucose or acrolein can strongly impair its antioxidant properties.147
Alpha-1 Antitrypsin
Alpha-1 antitrypsin (AAT) is viewed as a key inhibitor of serine proteases, specifically, neutrophil elastase and proteinase 3. However, numerous studies have shown that, aside from its anti-protease properties, AAT has anti-inflammatory and immune regulatory functions, and some of these functions seem to be independent of the anti-protease activities.
Similar to albumin, AAT has exposed methionine (Met) residues and a free cysteine at the position 232, which can be attacked by oxidants.148,149 The Met-358 is at the “P1 position,” which is located in the reactive site, and determines anti-protease activity of AAT. Therefore, oxidative change of this Met into methionine sulfoxide inactivates AAT as a serine protease inhibitor.150 Carp et al reported that AAT isolated from bronchoalveolar lavage fluid of smokers contains 4 oxidized Met residues with loss of 40% of anti-protease activity.151 Other investigators suggested that inactivation of AAT by oxidation of either Met-351 or Met-358 provides a mechanism for regulation of its activity at sites of inflammation.152
Experimental findings have suggested that the oxidation of Met residues by cigarette smoke or free radicals released from inflammatory cells not only reduces the anti-elastase activity of AAT but also converts AAT into a proinflammatory molecule. Likewise, oxidized AAT has been found to induce monocyte chemoattractant protein-1 (MCP-1) release from monocytes.153 MCP-1 belongs to the CC chemokine family and functions as a chemoattractant for mononuclear phagocytes, T lymphocytes, B cells, and natural killer cells. Increased MCP-1 and its receptor, CCR2, in the lung have been positively associated with leukocyte infiltration in COPD.154
The oxidized form of AAT has also been found to express anti-inflammatory effects. For instance, oxidized AAT inhibits inflammation in response to cigarette smoke in vivo155 and induces a broad anti-inflammatory profile in gene expression of primary human lung microvascular endothelial cells.156 Moreover, oxidized AAT was found to prevent acute liver injury in vivo.157 We recently provided in vitro evidence that both native and oxidized AAT control equally well ATP-induced IL-1β release from human mononuclear blood cells.158
Available findings have allowed us to speculate that the biological activities of oxidized AAT may depend on the magnitude of AAT oxidation, in a manner similar to that discussed for HSA (Figure 3).
Similar to albumin, AAT can function as an indirect free radical scavenger by interacting with neutrophil alpha defensins,159-161 free fatty acids,162 and free heme.163 As an example, Tiriveedhi et al reported that lung transplant patients, who developed chronic lung allograft rejection, show increased defensin and decreased serum AAT levels along with high concentrations of AAT-defensin complexes in their bronchial lavage.164
Some studies have proposed that a fraction of the AAT protein is S-nitrosylated under physiological conditions, and that AAT nitrosylation is more efficient than the nitrosylation of bovine serum albumin or glutathione.165 The S-NO-AAT expresses a potent antimicrobial activity, inhibits cysteine proteases, and induces heme oxygenase-1 expression in hepatic ischemia-reperfusion injury in rats.166 A recent study reported that S-nitrosylation altered AAT to a proinflammatory protein, which facilitated the inflammatory state of macrophages by upregulating proinflammatory molecules and the activation of MAPK signalling pathways.167
However, the antioxidant properties of AAT remain largely unknown. Further investigations are required to understand fully the dynamics of AAT oxidation, and the mechanism of action of oxidized AAT.
Oxidants/Antioxidants in the Liver and Lung of Individuals with Inherited Alpha-1 Antitrypsin Deficiency
Severe inherited alpha-1 antitrypsin deficiency (AATD) is a monogenic, autosomal, co-dominant, inherited disease associated with a risk for developing liver disease at any age and/or early onset emphysema. The most clinically relevant Z variant of AAT protein differs from the normal M by a single amino acid substitution (Glu342Lys). This mutation results in protein accumulation within the endoplasmic reticulum (ER) of hepatocytes and other AAT-producing cells, which leads to ER stress or an aberrant inflammatory response.168 Studies in experimental models have shown an association between AATD and oxidative stress.169 It has been demonstrated that the expression of human Z AAT protein in mouse liver leads to elevated oxidative stress and lowered antioxidant protection.170 However, selenoprotein S was found to reduce ER stress and enhance cell ability to cope with the burden of misfolded Z AAT protein.171,172
Liver is a major organ attacked by ROS.173 The oxidative stress is regarded as one of the pathological mechanisms during initiation and progression of liver fibrosis/cirrhosis, alcoholic liver diseases, and non-alcoholic steatohepatitis. Concomitantly, systemic oxidative stress arising during liver damage can affect extrahepatic organs.174
AATD-related liver diseases have a highly variable clinical phenotype, suggesting that disease progression is strongly influenced by environmental and genetic modifiers.172 Genes involved in pathways related to oxidative stress and antioxidant defense might therefore be potential genetic modifiers in AATD-related liver diseases, and warrant further investigation.
Numerous studies have shown an increase of systemic oxidative stress markers in the lungs of cigarettes smokers and COPD patients without and with inherited AATD.175-181
The finding that the administration of all-trans retinoic acid (ATRA) in elastase-induced emphysema in rats reversed the emphysematous changes,182 suggested that ATRA might be a beneficial therapy for patients with emphysema. However, clinical trials of emphysema patients with and without AATD have failed to demonstrate measurable improvements in lung destruction.183
Another approach has been based on the observation that emphysema patients showed a marked reduction in the levels of hyaluronic acid,184 and that therapy with hyaluronic acid protected elastase-induced emphysema in mice.185 Hyaluronic acid is a high molecular weight glycosaminoglycan involved in the regulation of migration of inflammatory cells and the scavenging of free radicals.186 The mechanism by which hyaluronic acid may protect elastin is not yet understood. One possibility is that hyaluronic acid binds to elastic fibres and prevents them from attack by elastase.187 Investigators have therefore hypothesized that aerosols of hyaluronic acid inhaled daily may protect against lung elastic fiber injury. To test this hypothesis, trials of inhaled hyaluronic acid in individuals with AATD are under way in the hope of preventing the progression of this lung disease.
Remarkably, a study by Escribano et al revealed that, when compared with the control group, children with severe AATD showed significantly increased levels of oxidative stress biomarkers and decreased levels of antioxidants, as expressed by lower total and reduced glutathione levels, decreased catalase activity, and increased glutathione peroxidase activity.188 These findings supported oxidative stress as a feature of AATD contributing to the risk of disease development late in life. Moreover, oxidation of AAT may lead to a loss of its anti-protease activity that is already lower in AATD, so the antioxidant potential in the treatment of emphysema patients with AATD needs to be considered.189
Until now there has been limited knowledge about the antioxidant status in AATD individuals, so the usefulness of antioxidant therapies remains to be investigated.
Conclusion
ROS are the natural consequence of aerobic metabolism and are important for basic cellular functions, including proliferation, inflammation, apoptosis, and gene expression. However, if the level of radicals exceeds that which the body can handle, then oxidative stress occurs. Factors increasing the production of reactive species can be internal, such as inflammation, or external such as pollution, UV exposure, xenobiotic compounds, and cigarette smoke. Many substances associated with oxidative stress increase during aging and in patients with chronic inflammatory diseases, like COPD. To protect the cells and organ systems against ROS, humans have evolved a highly sophisticated and complex internal and external antioxidant protection system. Preclinical studies and clinical trials suggest that antioxidants, such as small thiol molecules (N-acetyl-L-cysteine and carbocysteine), antioxidant enzymes (glutathione peroxidases), activators of Nrf2-regulated antioxidant defense system (sulforaphane), and vitamins, for example, C, E, and D, enhance the endogenous antioxidant system and reduce oxidative stress. Among important antioxidants are blood proteins, specifically albumin. Whether AAT is a significant contributor to the antioxidant protein pool in human blood remains to be investigated in more detail. Further basic and translational research is needed to identify individuals more susceptible to ROS damage, and to clarify whether ROS is an important target to treat COPD and AATD patients. This knowledge might be critically important for identifying patients who benefit most from the therapy with purified AAT protein and/or specific drugs with antioxidant potentials.
Abbreviations
reactive oxygen species, ROS; nicotinamide adenine dinucliotide phosphate hydrogen, NADPH; reactive nitrogen species, RNS; chronic obstructive pulmonary disease, COPD; manganese, Mn; Mn superoxide dismutase, MnSOD; nuclear factor erythroid-2-related factor, Nrf2; lipopolysaccharide, LPS; Beta-Carotene and Retinol Efficacy Trial, CARET; forced expiratory volume in 1 second, FEV1; myeloperoxidase, MPO, superoxide dismutase, SOD; cytoplasmic Cu-ZnSOD, SOD1; mitochondrial MnSOD, SOD2; glutathione peroxidases, GPXs; peroxiredoxins, Prxs; N-acetylcysteine, NAC; glutathione, GSH; coenzyme Q10, CoQ; uric acid, UR; human serum albumin, HAS; alpha-1 antitrypsin, AAT; methionine, Met; alpha-1 antitrypsin deficiency, AATD; endoplasmic reticulum, ER; all-trans retinoic acid, ATRA
Funding Statement
This study was supported by the National Science Center, Poland (grant 2015/17/B/NZ5/01370).
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