Chlorinative stress in age-related diseases: a literature review

Due to well-known HOCl generation by myeloperoxidase, Daugherty et al. in 1994. studied atherosclerotic lesions where they detected the enzyme MPO; their data sustained that MPO induced LDL oxidation by pathways involving HOCl and promoting atherogenesis [21]. These data were studied thoroughly by Hazen et al. which demonstrated that HOCl produced by the system myeloperoxidase-H2O2-Cl oxidated LDL l-tyrosine. Oxidated LDL were known to have a main role in converting macrophages into foam cells and in forming atherosclerotic lesions typical of aged people [22]. In a successive paper, they also demonstrated that 3-chlorotyrosine was a marker of chlorination at sites of inflammation [7]. Also the eosinophil peroxidase (EPO) was thought being implicated in provoking oxidative tissue damage in many conditions (i.e. asthma, allergic inflammatory disorders, cancer, infections). But Wu et al. reported that EPO generated reactive nitrogen species by direct oxidation of NO 2 and not by secondary oxidation of NO 2 by HOCl [23]. Every paper reported seemed to address the chlorinating stress as responsible of cardiovascular-age related damage so next step was demonstrating if oxidative stress HOCl-related could induce endothelial dysfunction by interfering with the NO synthetic pathway. Zhang et al. noticed that a treatment with HOCl caused the inhibition of aortic relaxation correlated to HOCl concentration. In their experiments, they also dosed endothelial NO synthase (NOS III) after the administration of HOCl then supplemented rats with L-arginine and reported a complete inversion of HOCl inhibitory effect vessel relaxation [24]. As Oxidized lipoproteins act a main role in atherosclerosis and high levels of 3-chlorotyrosine were demonstrated being in atherosclerotic lesion, Bergt et al. studied how activated phagocytes chlorinated specific region in HDL by mass spectrometry. Results obtained demonstrated how HOCl selectively targeted tyrosine residues nearby primary amino-groups in proteins. This oxidation process performed by phagocytes lead to damage host tissue during inflammatory diseases (i.e. atherosclerosis) [14]. As demonstrated by Cook et al., SERCA activity is fundamental in human homeostasis; it is blocked by oxidant agents and deregulated in aged tissues and cardiovascular pathologies. They reported that HOCl targeted thiols and provoked cellular impairment. They speculated that HOCl could inhibit SERCA activity by thiol oxidation and generated cytosolic Ca2+ augmented levels in artery endothelial cells [17]. Ismael et al. shown that exposure of macrophages to HOCl and HOSCN or to LDL already modified by these chlorinative stress agents caused a compromised lysosomal enzyme function reducing both proteolytic capacity and decrease cholesteryl ester hydrolysis; according the authors these events could conduct to the accumulation of protein and lipids in the arterial wall fundamental for the development of atherosclerosis [25].

Therefore, Wang et al. in vivo studies demonstrated that damaged LV-tissue by the induction of an acute myocardial infarction lead to the recruitment and activation of neutrophils and concomitant increase in MPO-activity and consequently of the HOCl; the 3-Cl-Tyr formed by the HOCl modification of the heme protein Mb impaired the protein’s affinity for binding oxygen in the myocardium [26].

From other studies emerged that MPO augmented activity during inflammatory processes could worsen diseases such as atherosclerosis and reperfusion injury; in fact, an increased release of hypochlorite contributed to the damage observed in these pathologies [24, 27‐30]. On these basis Sand et al. evaluated the effects of hypochlorite and H2O2 on 1-adrenoceptor, ET-1 receptors and M2 receptors processes on mice. They concluded that formation of hypochlorite provoked the amplification of the oxidative capabilities of H2O2 enhancing the damage of endothelial physiology. Hypochlorite also interfered with the normal transduction of the 1-adrenoceptor by altering the coupling of the muscarinic M2 receptor to the G-proteins favouring the progression of inflammation-associated pathologies in the cardiovascular system [31].

On the other hand it was also important understanding the inflammatory mechanisms HOCl - associated, so Raftery et al. demonstrated that HOCl produced by myeloperoxidase and H2O2 and by phorbol 12-myristate 13-acetate stimulated and activated neutrophils. HOCl oxidation during inflammation caused the formation of sulfamide monomers having chemotactic activity for neutrophils in inflammation. These changes in human proteins could, according Raftery et al. potentially play a critical role in physiological and pathological processes fundamental in aging and age-related diseases [32]. In a rat hepatocytes experiment, Mallis et al. reported that HOCl generated in a non-reversible way oxidized forms of carbonic anhydrase III in case of low doses or absence of glutathione (GSH). As it is known that there is a physiological reduction of glutathione in aged animals, these condition may together with other mechanisms favourite a higher irreversible protein oxidation [33]. Strosovà et al. 2005., studied the effects of HOCl in rabbit skeletal sarcoplasmic reticulum (SR) speculating an aging model. It was found that HOCl blocked Ca²⁺-ATPase activity. It also oxidated SH groups and formed protein carbonyls. On the other side they tested and demonstrated the antioxidant effect of stobadine (at least as much as lipoic acid), trolox and Pycnogenol [34]. Hazell et al., wanted to determine if HOCl could be involved in protein modifications associated to age-related eye disease such as nuclear cataract. In the human lens samples analysed no chlorotyrosine derivates could be detected and no myeloperoxidase activity trace could be found either [35].

In the attempt to report the role of neutrophils as source of oxidative stress in rheumatoid arthritis (RA), Baskol et al. 2006., described how advanced oxidation protein products (AOPP) are formed by the interaction of HOCl/HOCl and proteins. In the samples analysed the protein oxidative damage corresponded to increased levels of AOPP and nominated them as marker of oxidative stress. According their data, neutrophils, which produce great quantities of chlorinated oxidants by MPO, could augment serum AOPP levels and play a fundamental role in the pathogenesis of RA by generating pro-inflammatory mediators [36]. Although its known induction of oxidant intermediates Leung et Al. decided to study skin and NF-kB effects of topical application of HOCl. They reported HOCl capacity to block NF-kB signalling and to attenuate NF-kB related disease as acute radiation dermatitis and skin aging process [37].As regards the young and the elderly’s immune system, many years ago it emerged that neutrophil extracellular traps (NETs) are part of the defensive mechanism of neutrophils; their formation requires reactive oxygen species presence. Hazeldine et al. demonstrated that NET generation in response to HOCl was lower only in aged patients. A deficit on NET formation could contribute to a higher incidence of infection in older adults [38]. Superoxide (O2-) and hydrogen peroxide (H2O2) are consequences of hyperglycemia; during last years was clarified their role in the apoptosis of endothelial cells and in causing diabetic vascular injury. This damage is the result of endothelial dysfunction and vascular complications. As NADPH oxidase-derived ROS and vascular-bound MPO are increased in diabetic vessels, MPO/NADPH oxidase/H2O2/HOCl could constitute a main path in diabetic vascular damages. According Tian et al. blocking the MPO-NADPH oxidase-HOCl pathway could be a novel therapeutic strategy for the prevention and the recovery of vascular diseases [39].

MPO and its consequent product HOCl resulted involved in the pathophysiology of neurodegenerative diseases. In fact, MPO is expressed with increased levels in the cerebral tissue of patients affected by Alzheimer disease (AD) and this enzyme appears being catalytically active [40]. Not present in normal brains of old patients, MPO was detectable in amyloid plaques of AD patients. It was speculated a model where MPO expression in astrocytes promoted a HOCl related damage, contributing to neuronal damage and cognitive impairment [40, 41].