Abstract
Obstructive sleep apnoea/hypopnoea syndrome (OSAHS) is a highly prevalent breathing disorder in sleep that is an independent risk factor for cardiovascular morbidity and mortality. A large body of evidence, including clinical studies and cell culture and animal models utilising intermittent hypoxia, delineates the central role of oxidative stress in OSAHS as well as in conditions and comorbidities that aggregate with it. Intermittent hypoxia, the hallmark of OSAHS, is implicated in promoting the formation of reactive oxygen species (ROS) and inducing oxidative stress. The ramifications of increased ROS formation are pivotal. ROS can damage biomolecules, alter cellular functions and function as signalling molecules in physiological as well as in pathophysiological conditions. Consequently, they promote inflammation, endothelial dysfunction and cardiovascular morbidity. Oxidative stress is also a crucial component in obesity, sympathetic activation and metabolic disorders such as hypertension, dyslipidaemia and type 2 diabetes/insulin resistance, which aggregate with OSAHS. These conditions and comorbidities could result directly from the oxidative stress that is characteristic of OSAHS or could develop independently. Hence, oxidative stress represents the common underlying link in OSAHS and the conditions and comorbidities that aggregate with it.
- Cardiovascular morbidity
- inflammation
- metabolic dysregulation
- obesity
- obstructive sleep apnoea/hypopnoea
- oxidative stress
SERIES “THE GENETIC AND CARDIOVASCULAR ASPECTS OF OBSTRUCTIVE SLEEP APNOEA/HYPOPNOEA SYNDROME”
Edited by R.L. Riha and W.T. McNicholas
Number 5 in this Series
In recent years, obstructive sleep apnoea/hypopnoea syndrome (OSAHS) has become a major public health problem, as predicted by Phillipson 1 some 15 yrs ago in an editorial accompanying the seminal paper by Young et al. 2 on the prevalence of symptomatic sleep apnoea in the general population. The close association between OSAHS and cardiovascular morbidity has been a crucial factor in the process of making OSAHS a public health problem. Since the early days, when OSAHS patients were diagnosed in sleep laboratories, it has become evident that a substantial number exhibit cardiovascular risk factors and overt cardiovascular diseases 3–5. These initial observations, relying mostly on case series of patients studied in sleep clinics and cross-sectional studies, have been confirmed and expanded in recent years by well designed large-scale epidemiological, treatment and prospective studies, and by animal models of OSAHS. These demonstrated close association between OSAHS and hypertension, ischaemic heart disease, strokes, arrhythmias, chronic heart failure and cardiovascular mortality. Extensive reviews on cardiovascular morbidity and mortality in OSAHS and the association of OSAHS with components of the metabolic syndrome have been recently published 6–8. Moreover, patients with OSAHS without overt cardiovascular diseases show subclinical signs of atherosclerosis that are related both to the structure of the vasculature, such as increased intima-media thickness, arterial plaque formation and calcified artery atheromas 9–12, and to its function, such as endothelial dysfunction and higher pulse wave velocity 13–16. Some of these subclinical conditions were improved by treatments with nasal continuous positive airway pressure (nCPAP) or a dental device 17–19. Thus, today, there is a better understanding of the pathophysiology of cardiovascular diseases in OSAHS and of its natural evolution.
In the present review we will examine the role of oxidative stress in initiating cardiovascular consequences in OSAHS. We will argue that oxidative stress is not only a characteristic of OSAHS but is also an important component in the associated conditions and comorbidities that aggregate with it, such as sympathetic activation, obesity, hypertension, hyperlipidaemia and diabetes mellitus, of which some may precede the appearance of OSAHS, or develop independently. A discussion is dedicated to the potential synergistic effects of oxidative stress associated with these conditions and comorbidities and with sleep apnoea itself, which may greatly enhance the impact of oxidative stress and the resultant inflammatory/immune cell activation on the cardiovascular system. Wherever relevant, animal models treated with intermittent hypoxia (IH) mimicking OSAHS will be described to reinforce detailed mechanisms that cannot be directly investigated in OSAHS patients. A simplified scheme of the central role of oxidative stress in OSAHS and the associated risk factors leading to cardiovascular morbidity is illustrated in figure 1⇓.
PATHOPHYSIOLOGY OF CARDIOVASCULAR MORBIDITY IN OSAHS
The pathophysiological mechanisms of cardiovascular morbidity in OSAHS are complex and involve neural, humoral, mechanical and haemodynamic components that may be modified by genetic makeup, nutrition and lifestyle-related variables 20, 21. OSAHS is associated with elevated sympathetic discharge during sleep and waking that has been linked with increased systemic blood pressure and could be ameliorated by nCPAP treatment 22–25. Moreover, there is evidence that the sympathetic responses to hypoxic chemoreflex stimulation are enhanced in OSAHS 26, which could be mimicked by exposing healthy subjects to IH 27. Also, OSAHS patients have impaired glucose tolerance, leptin resistance and increased incidence of the metabolic syndrome 28. Higher fasting blood glucose levels in OSAHS increased the risk of diabetes mellitus. Mechanical and haemodynamic changes, which arise from the repeated negative intrathoracic pressure swings occurring because of the upper airway obstructions, result in altering stroke volume and cardiac output 29. Treatment with nCPAP was reported to decrease blood pressure, improve insulin sensitivity and decrease left ventricular wall thickness in OSAHS patients 30. Recent studies have shown that OSAHS, as well as an animal model of chronic IH, is also associated with hypercholesterolaemia independent of adiposity 31. Treatment with nCPAP decreased total and low-density lipoprotein (LDL) cholesterol without any change in body weight. Accumulated data from our laboratory and others have shown, however, that OSAHS is also strongly associated with oxidative stress, which, as will be demonstrated later in this review, is a major component in the chain of events leading to atherogenesis and cardiovascular morbidity. In the following sections we will review the evidence supporting the involvement of oxidative stress in OSAHS as well as in conditions and comorbidities that aggregate with it.
REACTIVE OXYGEN SPECIES AND OXIDATIVE STRESS IN HEALTH AND DISEASE
Reactive oxygen species: seminal discoveries and sources
Reactive oxygen species (ROS) or reactive nitrogen species (RNS) are atoms or molecules possessing one or more unpaired electrons in the outer orbit and, therefore, are prone to react chemically 32. The predominant ROS molecule is the superoxide radical (O2·-), which is generated by univalent reduction of molecular oxygen, mainly during mitochondrial respiration but also by several enzymatic systems, such as xanthine oxidase, “uncoupled” endothelial nitric oxide synthase (eNOS) and reduced nicotinamide adenine dinucleotide phosphate (NADPH) oxidase from primed leukocytes and endothelial cells 33, 34. The superoxide is a relatively weak radical, but reacting with other molecules can yield additional more potent ROS molecules and oxidants as hydrogen peroxide (H2O2), hydroxyl radical (OH·) and lipid peroxides. Additional toxic radicals, such as peroxynitrite (OONO-), which is formed by the reaction of superoxide with the primary vasodilator nitric oxide (NO), also contribute to oxidative/nitrosative stress. This reaction results in diminished NO availability and severely affects endothelial function 35.
While ROS are produced in normal aerobic metabolism, in order to keep oxidation–reduction under tight control, antioxidant defence systems have evolved to help maintain the tightly regulated balance termed oxidative homeostasis 32. Upon disruption of this balance, oxidative stress ensues. Thus, oxidative stress results in an imbalance between oxidant-producing systems and antioxidant defence mechanisms, resulting in excessive formation of ROS. This excess ROS/RNS can damage cellular components and various biomolecules, such as lipids, proteins, DNA and carbohydrates, and thus alter their biological functions.
The first to suggest that superoxide radicals were involved in pathologies such as atherosclerosis and cancer as well as ageing was Harman 36, 37. However, three major discoveries later established the roles of superoxide radicals in the biology and pathophysiology of medicine. In 1969, McCord and Fridovich 38, 39 discovered the superoxide dismutase (SOD) enzyme, which catalyses the dismutation of the superoxide radical to H2O2 and molecular oxygen. This discovery had far-reaching implications, since it indicated that the superoxide radical was indeed produced in the physiological setting, as suggested over a decade earlier by Harman. The second discovery, by Babior et al. in 1973 40, established the importance of the superoxide radical that is released by blood leukocytes as a protective mechanism against invading microorganisms, later shown to be the product of activated NADPH oxidase 41. The third and most relevant discovery to OSAHS was that by Granger et al. 42, which established the involvement of superoxide radicals in ischaemia/reperfusion injury. Specifically, the relevance of ischaemia/reperfusion injury was shown in conditions such as ischaemic heart disease, stroke, surgery and organ transplantation. The main sources of ROS for these pathologies were identified as xanthine oxidase 43, inflammatory cells and damaged mitochondria 44. Since then, more than 80 pathologies have been associated with ROS and oxidative stress, including all inflammatory diseases (such as arthritis, glomerulonephritis and adult respiratory distress syndrome), cancer, ischaemic heart diseases and stroke, diabetes, hypertension, atherosclerosis and neurodegenerative diseases (such as Alzheimer’s and Parkinson’s diseases) 45 and, more recently, OSAHS. The fact that a great number of diverse pathologies share such a common feature (overproduction of ROS) is likely to result from altered oxidative metabolism of injured cells, activated inflammatory cells or altered oxygen supply. However, a fundamental question arises: are ROS the cause or a consequence in each of these conditions? Apparently in many of the diseases this is an unresolved issue. However, we will confine the current discussion primarily to OSAHS.
ROS as signalling molecules
Although for many years ROS were considered merely as toxic and unavoidable by-products of normal respiratory oxidative metabolism, in the last decade they were consistently described as regulators of signal transduction and as second messengers in many signalling pathways in all cells 46. Since ROS are abundant molecules that react with many molecules and atoms, their specificity, which is a prerequisite for signalling, was questioned 47. However, their importance in the maintenance of strict cellular redox homeostasis is now well established 32, 47. The evidence that implicates ROS in the activation of a plethora of signalling pathways is rising. To date, pathways involved in initiation of inflammatory responses, ultimately leading to atherosclerosis, were described in an array of pathologies, such as hypertension, hyperlipidaemia, diabetes mellitus and obesity 48. Specifically, ROS were implicated in mitogen-activated protein kinase (MAPK) pathways, which induce activation of various nuclear transcription factors, such as nuclear factor (NF)-κB, activator protein (AP)-1, hypoxia-inducible factor (HIF)-1α, sterol regulatory element binding proteins (SREBPs) and GATA-4 32, 49, 50. NF-κB is of particular significance to the pathology of OSAHS since it initiates inflammatory pathways and orchestrates the production of adhesion molecules, inflammatory cytokines and adipokines. Moreover, NF-κB participates in obesity and the metabolic syndrome and, similarly to OSAHS, it induces inflammatory and atherosclerotic consequences. However, these mechanisms are not yet fully elucidated 51. HIF-1α is another transcription factor with potentially important implications to the pathology of OSAHS and in the augmentation of sympathetic nerve activity 52, 53, and associated comorbidities such as hypertension 54, 55 and hyperlipidaemia 56, arising from IH. Additional transcription factors that are redox sensitive and could possibly be implicated in OSAHS pathology include NF-interleukin (IL)-6, early growth response-1, specificity protein-1 and NF-(erythroid-derived 2)-related factor (Nrf)2-antioxidant responsive element (ARE), which regulates antioxidant genes. Additional findings on transcription factors in OSAHS are described in following sections of this review.
Evidence for oxidative stress in OSAHS and IH models
The evidence implicating oxidative stress as a fundamental component of OSAHS pathophysiology has been consistently rising in the last decade. It was shown in cells 57, 58, plasma 59–61, urine 62 and exhaled air 63, and could be moderated by various treatments, such as nCPAP or dental device 19, 59, 60, 63. The chain of events that promotes oxidative stress is most likely initiated by repeated breathing cessation, accompanied by drastic changes in oxygen tension, and is considered analogous to hypoxia and reoxygenation injury 33, 43, 64, 65. This process of hypoxia/reoxygenation affects cells and cellular components, resulting in increased ROS production. One of the most prominent features of hypoxia/reoxygenation is mitochondrial dysfunction, which induces increased production of ROS, particularly through complex I of the respiratory chain 33, 66. Leukocytes are affected as well and thus largely contribute to increased ROS production in OSAHS patients via the NADPH oxidase system, while treatment with nCPAP attenuates ROS production 57, 58, 67. Xanthine oxidase is another enzyme affected by OSAHS 33, 68. Additional ROS sources in OSAHS include endothelial cells and uncoupled eNOS 69. Accordingly, oxidation of various macromolecules further attests to enhanced oxidative stress in OSAHS. Of these, lipids are the most prone to oxidation. Increased lipid peroxidation in OSAHS that was attenuated by the use of nCPAP was demonstrated in several studies 59, 60, 70. Moreover, the reported increased lipid peroxidation was specifically found to be apnoea/hypopnoea index (AHI; the number of apnoeas plus hypopnoeas divided by hours of sleep)-severity dependent. Also, it was less affected by comorbidities such as hypertension and cardiovascular diseases, or by age and body mass index (BMI) 59. The fact that lipid peroxidation, which is a surrogate marker of atherosclerosis and cardiovascular morbidity, was found to be AHI-severity dependent emphasises the possible involvement of ROS in amplifying atherosclerotic processes in patients with OSAHS. Notably, a single night of treatment with nCPAP was sufficient to attenuate lipid peroxidation (L. Lavie, A. Vishnevsky and P. Lavie, Technion Institute of Technology, Haifa, Israel; personal communication). In addition, DNA oxidation was increased in patients with OSAHS 62. Similarly, oxidation of proteins, nucleic acids and lipids were shown in several studies using animal models exposed to chronic IH 71, 72. Furthermore, in rats exposed to chronic IH, lipid peroxidation was increased while antioxidant activity was decreased. These findings were correlated with blood pressure and left ventricular myocardial dysfunction 73.
Disruption of the tightly regulated cellular oxidation–reduction (redox) state, maintained between oxidant-producing systems and antioxidant defence mechanisms, could also be affected by decreased antioxidant capacities. As noted earlier, in patients with OSAHS this balance was shown to be perturbed by excess ROS formation. Thus, decreased antioxidant capacity was also shown to contribute to oxidative stress 61, 74. Additionally, the antioxidant enzyme paraoxonase-1, which is located exclusively on high-density lipoprotein (HDL) and protects both LDL and HDL from oxidative modification, was shown to decrease in patients with OSAHS. Moreover, the decreased paraoxonase-1 activity was more pronounced in patients who already had cardiovascular comorbidities 59. Paraoxonase-1 activity was also significantly negatively correlated with AHI but not with BMI or age (L. Lavie, A. Vishnevsky and P. Lavie; personal communication). In the clinical setting, paraoxonase-1 activity was shown to decrease in patients with acute myocardial infarction, hypercholesterolaemia, diabetes mellitus and hyperleptinaemia 75, 76. This is in agreement with the observation that HDL of OSAHS patients was shown to be dysfunctional 77.
The impact of oxidative stress on endothelial dysfunction is a likely possibility due to the decline in NO bioavailability noted in the circulation of patients with OSAHS 78–80, as discussed previously 33, 65, 81. A recent study conducted on freshly harvested venous endothelial cells from patients with OSAHS provided the first direct evidence at the cellular and molecular levels on the significance of oxidative stress to endothelial cell function 69. In that study, the eNOS and its phosphorylated active form were attenuated in patients with OSAHS, whereas the oxidative stress marker nitrotyrosine, which is indicative of NO inactivation by oxidative stress, was elevated. Treatment with nCPAP reversed these values and improved endothelial function as determined by flow-mediated dilation 69. Furthermore, data have demonstrated that treating OSAHS patients with allopurinol, a xanthine oxidase inhibitor, or the antioxidant vitamin C improved endothelial function 68, 82. Additionally, the potential importance of antioxidant treatment for attenuating oxidative stress and inflammation resulting from chronic IH is exemplified in a recent animal model treated orally with antioxidant green tea polyphenols (GTP) 83. While IH induced cognitive decline, increased brain lipid peroxidation via NADPH oxidase activation, and elevated the levels of the inflammatory prostaglandin E2, treatment with GTP improved these measures 83.
Taken together, the wealth of data accumulated thus far, in OSAHS and in animal models treated with IH, clearly attests to the presence of oxidative stress. This was shown by increased production of ROS, decreased antioxidant capacity, diminished NO bioavailability and reversal by treatment with antioxidants, nCPAP or dental device.
Activation of transcription factors in OSAHS and in animal models of IH
NF-κB and AP-1
Activation of inflammatory pathways by upregulation of NF-κB was demonstrated in neutrophils and monocytes of patients with OSAHS 84–86, and in an in vitro model of HeLa cells treated with IH 87. Consequently, upregulation of adhesion molecules and inflammatory cytokines and adipocytokines, the gene products of NF-κB, were also noted, further supporting activation of NF-κB in OSAHS 57, 67, 88, 89, as well as in associated conditions and comorbidities 90. Upregulated activity of AP-1 and tyrosine hydroxylase mRNA, which is an AP-1-regulated downstream gene, was demonstrated in tissue culture in PC12 cells exposed to IH 91. Since AP-1 upregulation, similarly to NF-κB, involves upregulated expression of adhesion molecules and inflammatory cytokines, the involvement of AP-1 is also implicated in the pathogenesis of OSAHS 33, 81. Interestingly, IH in vitro was shown to activate the NF-κB in an IκB kinase-dependent manner via activation of p38 MAPK 92. Thus, the data on the involvement of inflammation in OSAHS are well established, but the pathways of activation need to be elucidated.
HIF-1α
Induction of the master regulator HIF-1α, which is essential for oxygen homeostasis and adaptive response to hypoxia, was documented primarily in several experimental models of IH in tissue culture, and in rodents exposed to chronic IH 93. By delineating the transduction signals that activate HIF-1α under IH conditions, it was shown that IH in PC12 cells induced HIF-1α transcriptional activity via a novel signalling pathway involving Ca2+/calmodulin-dependent kinase 94. In yet another study conducted on endothelial cells in vitro, four cycles of repeated hypoxia/reoxygenation induced a modification in HIF-1α phosphorylation patterns via p42/p44 activation 95. By contrast, Ryan et al. 92 did not find increased HIF-1α activation in bovine aortic cells exposed to IH in vitro. Such contradictory findings may result from different cell types or from the different IH patterns employed. In animal models exposed to chronic IH, HIF-1α was implicated in hypertension 54, 55 and in components of the metabolic syndrome 56. In wild-type mice treated with chronic IH, hypercholesterolaemia and hypertriglyceridaemia were evident after 5 days of treatment, whereas, in mice with partial deficiency for HIF-1α, the development of hypertriglyceridaemia was inhibited 56. Thus far, HIF-1α activation has not directly been demonstrated in patients with OSAHS. However, upregulation of some of its gene products, including erythropoietin, vascular endothelial growth factor and heat shock proteins, supports this notion 33, 96, 97, although erythropoietin was not reported by all 87. Combined with the data from animal studies described above, the role of HIF-1α in OSAHS pathophysiology is waiting to be unveiled.
SREBPs
The SREBPs are another group of transcription factors with possible implications in the pathology of OSAHS. The SREBPs that activate genes regulating lipid metabolism 98, 99 were shown to be upregulated in experimental models of IH 100, 101. Furthermore, SREBPs were also shown to be affected by redox imbalance and oxidative stress 102, 103. To date, all studies describing the possible involvement of SREBPs in OSAHS were derived from rodents exposed to chronic IH. In this model, the development of atherosclerosis was demonstrated in response to chronic IH and both lipid peroxidation and atherosclerosis were dependent on the severity of the chronic IH 104. Interestingly, although the hyperlipidaemia observed was mediated by the SREBP-1 pathway 31, 105, HIF-1α was also implicated in the upregulation of serum triglyceride levels through post-translational regulation of SREBP-1 56.
Given that OSAHS is associated with hyperlipidaemia independent of obesity, as manifested by various studies 106–110, it is a likely possibility that the hyperlipidaemia observed in OSAHS is mediated via upregulated SREBP-1 pathway and HIF-1α involvement, as demonstrated by the animal models previously cited. Furthermore, while oxidative stress was implicated in the upregulation of SREBP, antioxidants were inhibitory 102, 103. Thus, IH and oxidative stress in humans, like in experimental models, may upregulate SREBP-1 leading to the hyperlipidaemia associated with OSAHS. Yet the possible complex interactions with HIF-1α remain elusive.
GATA
The GATA transcription factors owe their name to their ability to bind the consensus DNA sequence (A/T) and (A/G) through two highly conserved zinc finger domains. Based on animal models of chronic IH, the GATA family is emerging as yet another set of redox-sensitive transcription factors with far-reaching implications for cardiovascular morbidity in OSAHS. The GATA-4 and GATA-6 members of this family were implicated in the regulation of cardiac development and growth as well as in heart failure. However, an altered balance of GATA-4 may cause cardiac hypertrophy or promote cardioprotection 111. Moreover, recent data show that GATA-4 might be an important mediator of cardiac myocyte survival via endothelin-1 and hepatocyte growth factor, to prevent cardiomyocyte death by oxidative stress-induced apoptosis 112.
By treating a mouse model with IH, GATA-4 was shown to exert preconditioning-like cardioprotective effects, by protecting cardiomyocytes from apoptosis. While treatment with acute IH exerted cardioprotective effects, treating mice with a prolonged period of IH induced increased susceptibility of the heart, which was mediated by increased oxidative stress. Additional treatment with prolonged IH reversed the added myocardial damage 113, 114. It is therefore of utmost importance to delineate the complex effects of IH on the GATA family of transcription factors in the human heart. This could help in identifying patients with OSAHS at risk of developing cardiovascular morbidity or alternatively those who may develop cardioprotection.
Nuclear transcription factors act in concert and, apart from being activated by oxidative stress, are also activated by a variety of other signals, such as hormones, growth factors and cytokines, to regulate gene expression. Thus, investigating the mechanisms of their upregulation and the transduction pathways that are activated in OSAHS may prove difficult, mainly due to various inter-individual differences in the levels of signals other than IH. Employing tissue culture models, knockouts and transgenic mice exposed to IH may prove useful in delineating such mechanisms.
INFLAMMATORY PATHWAY ACTIVATION AND INTERACTIONS WITH ENDOTHELIAL CELLS IN OSAHS
As noted earlier, ROS molecules and a state of oxidative stress are considered potent activators of a cascade of inflammatory pathways that induce overexpression of adhesion molecules and pro-inflammatory cytokines. These adhesion molecules facilitate the recruitment and accumulation of leukocytes, platelets and possibly red blood cells (RBCs) on the endothelium lining the vasculature. Such cellular interactions between blood cells and endothelial cells may promote endothelial cell injury 33.
Blood cell activation and expression of adhesion molecules
Normally, circulating leukocytes are free flowing in the circulation and resist interactions with endothelial cells. Upon encounter with a variety of stimuli or insults, including inflammation, infections, hypercholesterolaemia, cytokines, hypoxia/reoxygenation and sleep apnoea, adhesion molecules and cytokines are upregulated in blood cells as well as in endothelial cells. Expression of adhesion molecules is a highly regulated and orderly process that facilitates these interactions between blood cells and endothelial cells. Such cellular interactions promote adherence and injury to the vascular endothelium. The selectins (L-selectins in leukocytes, E-selectins in endothelial cells and P-selectins in platelets and endothelial cells) facilitate weak binding between leukocytes and endothelial cells. A firm binding is mediated by the integrins, which also mediate transmigration into the interstitial layer through the endothelial cell layer 48, 115. In OSAHS, several studies have described the expression of adhesion molecules on various leukocyte subpopulations and the interactions with endothelial cells 57, 67, 88, 89, 116, 117.
Polymorphonuclear leukocytes
The polymorphonuclear leukocytes (PMNs) are the most abundant of the leukocyte subpopulations, representing approximately 60% of all circulating leukocytes. They are short lived (up to 24 h in the bloodstream) terminally differentiated cells that continuously undergo cell death by apoptosis. PMNs actively participate in inflammatory responses in order to protect from invading microorganisms, foreign particles or cellular debris. While recruited to inflammatory sites or in conditions characterised by ischaemia and reperfusion, they express various injurious molecules, such as ROS, inflammatory cytokines, adhesion molecules and cell surface receptors 118. Interestingly, PMNs were shown to infiltrate eroded or ruptured plaques obtained from patients with acute coronary syndromes 119, 120, and to participate in the pathogenesis of lethal myocardial reperfusion 121. Notably, depleting PMNs resulted in reduced myocardial infarct size and a protected myocardium 122, 123.
In patients with OSAHS, increased expression of selectins CD62 and CD15 was noted in a severity-dependent manner. Treatment with nCPAP effectively lowered the expression of CD15 67. However, the expression of the β-subunits of the integrins CD11b (O. Golan-Shany, P. Lavie and L. Lavie, Technion Institute of Technology, Haifa, Israel; personal communication) or CD11c, and adhesion to endothelial cells, were unaffected 57. Since the selectins but not integrins of OSAHS patients’ PMNs were upregulated, this implies that only the interactions involving binding and tethering with endothelial cells are increased while those for firm adhesion are not necessarily affected. In addition, PMN apoptosis, a fundamental injury-limiting mechanism and a key event in the control of inflammation, was suppressed in OSAHS PMNs. Suppressed apoptosis and increased expression of selectins in OSAHS PMNs could suggest increased PMN/endothelial cell interactions and, therefore, amplification of their destructive potential towards the endothelium 67.
Monocytes
Like PMNs, monocytes act as professional phagocytes, but unlike PMNs, they are long lived and their initiation, participation in progression and persistence of atherosclerosis are well established 48, 124. Upon activation by various stimuli and inflammatory conditions they too express higher amounts of adhesion molecules, ROS molecules and inflammatory cytokines. In OSAHS, monocytes were shown to be activated and expressed higher amounts of CD15 and CD11c, ROS and cytokines 57, 125. Furthermore, CD15 expression was shown to depend on the severity of OSAHS 89 and in healthy individuals hypoxia in vitro resulted in upregulated CD15 expression 57. Unlike in PMNs, the CD11c integrin of OSAHS monocytes was also elevated, while treatment with nCPAP attenuated the levels of both CD15 and CD11c. Accordingly, increased adhesion of OSAHS monocytes to endothelial cells of venous origin (human umbilical vein endothelial cells) or arterial origin (human coronary artery endothelial cells) was noted. Treatment with antibodies neutralising selectins (anti-CD62) and integrins (anti-CD54) abrogated the adhesion of monocytes to endothelial cells 57. The involvement of monocytes in atherogenesis in OSAHS was further implicated by the observation that lipid uptake was increased in human macrophages that were treated with experimental IH in vitro 126.
T-lymphocytes
Numerous subpopulations of lymphocytes have mainly been implicated in various atherogenic processes via cytokine secretion and antibody production. Also, lymphocytes have been shown to be prevalent in atherosclerotic lesions and to modulate atherosclerotic responses 127, 128. Natural killer (NK) lymphocytes, CD8+, CD4+ and γδ T-cells were all implicated in atherosclerotic sequelae, further adding to the complexity of atherosclerosis. In patients with OSAHS, most T-cell subpopulations were meticulously investigated in our laboratory. In fact, all T-cells investigated (CD8+, CD4+ and γδ T-cells) expressed an activated and a cytotoxic phenotype.
Assessment of γδ T-cell phenotype and function revealed that expression of CD62L selectins was increased in OSAHS compared with controls. Also, adhesion to endothelial cells and cytotoxicity towards endothelial cells were higher in OSAHS. The higher avidity and cytotoxicity of OSAHS γδ T-cells were mainly attributed to the pro-inflammatory cytokine tumour necrosis factor (TNF)-α. Treatment with antibodies that neutralise TNF-α abolished the cytotoxicity of γδ T-cells against endothelial cells 117.
Unlike in γδ T-cells, adhesion of CD4+ and CD8+ T-cells to endothelial cells was unaffected by OSAHS, but their cytotoxic capacities against endothelial cells were increased. Moreover, the killing capacities of CD8+ T-lymphocytes were also found to be AHI-severity dependent. However, each subpopulation employed different killing mechanisms to damage endothelial cells 88, 116, 117. Unlike in γδ+ T-lymphocytes, which primarily utilised TNF-α for endothelial cell killing, CD8+ T-cells expressed higher amounts of the CD56 NK receptors, higher perforin levels and more than three-fold higher CD40 ligand, accounting for their higher cytotoxicity 116. In CD4+ T-cells of OSAHS patients, the cytotoxic CD4+/CD28-null subpopulation was increased three-fold. All in all, the most potent cytotoxicity against endothelial cells was expressed by OSAHS γδ T-cells; CD8+ cytotoxicity was somewhat lower and that of CD4+ T-cells was the lowest.
Platelets
Platelets maintain vascular homeostasis by clot formation and wound healing. Under physiological conditions, platelets circulate in a quiescent state protected from activation by inhibitory mediators released from intact endothelial cells, including NO. When encountering vascular damage or under oxidative stress, or in response to endothelial dysfunction, platelets rapidly undergo activation. This is followed by increased interactions with monocytes and PMNs and increased adhesion and aggregation in the vessel wall, which implicates their involvement in atherosclerosis 129. Also, in conditions such as hypoxia/reoxygenation, platelets have been shown to acquire an activated and a pro-thrombotic phenotype 130. In patients with OSAHS, platelets have been shown to express increased activation and aggregability in vitro. The expression of P-selectins (CD62P) was increased 131, 132, mainly in the severe group of patients 133, and was lowered by treatment with nCPAP 134. In addition, increased levels of haematocrit, blood viscosity and fibrinogen in patients with OSAHS could further affect hypercoagulability and contribute to the increased incidence of cardiovascular events in OSAHS 135–137.
Jointly, increased expression of adhesion molecules on leukocytes and platelets followed by increased avidity to endothelial cells and higher cytotoxicity of T-cells towards endothelial cells, delayed PMN apoptosis, higher ROS generation by leukocytes and the higher aggregability of platelets, are all markers of activation of these cells and indicative of the possible ongoing processes that may affect endothelial function and elicit atherogenesis in patients with OSAHS. Such cellular interactions of leukocytes and endothelial cells were also demonstrated by intravital microscopy in a rat model of IH 138.
RBCs
The RBCs comprise the major cell type in the circulation. Their main function is oxygen delivery to all tissues and organs. Under normal blood flow their adherence to endothelial cells is nonsignificant and their deformability facilitates tissue perfusion. Under hypoxic/ischaemic conditions, RBCs are capable of inducing and participating in inflammatory responses, most likely through ROS molecules and redox-sensitive transcription factors 139. Moreover, adhesiveness and aggregation of RBCs were shown to be elevated in hypertension 140, atherosclerosis 141 and obesity 142. Increased RBC aggregation/adhesion was also associated with OSAHS, and correlated with increased C-reactive protein (CRP) levels 143. Being the major component in the circulation, the effects of sleep apnoea and IH on RBC functions and adhesive properties should be considered for investigation.
Endothelial cells
Endothelial cells line the vasculature and form the endothelial cell layer, which provides a permeability barrier for the vasculature, regulates vessel tone and maintains an anti-inflammatory and anti-thrombotic phenotype. In their nonactivated state, endothelial cells resist adhesion to leukocytes, platelets and RBCs. However, activation or injury by various factors, such as hypercholesterolaemia, obesity, hypertension and hypoxia/reoxygenation, triggers the expression of adhesion molecules, which mediate these interactions 130, 144. Recently, Jelic et al. 69 demonstrated in vivo activation of endothelial cells in patients with OSAHS. Additionally, both oxidative stress and inflammation were induced by OSAHS while NO bioavailability and the repair capacity of endothelial cells were attenuated 69. Earlier studies indirectly corroborating these findings include identification of soluble variants of endothelial cell adhesion molecules in the circulation of OSAHS patients, such as E- and P-selectin, intracellular adhesion molecule (ICAM)-1 and vascular cell adhesion molecule (VCAM)-1 110, 145–148. Circulating adhesion molecules released from the endothelium are considered as markers of active atherosclerotic diseases and as predictors of future cardiovascular disease 81. Numerous recent studies also investigated apoptosis of endothelial cells and endothelial progenitor cells (EPCs) in OSAHS. Results, however, were inconclusive. While the numbers of circulating apoptotic endothelial cells in patients with OSAHS were lowered after nCPAP in one study 149, no changes were noted in another 150. Conflicting results were also reported on the amounts of EPCs, which at low numbers are indicative of impaired vascular function. While one study described a reduced number of circulating EPCs in OSAHS 151, in another study no differences were noted between patients with OSAHS and controls 150. Such conflicting results can stem from the very small numbers of apoptotic cells or EPCs in the circulation. Thus, more rigorous measures are needed to investigate the involvement of endothelial cell apoptosis or EPC function in OSAHS.
Inflammatory mediators in OSAHS
Cytokines
Similarly to adhesion molecules, pro-inflammatory cytokines are also induced by the redox state of the cells in which they are synthesised. Cytokines actively participate and modulate inflammatory responses by complex interactions with various transcription factors. These multipurpose molecules are synthesised and released by many cell types and regulate both the innate and adaptive immune system. These include regulation of macrophage activation, modulation of smooth muscle cell proliferation, NO production and activation of endothelial cells. Many of these functions are involved in the progression of atherosclerosis.
TNF-α is a pro-inflammatory cytokine involved with the initiation and progression of cardiovascular pathology 152, 153. It is synthesised by a variety of cells including inflammatory leukocytes and adipocytes. TNF-α induces oxidative stress on the endothelium, upregulates endothelial cell adhesion molecules and stimulates cytokine production via NF-κB-dependent pathways. TNF-α is also one of the most studied cytokines in OSAHS. In many of these studies, TNF-α of OSAHS patients was increased in plasma or serum 154–156. Similarly, IL-6, IL-8 and the anti-inflammatory cytokine IL-10 were shown to be affected by OSAHS 9, 155, 157, 158. As IH initiates the inflammatory response, these pro-inflammatory cytokines can in turn activate NF-κB and thus can further exacerbate inflammation. Interestingly, TNF-α was also shown to induce HIF-1α activation via NF-κB-dependent pathways in normoxic conditions 159.
Apart from circulating levels of cytokines, elevated cytokine levels were described in monocytes and in various cytotoxic T-lymphocytes 88, 116, 117, 125. Specifically, in γδ+ T-lymphocytes the pro-inflammatory TNF-α was increased and the anti-inflammatory IL-10 was decreased compared with control values. Also, the expression of IL-8, a pro-inflammatory cytokine with strong chemoattractant and activating properties for PMNs, was shown to increase in γδ T-cells of patients with OSAHS 117. This clearly attests to a pro-inflammatory state of these cells. In CD8+ T-cells, both TNF-α and IL-10 were increased compared with controls. However, TNF-α was increased four-fold whereas IL-10 was increased only 1.3-fold. By contrast, in CD4+ T-cells the percentage of cells expressing TNF-α was unaffected by OSAHS, but the expression of IL-10 was increased 4.9-fold compared with control values 88, 160. Such altered cytokine balance can result in activated T-cells and can lead to their differentiation into effector cells with a tissue-damaging potential or alternatively with the capacity to moderate inflammation depending on these cytokine ratios 124.
Adipokines
In recent years the adipose tissue has gained recognition as a highly active endocrine organ and as a rich source for cytokine production. These cytokines are termed adipocytokines or adipokines due to their source. The key adipokines include TNF-α, IL-6, CRP, leptin, resistin and angiotensinogen 161. Some are also synthesised in other cells and tissues as aforementioned. The blood levels of some of these adipokines are elevated in the obese as well as in patients with OSAHS, resulting in low-grade inflammation in both instances 162. Since the fat tissue represents a major source for cytokines/adipokines, the cytokines released by adipocytes, when measured in the circulation, can pose a problem in identifying their source: whether they are synthesised in obesity per se and/or because of OSAHS. Thus, when obese OSAHS patients are investigated, the contribution of obesity should be separated from that of OSAHS. Such data were clearly demonstrated in obese and overweight patients undergoing surgical treatment 155. In the majority of studies, cytokine/adipokine levels were determined in serum or plasma of OSAHS patients and thus represent the overall pool of cytokines/adipokines released from various inflammatory cells, adipocytes, the liver and other tissues. Therefore, such data cannot provide information on specific inflammatory/anti-inflammatory responses, or on an ongoing process in specific inflammatory cells, as each cell has a unique cytokine profile, as already discussed 160. Adipokines specific for the fat tissue, such as leptin and adiponectin will be discussed in the section on obesity.
CRP
CRP is another molecule potentially linking OSAHS to oxidative stress, inflammation and atherosclerosis, which is secreted primarily by the liver but also by other cell types. It is an acute-phase reactant induced by IL-6, a marker of inflammation and a strong predictor of coronary heart disease and of future cardiovascular events 163, 164. As inflammation and atherogenesis are closely associated with oxidative stress and altered redox balance, analysis was conducted on coronary arteries of patients undergoing atherectomy procedures. Immunohistochemical analysis clearly demonstrated that CRP protein, as well as its mRNA, were co-expressed with NADPH oxidase in vascular smooth muscle cells and macrophages obtained from vulnerable plaques. Moreover, when added to cultured coronary artery smooth muscle cells, CRP had pro-oxidant effects. This suggests that CRP could play a crucial role in plaque instability and acute coronary syndrome via its pro-oxidant effects 165. Another function of CRP that is oxidative stress dependent is its ability to induce tissue factor expression by vascular smooth muscle cells, which implicates it in the pathogenesis of arterial thrombosis 166. In addition, CRP levels were shown to affect endothelial cells and induce their expression of adhesion molecules such as E-selectin, ICAM-1 and VCAM-1 in vitro 167, and to sensitise endothelial cells to killing by T-cells 168. CRP was also shown to inhibit endothelium-dependent NO-mediated dilation in retinal arterioles by initiating superoxide production from NADPH oxidase. This effect was abolished using the antioxidant tempol 169. These diverse effects of CRP on endothelial cells and vascular smooth muscle cells can promote endothelial dysfunction and atherothrombosis. Thus, it is obvious that CRP is not merely an inflammatory marker but rather a modulator of functions that may contribute to the development of inflammatory/atherosclerotic processes via oxidative stress 167.
In OSAHS, the question of whether CRP levels are elevated is controversial. Earlier, CRP was reported to be elevated in a severity-dependent manner 170 and to decrease with nCPAP 157. More recently, however, obesity rather than OSAHS was suggested as a risk factor for elevated CRP 171–175. Current data from the large Wisconsin Sleep Cohort Study support the mediation of obesity in the elevated CRP levels observed in OSAHS 173. However, the fact that CRP levels are also affected by sleep duration 176 makes it difficult to separate the independent contribution of each of the factors affecting CRP in OSAHS. It is likely that all these components contribute to varying degrees. Thus, a patient with OSAHS also having high CRP levels should be considered at a high risk for developing cardiovascular complications regardless of its cause.
OXIDATIVE STRESS IN CONDITIONS AND COMORBIDITIES THAT AGGREGATE WITH OSAHS
Thus far, we have examined the role of oxidative stress in sleep apnoea within the context of IH and its more pronounced consequences such as inflammation 50. However, as will be discussed next, oxidative stress is associated with a variety of conditions such as obesity and sympathetic activation and comorbidities such as hypertension, hyperlipidaemia and diabetes, which aggregate with OSAHS. Hence, in OSAHS there could be a confluence of different potentially independent sources of ROS that could greatly amplify its effects.
Obesity
Obesity is strongly associated with OSAHS. Notably, between 60% and 90% of OSAHS patients are obese 177. Although the nature of this association is not clear, gaining weight aggravates the severity of OSAHS, while drastic weight reduction by controlled diet or by surgical means improves it 178. Obesity, particularly visceral obesity, is also a cardiovascular risk factor, as demonstrated in cross-sectional, clinic-based and population-based studies 76. Similarly to OSAHS, obesity is associated with the male sex, post-menopausal status in females, cardiovascular morbidity, hypertension, stroke, insulin resistance and type 2 diabetes 179. Obesity is also associated with oxidative stress. For instance, in the community-based cohort of the Framingham Heart Study, Keaney et al. 180 demonstrated that smoking, diabetes and BMI were significantly and independently associated with systemic oxidative stress markers. Furukawa et al. 181 demonstrated that, in nondiabetic subjects, fat accumulation was closely correlated with markers of systemic oxidative stress and plasma adiponectin levels were inversely correlated with oxidative stress. Moreover, a drastic weight reduction by surgical intervention attenuated oxidative stress markers, free fatty acids and cholesterol, in the obese 182. A recent review summarising the presence of various oxidative stress markers in plasma, serum, urine and erythrocytes in humans concluded that oxidative stress levels are elevated in human obesity 76. Notably, as OSAHS has not been taken into consideration in studies investigating oxidative stress in obese individuals (this can apply to at least 60% of the obese), the contribution of OSAHS to oxidative stress in the obese cannot be excluded. However, reproducing these results in several mouse models of obesity suggests that accumulated fat contributes to oxidative stress independently of OSAHS. Furthermore, animal models displaying oxidative stress in accumulated fat indicate that it is mediated by the obesity-associated development of metabolic syndrome via dysregulated production of adipokines 181. The mechanisms involved with increased oxidative stress in this animal model include upregulated expression of NADPH oxidase and concomitant decreases in the expression of antioxidant enzymes in adipocytes. Additional suggested sources of oxidative stress in obese individuals include uncoupled mitochondria, free fatty acid-associated protein and lipid peroxidation, decreased antioxidant defence, and leukocytes and endothelial cells 76. Also, other sources of ROS are derived from conditions and comorbidities associated with obesity, such as hypertension, insulin resistance, hyperglycaemia and inflammation 76.
Exposure of adipocytes to hypoxia also elicits dysregulated production of adipokines such as TNF-α, leptin, resistin and adiponectin, which result in low-grade inflammation 183. Similar findings on dysregulated adipokine production and inflammation were also reported in OSAHS 90. Trayhurn and Wood 184 suggested that the inflammation in adipose tissue, in the obese, is a response to hypoxia of enlarged adipocytes distant from the vasculature. Thus, obesity renders adipocytes hypoxic and predisposes the obese to sustained hypoxia 184. Collectively, many of the sources of oxidative stress in the obese are parallel to those in OSAHS. Yet, the lower vascularisation characteristic of fat tissue, which renders it partially hypoxic in a sustained manner, should be considered as well in the obese with OSAHS.
Hyperleptinaemia
Normal leptin production and action through its receptors are essential for regulating body weight and appetite by inhibiting food intake and maintaining energy balance, thus influencing energy expenditure 185. Leptin was also shown to exert angiogenic properties via induction of the redox-sensitive HIF-1α under hypoxic conditions 32, 186. In several studies leptin was shown to increase ROS and the potent vasoconstrictor endothelin (ET)-1, to activate protein kinase C and to promote the secretion of atherogenic compounds 187, 188. The increase in oxidative stress and ET-1 levels by leptin can elicit increased expression of adhesion molecules and recruitment of leukocytes directly damaging endothelial cells and vascular smooth muscle cells and possibly increase blood pressure 76. Also, hyperleptinaemia lowers the antioxidant paraoxonase-1 activity, as previously shown also for OSAHS patients 59, 187. Jointly with the increases in atherogenic factors in the circulation, leptin may further contribute to endothelial dysfunction and the development of atherosclerosis.
In patients with OSAHS, leptin levels were reported to be higher in the majority of studies. Large differences were particularly noted in studies investigating non-obese or at most overweight subjects 108, 189, 190. However, by comparing obese patients with obese controls (BMI >30 kg·m−2), the differences disappeared 189. The association between hyperleptinaemia and OSAHS is supported by observations that long-term nCPAP treatment lowered leptin levels 106, 189, 191, and by data from experimentally induced chronic IH in animal models 192. Notably, the disrupted leptin metabolism due to IH also affected insulin resistance. Thus, it was suggested that elevated leptin levels induced by OSAHS may represent an important compensatory mechanism to minimise metabolic dysfunction 192. However, given the angiogenic properties of leptin, its levels may also rise to compensate for the decrease in oxygen supply due to OSAHS.
Adiponectin
Adiponectin is the most abundant of all circulating adipokines, and is exclusively produced by adipose tissue. It decreases in the obese and in patients with type 2 diabetes, and was shown to correlate with insulin sensitivity 193, 194. Notably, it acts as an anti-diabetogenic and anti-inflammatory cytokine with cardiovascular protective effects. In contrast to leptin, adiponectin attenuates endothelial cell adhesion molecules and the levels of pro-inflammatory cytokines such as TNF-α, IL-8 and IL-6, while increasing the levels of the anti-inflammatory cytokine IL-10. In a rat model of angiotensin (Ang)II-induced hypertension, oxidative stress was increased while attenuating mRNA levels of adiponectin. However, the antioxidant tempol abolished the hypertension, decreased the oxidative stress and increased mRNA adiponectin levels 195. In addition, this has been directly demonstrated in adipose tissue of obese mice and humans. Adipocytes treated with hypoxia in vitro were also shown to have altered adiponectin levels 196. Thus, both hypoxia and oxidative stress greatly attenuate adiponectin levels.
In OSAHS, most studies have reported that adiponectin levels were mainly unaffected by the syndrome. This is particularly evident in studies selecting non-obese, comorbidity-free patients 67, 108, 197. However, adiponectin levels were also shown to increase in obese OSAHS 198, or to decrease in severe patients 199. Notably, decreased adiponectin levels in OSAHS were attributed to obesity 197. In line with the data reporting on unchanged adiponectin levels in OSAHS, long-term nCPAP treatment was also shown to be ineffective 200, 201. As noted earlier, adiponectin is primarily released by adipose tissue and decreases in the obese and yet is affected by oxidative stress. However, the majority of studies show that it is not affected by OSAHS. This may imply that, regarding adiponectin, obesity and increased tissue-specific oxidative stress override the influence of OSAHS.
Sympathetic activation and hypertension
Sympathetic activation is a prominent feature of OSAHS 22–25 and has been linked with hypertension. There is evidence, however, mostly from animal studies, that ROS and oxidative stress participate in cardiac-autonomic signalling 202. Oxidative stress may induce sympathetic hyperactivation and, vice versa, sympathetic activation may increase oxidative stress, thus creating a vicious cycle that greatly affects the cardiovascular system. It was shown that oxidative stress mediates increased expression of inducible nitric oxide synthase (iNOS) in the rostral ventrolateral medulla in rats and thus causes sympathetic activation and blood pressure elevation. Administration of tempol, an antioxidant inhibiting superoxide production, significantly inhibited the pressor response induced by iNOS 203. Likewise, tempol significantly attenuated sympathetic nerve activity in a dose-dependent manner without alterations in mean arterial pressure and heart rate in spontaneously hypertensive rats 204. Increased superoxide production that was mediated by ET-1 was also shown in sympathetic ganglia of hypertensive rats. These data indicate that a change in the redox environment of sympathetic ganglionic neurons may activate sympathetic neurons and result in vasoconstriction and hypertension 205. In fact, a great number of animal studies have demonstrated an association between hypertension and increased formation of ROS and impaired endogenous antioxidant defence mechanisms 206. Both AngIIb and ET-1 were implicated in ROS formation accompanied by vasoconstriction and hypertension in rat vasculature. Furthermore, treatment with SOD, which scavenges superoxide, reduced blood pressure 206. ROS formation was increased via activation of vascular NADPH oxidase and xanthine oxidase, and resulted in increased oxidative stress markers in heart vessels and various other tissues 206, 207. It should be noted that AngII also induced insulin resistance in skeletal muscle that was mediated by NF-κB activation via NADPH oxidase 208. Similarly, ET-1, another potent vasoconstrictive and mitogenic peptide with blood pressure-elevating properties, was also shown to induce hypertension via ROS formation. The source of ROS was also shown to be NADPH oxidase in the vasculature 209.
Two recent studies in animal models implicate oxidative stress in the development of hypertension by exposure to chronic IH. In one study, ROS formation directly increased the production of ET-1 and thus also increased hypertension. Treatment with the antioxidant tempol prevented the increase in blood pressure and lowered oxidative stress and plasma ET-1 210. In another study, Peng et al. 55 demonstrated that arterial blood pressure, plasma noradrenalin and oxidative stress markers were increased in a mouse model of chronic IH. Treatment with a potent superoxide scavenger lowered blood pressure and attenuated noradrenalin and oxidative stress. Conversely, chronic IH treatment of a mouse model partially deficient in HIF-1α did not increase mean blood pressure, adrenalin or oxidative stress. This study not only implicates free radicals in the development of hypertension due to IH but also implicates HIF-1α activation and the complex interactions between oxidative stress and HIF-1α in affecting blood pressure due to IH.
Jointly, the results from animal studies suggest that, in OSAHS, oxidative stress could be one of the mediating factors between IH, AngII, ET-1 and hypertension. Data from patients with OSAHS are mostly in agreement with the animal studies. AngII and ET-1 were reported to be elevated in OSAHS and were correlated with blood pressure, while long-term nCPAP attenuated blood pressure. The decrease in blood pressure was correlated with lower plasma renin and AngII levels 211. However, delineating the complex interactions between sympathetic activation, AngII, ET-1, HIF-1α and oxidative stress in humans may prove difficult.
Dyslipidaemia
Dyslipidaemia is also a prevalent finding among sleep apnoea patients. Increased total serum cholesterol and triglyceride levels and decreased HDL independent of age and BMI were shown in epidemiological studies and in matched case–control studies of sleep apnoea patients 107, 108. Additionally, dysfunctional HDL 77 and lower antioxidant activity of paraoxonase-1 bound to HDL were detected in patients with OSAHS, particularly in those who also had cardiovascular comorbidities 59. Effective amelioration of the apnoeas with nCPAP treatment lowered serum total cholesterol levels 109. Animal models treated with chronic IH also demonstrated increased hypercholesterolaemia and accelerated atherosclerosis, which are directly attributed to the IH via activation of SREBP 100, 104. Hypercholesterolaemia has a profound effect on endothelial function. In relatively short periods (within days), hypercholesterolaemia can alter the phenotype of endothelial cells from anti-inflammatory/anti-thrombotic to pro-inflammatory/pro-thrombotic phenotype. The altered vascular phenotype in hypercholesterolaemia is largely attributed to increased oxidative stress, which also results in a decreased bioavailability or bioactivity of NO, increased expression of adhesion molecules and increased leukocytes/platelets/endothelial cell interactions 212, 213. Notably, hypercholesterolaemia, even in an acute state, induces oxidative stress via activation of NADPH oxidase or xanthine oxidase, yet the initiating factors remain elusive 213. Hence, IH in sleep apnoea could be one possible initiating factor.
Insulin resistance and type 2 diabetes
Oxidative stress was also suggested to be one of the major causes of hyperglycaemia and diabetes, since it was shown to impair glucose uptake in muscle and fat and to decrease insulin secretion from pancreatic β-cells 214–216. Conversely, hyperglycaemia was also shown to trigger increased formation of ROS via glucose auto-oxidation. Accordingly, consumption of a high free-glucose diet promoted the development of oxidative stress 217. Increased production of free radicals in diabetic patients was also shown by protein glycation and the formation of glycosylation end-products 218, 219. In the insulin-resistant obese Zucker rat, acute pro-oxidant challenge in vivo exacerbated insulin resistance, impaired glucose tolerance and promoted the onset of type 2 diabetes 220. Activation of NF-κB 221 and increased NADPH oxidase activity were suggested as likely mechanisms in this sequence 208. Furthermore, in both type 1 and type 2 diabetes, the late diabetic complications in neurons, vascular endothelium and kidney arise from common stress-activated signalling pathways such as NF-κB and p38 MAPK 222. The facts that elevated insulin levels generate free radicals by NAD(P)H-dependent mechanisms 223, and that plasma concentrations of inflammatory mediators, such as TNF-α and IL-6, are increased in the insulin-resistant states of obesity and type 2 diabetes, support the involvement of oxidative stress in atherogenesis and cardiovascular sequelae in diabetes 224.
Although it is not clear if OSAHS causes diabetes, insulin resistance was shown to be independently associated with OSAHS in severity-dependent measures such as AHI and minimum oxygen saturation. However, obesity is also a major determinant in insulin resistance 225. Punjabi et al. 226 have shown that sleep-disordered breathing is a prevalent finding in mildly obese males and is independently associated with glucose intolerance and insulin resistance. This association was verified in large-scale epidemiological studies of the Wisconsin Sleep Cohort and the Sleep Heart Health Study 227, 228. Additionally, treatment with nCPAP immediately restored blood glucose levels, mainly in non-obese OSAHS patients 229, although improvement was also noted in diabetic OSAHS patients 230. This, however, was not shown in all studies 201.
SUMMARY
The accumulated evidence presented in this review is illustrated by the tentative model presented in figure 2, which introduces oxidative stress as the unifying link between OSAHS and the conditions and comorbidities that aggregate with OSAHS.
Obesity can develop independently, due to genetic, behavioural or lifestyle-related variables, but it is suggested that it may also induce or exacerbate OSAHS. Conversely, OSAHS may also induce or exacerbate obesity. Thus, obesity and OSAHS may exacerbate each other, yet both promote oxidative stress. OSAHS via IH, and obesity through sustained hypoxia, can activate enzymes such as NADPH oxidase, xanthine oxidase, complex I in mitochondria and uncoupled eNOS, to produce ROS.
Once oxidative stress is initiated it affects multiple systems. By reaction of ROS with NO, oxidative stress is increased while NO is diminished, thus promoting inflammation and endothelial dysfunction. Oxidative stress can also induce sympathetic activation and increases in AngII and ET-1 and, therefore, may promote hypertension. At the same time, oxidative stress can induce the upregulation of numerous redox-sensitive transcription factors, such as HIF-1α, NF-κB, SREBPs and GATA. Also, insulin resistance is affected by oxidative stress and, when combined with upregulated NF-κB activity, may promote type 2 diabetes. Dyslipidaemia may develop via upregulation of SREBP. Upregulated HIF-1α activity may be involved in the development of hypertension and induction of hypertriglyceridaemia via SREBP activation. HIF-1α is also upregulated in obesity. Diabetes, dyslipidaemia, obesity and hypertension, as well as OSAHS, are involved with NF-κB activation and inflammation. Inflammatory pathway activation is characterised by increased expression of adhesion molecules, cytokines, adipokines, CRP, activated blood cells and endothelial cells.
Many of the inflammatory pathways activated by NF-κB, such as TNF-α, further induce oxidative stress through activation of NADPH oxidase. In many of the pathways, the conditions and comorbidities that develop can further induce oxidative stress, thus creating a vicious cycle of oxidative stress and inflammation. The possible interactions described in this review are much more complex than could be depicted in figure 2. For instance, AngII, through NF-κB activation, may induce NADPH oxidase activation and insulin resistance. ET-1 may activate GATA-4, which could prevent cardiomyocyte apoptosis by oxidative stress [112]. The involvement of HIF-1α in upregulation of leptin and the effects of hyperleptinaemia on oxidative stress and inflammation, as well as additional interactions between obesity and oxidative stress, have been illustrated previously [76]. Details of possible intricate interactions between NF-κB and HIF-1α have been described elsewhere [159].
CONCLUSION
In recent years a large body of evidence has implicated oxidative stress, inflammation, sympathetic activation, obesity and hyperlipidaemia as fundamental components in the pathophysiology of cardiovascular morbidity in OSAHS. The data presented in this review demonstrate that ROS play a significant role in a great number of pathologies and conditions that aggregate with OSAHS (fig. 1⇑). Although the specific pathways and sites (tissues) at which ROS are generated and induce damage may vary from one condition to another, their involvement in signalling pathways, particularly those activating inflammatory/immune sequences, is common to all conditions. Thus, obesity, hypertension, hyperlipidaemia, hyperleptinaemia and insulin resistance all share with sleep apnoea ROS-dependent pathway activation and inflammatory responses, which ultimately lead to endothelial dysfunction and atherosclerosis. In some of these conditions and comorbidities it is not always clear what the initiating factor is. These comorbidities could develop independently of OSAHS due to genetic, hormonal, nutritional or lifestyle-related variables, or be a direct consequence of OSAHS. Thus, metabolic dysregulations and obesity that aggregate with OSAHS could be in many instances a consequence of sleep apnoea. That is, the apnoeas related to IH and the ensued oxidative stress, followed by the chain of events described in figure 2⇓, may orchestrate the simultaneous or sequenced development of sympathetic nerve activity, hypertension, hyperlipidaemia, insulin resistance and diabetes. However, obesity could be a likely candidate for an initiating factor. Regardless, however, of who preceded whom, whether sleep apnoea or metabolic dysregulation, it is obvious that once sleep apnoea develops and aggregates with the aforementioned conditions, the oxidative stress it initiates night after night becomes a central factor in eliciting the cascade of events that eventually result in cardiovascular morbidities. Also, it is not always clear which comes first, oxidative stress or inflammation, as both are fundamental components in each of the conditions and comorbidities that aggregate with sleep apnoea. Furthermore, as most OSAHS patients are obese, sustained hypoxia, which is characteristic of adipose tissue, may also contribute to oxidative stress in addition to the IH, and may activate different ROS-dependent signalling pathways as well. Thus, clarifying various pathways of activation in the obese apnoeic patient would prove difficult, or incorrect, for understanding sleep apnoea-related mechanisms. This also could explain some of the contradictory results in the literature regarding oxidative/inflammatory markers in OSAHS.
In order to clarify basic mechanisms imposed by intermittent hypoxia, more in vitro studies at the cellular level and animal studies should be conducted. Using specific cells, such as endothelial cells, cardiomyocytes, adipocytes, hepatocytes and blood cells, under intermittent and sustained hypoxic conditions, could help to delineate cell-specific mechanisms. Complementary studies, employing various transgenic and knockout mice for specific genes, could further expand our understanding of the basic mechanisms that are governed by intermittent hypoxia.
Support statement
This study was supported in part by a grant from the United States–Israel Binational Science Foundation (Jerusalem, Israel), grant no. 1006695.
Statement of interest
A statement of interest for P. Lavie can be found at www.erj.ersjournals.com/misc/statements.dtl
- Received June 7, 2008.
- Accepted February 25, 2009.
- © ERS Journals Ltd
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