Obesity is now assuming epidemic proportions worldwide. Elevated arterial pressure is a frequent complication of excess body weight, and both obesity and hypertension are components of insulin-resistance syndrome [1,2]. Many obese hypertensive patients tend to develop type-2 diabetes mellitus, which further increases their cardiovascular risk. While lifestyle modification is the key to weight and blood pressure reduction, pharmacological intervention remains essential to lowering blood pressure to target levels in obese patients with hypertension. Antihypertensive drugs such as thiazide diuretics and β-blockers adversely affect glucose metabolism and increase the risk of developing type-2 diabetes [3-6], though this has been disputed [7-11]. On the other hand, drugs that interfere with the renin–angiotensin system (RAS) improve insulin sensitivity, produce a significant decline of albuminuria, induce a drop of the pathological glomerular hyperfiltration, and reduce the incidence of new-onset diabetes [12-17]. Therefore, the initial selection of antihypertensive therapy for obese patients could have a significant influence on their overall cardiovascular risk. In this context, the beneficial actions of angiotensin-converting enzyme inhibitors and angiotensin-II receptor blockers in the prevention or postponement of the development of type 2 diabetes mellitus in hypertensives who are at high risk of development of type 2 diabetes mellitus needs a closer look [18, 19].
Free Radicals, Nitric Oxide (No), Eicosanoids, Pro- and Anti-Inflammatory Cytokines, and Long-Chain Polyunsaturated Fatty Acids (Pufas) in Hypertension and Type 2 Diabetes Mellitus
There is a close association between hypertension and type 2 diabetes mellitus that could be attributed to the involvement of free radicals, nitric oxide (NO), eicosanoids, pro- and antiinflammatory cytokines, long-chain polyunsaturated fatty acids (PUFAs) and their metabolites, folic acid, and vitamin C in the pathogenesis of both hypertension and type 2 diabetes mellitus. For example, under physiological conditions, a balance is maintained between endothelial vasoconstrictors and vasodilators such that normal blood pressure is maintained. When this balance is altered more in favor of vasoconstrictors and/or when the concentrations of vasodilators are reduced, hypertension develops. One mechanism by which endothelium-dependent vasodilatation is impaired is due to an increase in the oxidative stress that inactivates NO and PGI2 (prostacyclin). Polymorphonuclear leucocytes of patients with uncontrolled essential hypertension produce significantly large amounts of superoxide anion and hydrogen peroxide (H2O2), and lipid peroxides, indicating that an increase in oxidative stress occurs in hypertension [20-23]. In addition, a decrease in the levels of superoxide dismutase (SOD), catalase, glutathione peroxidase, and vitamin E in the RBC membranes of uncontrolled hypertensives was noted. These biochemical abnormalities revert to normal after the control of hypertension. Thus, decreased NO bioavailability and increased superoxide anion generation due to enhanced NAD(P)H oxidase activity could be responsible for oxidative stress seen in hypertension. These evidences coupled with the observation that a graded positive relationship exists between blood pressure and levels of intercellular adhesion molecule-1 (ICAM-1) as well as IL-6 was in healthy men suggests that low-grade systemic inflammation occurs in hypertension.
In a similar fashion, plasma levels of C-reactive protein (CRP), tumor necrosis factor-α (TNF-α), and interleukin-6 (IL-6) are elevated in subjects with type 2 diabetes, indicating the existence of low-grade systemic inflammation in diabetics too. Dietary glycemic load is significantly and positively associated with plasma CRP (26), suggesting that hyperglycemia induces inflammation. Since low-grade systemic inflammation occurs both in hypertension and type 2 diabetes mellitus, it is not surprising that blood pressure progression is a strong and independent predictor of occurrence of type 2 diabetes in hypertensives. In view of the overlap biochemical abnormalities in obesity, type 2 diabetes, hypertension, and insulin resistance such as cytokines, adipokines, reactive oxygen species, antioxidants, and NO, it is reasonable to suggest that low-grade systemic inflammation is the underlying pathophysiological process in them.
Angiotensin-II is Proinflammatory in Nature
Several studies indicated that ACE inhibitor therapy reduces the development of type 2 diabetes in persons with essential hypertension, a population with a high prevalence of insulin resistance. ACE inhibitor therapy has been shown to improve surrogates of cardiovascular disease (e.g., vascular compliance, endothelial-derived nitric oxide production, vascular relaxation and plasma markers of inflammation, oxidative stress, and thrombosis) and reduce cardiovascular disease, renal disease progression, and stroke . These anti-inflammatory actions of ACE inhibitors and angiotensin-II receptor blockers may explain their possible beneficial action in the prevention of development of type 2 diabetes mellitus in those who were given these drugs for the management of hypertension. This implies that enhanced circulating levels of renin, angiotensin-II, and aldosterone as a result of overactive renin–angiotensin–aldosterone system could predispose or initiate the development of insulin resistance, type 2 diabetes mellitus, and metabolic syndrome in subjects with hypertension. This is supported by the observation that angiotensin-II is pro-inflammatory in nature and angiotensin-II receptor blockers and angiotensin-II antagonists have anti-inflammatory actions [28,29]. Since both hypertension and type 2 diabetes mellitus are low-grade systemic inflammatory conditions, this amply supports the involvement of renin–angiotensin system in the pathobiology of hypertension and type 2 diabetes mellitus.
Ras and Food Intake
Since obesity is common in subjects with insulin resistance, hypertension, and type 2 diabetes mellitus, and obesity results from increased intake of energy-dense food, it is reasonable to propose that, in all probability, renin–angiotensin–aldosterone system (RAS) and/or angiotensin-II, the principal hormone of the RAS, may have a role in food intake. Sasaki et al  noted that consumption of total lipids, cholesterol, and unsaturated free fatty acids was higher in MM/ MT of AGT (angiotensinogen) Met235Thr than TT polymorphism. However, it was observed that the AGT polymorphism (rs7079), and the ACE I/D were not associated with food preferences. In contrast, it was noted that the ADRB3 Trp64 (adrenergic β3 receptor = ADRB3 gene) polymorphisms tended to show high-energy intake and preferences to protein and lipids including fatty acids and cholesterol. These studies led to the conclusion that AGT Met235Thr polymorphism was significantly associated with higher caloric intake due to total fats and carbohydrate consumption, emphasizing the importance of angiotensin-II and adrenergic β3 receptor in higher caloric intake due to total fats and carbohydrate consumption.
The regulatory role of RAS in the control of water and sodium intake is well documented by its action on kidney and brain that may also explain the role of central renin– angiotensin system in the pathogenesis of hypertension [30-33]. It was reported that intracerebroventricular (ICV) infusion of the angiotensin antagonist [Sar1,Thr8]-AII, effectively lowered the blood pressure in normotensive rats. These and other studies led to the conclusion that perturbations of the endogenous brain–angiotensin system are effective at rapidly influencing both cardiovascular and body fluid homeostasis . Some of these actions of Ang-II seem to be mediated by its stimulatory action on the release of vasopressin  and its action on the paraventricular nucleus of the hypothalamus, a center that is known to be an important site of integration for sympathetic outflow. When renal sympathetic nerve discharge (RSND), arterial blood pressure (AP), and heart rate (HR) were measured in response to administration of ANG II and N(G)-monomethyl-l-arginine (L-NMMA) into the PVN, it was noted that Ang-II (0.05, 0.5, and 1.0 nmol) into the PVN increased RSND, AP, and HR in a dose-dependent manner. These responses were significantly enhanced by prior microinjection of l-NMMA and administration of antisense to neuronal NO synthase within the PVN and were blocked by losartan, an Ang-II type 1 receptor antagonist. Conversely, overexpression of neuronal nitric oxide synthase (NOS) within the PVN with adenoviral gene transfer significantly attenuated Ang-II responses, whereas Ang-II (1 nmol) when injected into the PVN induced an increase in NO release. These results indicate that Ang-II type 1 receptors within the PVN mediate an excitatory effect on RSND, AP, and HR, while NO in the PVN, which can be induced by ANG II stimulation, in turn inhibits the Ang-II-mediated increase in sympathetic nerve activity. This negative feedback mechanism within the PVN may play an important role in maintaining the overall balance and tone of sympathetic outflow [37-39] and suggests that Ang-II and NO interact with each other and regulate water and sodium intake and blood pressure by their central action, an action that is predominantly mediated by Angtype 1 (AT(1)) receptor. Subsequent studies revealed that Ang-II acts through G protein-coupled receptors of two pharmacological classes, AT(1) and AT(2), wherein AT(1) receptors, expressed in brain and peripheral tissues, mediate blood pressure homeostasis and regulation of drinking and water balance. In rodents, two highly homologous AT(1) receptor isoforms, termed AT(1A) and AT(1B) receptors, expressed in major forebrain cardiovascular and fluid regulatory centers, with AT(1A) regulating the blood pressure in response to centrally administered angiotensin II while the drinking response is mediated by AT(1B) receptors.
Ras and Body Weight
Furthermore, Ang-lI decreases body weight by its ability to stimulate sympathetic neurotransmission to interscapular brown adipose tissue (ISBAT), which is characterized by enhanced release of norepinephrine (NE) from ISBAT sympathetic nerve terminals. Increased sympathetic neurotransmission to ISBAT may contribute to Ang-lIregulation of body weight  that suggests that Ang-II regulates body weight through mechanisms related to increased peripheral metabolism and independent of elevations in blood pressure . This is supported by the observation that angiotensinogen-deficient mice exhibit impairment of diet-induced weight gain with alteration in adipose tissue development and increased locomotor activity , have increased energy expenditure, with reduced fat mass, and improved glucose clearance [44, 45], events that are in support of the beneficial actions of angiotensin-converting enzyme inhibitors and angiotensin-II receptor blockers in the prevention or postponement of the development of type 2 diabetes mellitus in hypertensives [18, 19].
Central AT(1) receptor signaling plays a homeostatic role in the regulation of food intake by maintaining gene expression of corticotropin-releasing hormone in hypothalamus . Ang-II acts in the brain to promote negative energy balance by altering the hypothalamic circuits regulating energy balance that include increased uncoupling protein-1 and β(3)-adrenergic receptor expression in brown adipose tissue and β3-adrenergic receptor expression in white adipose tissue, suggesting enhanced sympathetic activation and thermogenesis; decrease food intake, increase in energy expenditure , and finally Ang II type-1a receptor-dependent Ang-II signaling reduces food intake by suppressing the hypothalamic expression of neuropeptide Y and orexins via AMPK dephosphorylation .
Ras, Estrogen, and Lipoxin A4
In this context, it is noteworthy that ovariectomized (OVX) female rats treated with estradiol benzoate (EB) had a 30–40% reduction in the levels of AT-I receptor mRNA in pituitary and HTS (hypothalamic-thalamic-septa) tissue samples as compared to OVX, control animals. In the pituitary, the mRNA levels for angiotensinogen (AGT) were increased by 45% following estrogen administration. In addition, a reduction in [125I]-AngII binding to AT-I receptors in the pituitary and the subfornical organ following estrogen treatment was noted. These results suggest that estrogen modulates the pituitary and central RAS through a coordinate regulation of the angiotensin receptors and the levels of newly synthesized Ang-II , which may explain sex-dependent changes in the response of male and females to Ang-II antagonists and Ang-II receptor blockers.
Estrogen reduces appetite by its action in the brain in a way similar to leptin. But, the clinical use of estrogen to reduce body weight and appetite limited due to the severity of its side effects, especially increased incidence of cancer after its use. Anorexigenic effects of estrogen are strongly linked to its action on hypothalamic pro-opiomelanocortin (POMC) neurons in the arcuate nucleus . Estrogen induces rapid synaptic plasticity in the arcuate nucleus, an effect similar to those of leptin .
Estrogen augments synthesis of lipoxin A4 (LXA4), a potent anti-inflammatory bioactive lipid formed from arachidonic acid (AA). Lipoxins are a group of nonclassic eicosanoids that possess potent anti-inflammatory and proresolution properties[53-58]. Endometrium contains 15-LOX-2, an enzyme necessary for lipoxin biosynthesis. LXA4 showed robust estrogenic activity through its capacity to alter estrogen receptor transcriptional activity, as well as expression of estrogen-regulated genes and proliferation of human endometrial epithelial cells. The actions of LXA4 are exclusively mediated through estrogen receptor and closely mimic those of the potent estrogen, 17β-estradiol. LXA4 exhibited estrogenic activity in vivo, increasing uterine wet weight and modulating 17β-estradiol regulated gene expression . These studies [59-62] suggest that LXA4 mediates anti-inflammatory actions of estrogen. Since LXA4 induces the production and release of eNO [63-65], this implies that estrogen induced LXA4 synthesis, which, in turn, enhances eNO generation. The broader implication of the action of estrogen on LXA4 synthesis is that several beneficial actions of estrogen could be mediated by LXA4. Some of these actions could include its (estrogen) anti-inflammatory, antiatherosclerotic, antihypertensive, vasodilator, and anti-preeclamptic actions. In addition, exercise that is beneficial in the prevention and management of obesity, type 2 diabetes mellitus, hypertension, and metabolic syndrome also augments LXA4 formation. This implies that LXA4 may function as an endogenous antidiabetic and antihypertensive molecule  and may function as a physiological antagonist of Ang-II.
It is evident from the preceding discussion that RAS and Ang-II, in particular, does influence food intake, energy expenditure, and development of obesity and type 2 diabetes mellitus apart from its influence on water, salt balance, and blood pressure (Figure 1).
In the light of these facts, it would be interesting to study plasma levels of ghrelin, cholecystokinin, GLP-1 (glucagon-like peptide-1) and other incretins, LXA4, and vagal tone and correlate them to changes in body weight, food intake, insulin resistance, and glucose tolerance in the transgenic mouse model overexpressing renin in the liver (RenTgMK). It is suggested that RAS will have a modulatory action on LXA4 synthesis. It is predicted that angiotensin-II may suppress LXA4 formation and thus bring about its pro-inflammatory actions, while Ang-II and Ang-II receptor antagonists promote LXA4 formation. This implies that plasma levels of LXA4 could be used as a marker of the actions of Ang-II and Ang-II receptor antagonists: plasma LXA4 levels would increase when the dose and action of Ang-II and Ang-II receptor antagonists are optimal. Thus, there could occur an integrated and coordinated interaction(s) among RAS, estrogen, ghrelin, cholecystokinin, GLP-1 (glucagon-like peptide-1), and other incretins, hypothalamic neurotransmitters and neuropeptides, LXA4, and vagal tone that ultimately determines appetite, food intake, autonomic nervous system tone and function, development of hypertension, obesity, metabolic syndrome, and type 2 diabetes mellitus (Figure 1). A better understanding of such interaction(s) could lead to more targeted therapeutic and preventive strategies for obesity, hypertension, and metabolic syndrome.
Conflict of Interest
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