Abstract

Obesity, hypertension, and type 2 diabetes are rapidly growing public health problems. Heightened sympathetic nerve activity is a well-established observation in obesity, hypertension, and type 2 diabetes. Human obesity, hypertension, and diabetes have strong genetic as well as environmental determinants. Reduced energy expenditure and resting metabolic rate are predictive of weight gain, and the sympathetic nervous system participates in regulating energy balance through thermogenesis. The thermogenic effects of catecholamines in obesity are mainly mediated via the β2, and β3-adrenergic receptors in humans. Further, β2-adrenoceptors importantly influence vascular reactivity and may regulate blood pressure. β-adrenoceptor polymorphisms have also been associated with adrenoceptor desensitization, increased adiposity, insulin resistance, and enhanced sympathetic nervous activity. Many epidemiological studies have shown strong relationships between adrenoceptor polymorphisms and obesity, but the observations have been discordant. This paper will discuss the current topics involving the influence of the sympathetic nervous system and β2- and β3-adrenoceptor polymorphisms in obesity.

1. Introduction

Obesity is a major and growing health problem. Importantly, the presence of increased adiposity is associated with elevated risk of development of cardiovascular and renal complications [14]. Obesity is frequently associated with hypertension, diabetes, and metabolic syndrome [57], and sympathetic nervous activation is frequently observed in those conditions [8]. Thus, sympathetic nerve activation may play a major role in the onset and development of obesity, hypertension, and the development of the metabolic syndrome as well as controlling to the cardiovascular complications evident in patients with hypertension, diabetes, and obesity [2, 4, 9].

The sympathetic nervous system plays an important role in the regulation of energy expenditure. Reduced energy expenditure and resting metabolic rate are predictive of weight gain (obesity). Furthermore, blunted sympathetic nervous responses to energy intake have been observed in obese subjects with the metabolic syndrome and insulin resistance [10, 11]. The sympathetic nervous system participates in regulating energy balance through thermogenesis [12]. Recently, the important relationships of brown adipose tissue for energy expenditure [1315] were argued, however a large part of the sympathetic nervous system-mediated energy expenditure takes place in skeletal muscle, via the coupling of catecholamines with β2-adrenoceptors. Catecholamines are also powerful regulators of lipolysis and act via β1-, β2-, β3-(stimulatory), and α2-(inhibitory) adrenoceptor subtypes in adipose tissue, where their role becomes especially important during both exercise and energy restriction, when increased need for fat as a fuel exists. Thus, β-adrenoceptors play important roles in energy expenditure and control body weight [1620].

Recent evidence indicates that human obesity indeed has a genetic component with [2123] several epidemiological and clinical studies indicating a strong linkage between β-adrenoceptor polymorphisms and obesity or weight gain [24, 25]. Furthermore, heightened sympathetic nervous system activity associated with β2- and β3-adrenoceptor polymorphisms predicts subsequent weight gain and blood pressure elevation in originally nonobese subjects [11, 24], and rebound weight gain after significant weight loss in obese subjects [26]. β2-adrenoceptor polymorphisms are related to the onset of insulin resistance [27] and blunted responses of sympathetic nerve activity to acute hyperinsulinemia [10, 11, 2729]. These findings show that the genetic background, especially β2- and β3-adrenoceptor polymorphisms, are associated with sympathetic nervous system activation, and are important in the pathogenesis of obesity-related hypertension and insulin resistance. Many investigations regarding the relationships between β-adrenoceptor polymorphisms and obesity have been analysed; however, the results are discordant [3032].

2. Role of the Sympathetic Nervous System in Obesity

Many epidemiological and clinical studies have demonstrated a close relationship between sympathetic nervous activation and insulin levels in obesity [3337]. Several longitudinal studies have examined the effect of body weight changes (weight loss or weight gain) on sympathetic nervous system activity and insulin sensitivity (fasting plasma insulin levels and HOMA-IR). Elevated activity of the sympathetic nervous system and increased insulin levels during weight gain [16, 24, 26, 38, 39] and reductions of sympathetic nerve activity and insulin levels during weight loss [4045] have been observed. In obese normotensive subjects, a reduction in body weight induced exerts a marked reduction in sympathetic activity owing to central sympathoinhibition due to the consequences of an increased insulin sensitivity and a restoration of the baroreflex [45]. These studies have clearly shown heightened sympathetic nerve activity and insulin resistance are closely linked to weight gain and the onset and maintenance of obesity.

Landsberg et al. [4648] and Julius et al. [49] have proposed hypotheses to explain the mechanism linking the sympathetic nervous system and insulin resistance in obesity. The former proposes that hyperinsulinemia and insulin resistance in obese subjects are all part of a response to limit further weight gain via stimulating sympathetic nervous activity and thermogenesis [50], and the latter indicates that sympathoexcitation in the skeletal muscle vascular bed cause neurogenic vasoconstriction and reduction in blood flow to muscle and consequently induces a state of insulin resistance by lowering glucose delivery and uptake in hypertension and obesity. Masuo et al. in a series of longitudinal studies observed that heightened sympathetic activity was the prime mover for future weight gain in originally nonobese, normotensive subjects, and that insulin resistance was more an ancillary factor [24, 51, 52]. In investigations examining the effect of weight loss, reductions in plasma norepinephrine followed by reductions in HOMA-IR as a marker of insulin resistance were significantly greater in subjects experiencing significant weight loss compared to those without significant weight loss [26, 40, 43]. These observations provide some support for the hypothesis of Julius and colleagues.

Valentini et al. [53] reported attenuation of hemodynamic and energy expenditure responses to isoproterenol infusion in hypertensive patients. Their findings that a generalized decrease of β-adrenergic responsiveness in hypertension supports the hypothesis that heightened sympathetic nerve activity, through downregulation of β-adrenoceptor-mediated thermogenesis, may facilitate the development of obesity in hypertension. Their results suggested that sympathetic nerve activity-induced hypertension may subsequently lead to the development of obesity.

3. Role of β-Adrenoceptor Polymorphisms in Obesity

The sympathetic nervous system plays an important role in the regulation of energy expenditure. A large part of the sympathetic nervous system-mediated energy expenditure takes place in skeletal muscle, via the coupling of catecholamines with β2-adrenoceptors [54]. Catecholamines are also powerful regulators of lipolysis and act via β1-, β2-, β3-(stimulatory) and α2-(inhibitory) adrenoceptor subtypes in adipose tissue, where their role becomes especially important during both exercise and energy restriction, when increased need for fat as a fuel exists. Stimulation of β-adrenergic receptors by the sympathetic nervous system is a significant physiological modulator of pre- and postprandial energy expenditure [1820] and total daily energy expenditure [16, 17, 50]. The subtypes of adrenoceptors on lipid and glucose metabolisms are summarized as following; α1-adrenoceptors, glycogenolysis and gluconeogenesis in adipose tissue and liver; α2-adrenoceptors, induction of glucagon release from pancreas; β1-adrenoceptors, lipolysis in adipose tissue; β2-adrenoceptors, glycogenolysis and gluconeogenesis in adipose tissue and liver; β3-adrenoceptors, lipolysis on adipose tissue.

Recent studies show that β-adrenoceptors are polymorphic with single nucleotide polymorphisms exerting functional consequences in terms of receptor activity and regulation and hence perhaps may contributing to the pathophysiology of obesity and hypertension [24, 25, 5559]. On the other hand, there are few studies on the relationships between α-adrenoceptor polymorphisms and obesity.

3.1. β1-Adrenoceptor Polymorphisms (Table 1)

The β1-adrenoceptor is predominantly expressed in cardiac myocytes and adipose tissue, where its activation leads to increased heart rate and contractility and stimulation of lipolysis, respectively. The β1-adrenoceptor is a candidate gene for obesity because of its role in catecholamine-mediated energy homeostasis. In obese individuals, the degree of weight loss during a very low calorie diet has been shown to correlate with changes in β1-adrenoceptor protein concentration in adipose tissue [65]. The two most common β1-adrenoceptor polymorphisms are Ser49Gly and Arg389Gly, with relative allele frequencies of 0.85/0.15 and 0.70/0.30 in Caucasian population, respectively. An investigation involving a population cohort of 761 women indicated that women carrying the Gly49 genotype had greater elevation in BMI over 15 years compared to those with the Ser49 genotype [62]. Again, in Caucasian women ( ), Dionne et al. [60] observed that the Gly389Arg, β1-adrenoceptor variant exhibited a strong relationships with obesity. Conversely, Gjesing and colleagues found that the distribution of the Arg389Gly polymorphism was similar in lean and obese subjects, suggesting that it has no important influence on human obesity [63, 66]. Although earlier small case-control studies demonstrated an increase in the risk of hypertension in Arg389 homozygotes [67, 68], a recently published study comprising 3981 normotensive and 2,518 hypertensive patients failed to replicate this association [63] (summarised in Table 1). Arner [67] reviewed that Arg389Gly polymorphism in the β1-adrenoceptor, which alters receptor function in transfected cell lines, and concluded that the SNP has no effect on lipolysis in human fat cells and is not associated with obesity.

3.2. β2-Adrenoceptor Polymorphisms (Table 2)

The β2-adrenoceptor is the dominant lipolytic receptor in white human adipose tissue [20, 55, 56] and in skeletal muscle [19, 57]. Gln16Glu and an Arg164Ile variation in the β2-adrenoceptor cause marked variations in the lipolytic sensitivity of this receptor in human adipocytes. Multiple β2-adrenoceptor polymorphisms including haplotypes, markedly influence β2-receptor function- and catecholamine-induced lipolysis in fat cells [76]. These haplotypes may be important genetic factors behind impaired lipolysis in obesity [25].

The β2-adrenoceptor also plays an important regulatory role in the peripheral vasculature. Genetic polymorphisms of the β2-adrenoceptor have been associated with obesity, hypertension, and diabetes mellitus. The most common polymorphisms are Arg16Gly, with an allele frequency of 0.40/0.60 and Gln27Glu, with an allele frequency of 0.55/0.45 in the Caucasian population. The Thr164Ile polymorphism is rare, occurring in only 3 to 5% of the general (Caucasian) population.

Studies of agonist stimulation in cultured cells demonstrate that Gly16 receptors have a greater reduction in numbers or enhanced downregulation when compared with Arg16, whereas the Glu27 receptor is resistant to down regulation when compared with the Gln27 variant [77]. A number of clinical studies have investigated the impact of these polymorphisms on vascular responsiveness [55, 78]. Gratze et al. [79] found that young normotensive white men homozygous for the Gly16 allele had higher blood pressure and lower peripheral vasodilation after infusion of the β2-agonist salbutamol. Similar results were obtained by Hoit et al. [80] using the agonist terbutaline. On the other hand, volunteers homozygous for Gly16 exhibited larger vasodilatory responses than did volunteers homozygous for Arg16 [81]. Conflicting results have also been published with regards to the effects of genetic variants on the sympathetic nervous system modulation of energy expenditure. Bell et al. [82] reported that the response of resting energy expenditure to nonspecific β-adrenoceptor stimulation (with isoproterenol infusion) was not different between the 3 genotypes of Arg16Gly. Stob et al. [70] showed that individuals carrying the Arg16Arg variant of the β2-adrenoceptor gene have a reduced thermogenic response to selective β2-adrenoceptor activation.

Associations of β2-adrenoceptor polymorphisms with obesity have been reported in many epidemiological studies but results are also discordant (summarised in Table 2).

3.3. β3-Adrenoceptor Polymorphisms (Table 3)

The β3-adrenoceptor, which is mainly expressed in adipose tissue, differs from the β2-adrenoceptor in two ways: it has a lower affinity for catecholamines, and it resists desensitisation (i.e., downregulation). These characteristic differences might lead to the different effects of catecholamine on β2-adrenoceptors and β3-adrenoceptors. β3-adrenoceptors stimulates the mobilization of lipids from the white adipose tissue and increases thermogenesis in brown adipose tissue. Cypess et al. and other investigators demonstrated that potential roles of β3-adrenoceptor polymorphism (Trp64Arg) associated with potential role of uncoupling protein (UCP) polymorphisms and brown adipose tissue in thermogenesis and resultant body weight in humans [1315]. Decreased function of β3-adrenoceptor in white adipose tissue could slow lipolysis and thereby cause the retention of lipids in adipocytes. Slow lipolysis may contribute strongly to visceral obesity in human, and treatment of obese animal models with selective β3-adrenergic agonists reduces fat stores effectively [8890]. Hoffstedt et al. [91] compared adrenergic regulation of lipolysis between omental and subcutaneous adipocytes from 15 obese and 14 nonobese men. In their study, catecholamine-induced lipolysis was markedly increased in omental adipocytes as compared to subcutaneous adipocytes in obese male subjects mainly due to an increase in β3-adrenoceptor function of visceral fat, in combination with a smaller increase in β1-adrenoceptor function [91]. Recently, Eriksson et al. [76] observed that Trp64Arg polymorphism in the β3-receptor, which associates with obesity, is accompanied by changes in lipolytic sensitivity of the receptor in human adipocytes. Many epidemiological studies have shown the strong relationships between β3-adrenoceptor polymorphisms (mainly Trp54Arg), obesity, metabolic syndrome, and hypertension [8792] (Table 3).

3.4. Confounding Variables Affecting the Relationships of β-Adrenoceptor Polymorphisms with Obesity, Hypertension and Diabetes (Table 4)

Tables 13 show the discordant contributions of β-adrenoceptor polymorphisms to obesity. Table 4 summarizes factors which might explain the discrepancy of published data. Importantly, haplotypes of polymorphisms have strong influence on β-adrenoceptor function in each polymorphism [25, 73, 86, 9397].

4. Sympathetic Nervous System Activity and β2- and β3-Adrenoceptor Polymorphisms in Obesity

Many studies have examined the associations of the β2-or β3-adrenoceptor polymorphisms with obesity and blood pressure as mentioned above. A series of studies conducted by Masuo et al. have included measurements of sympathetic nervous system activity [24, 26]. In a longitudinal study over 5 years, originally nonobese, normotensive subjects carrying the Gly16 allele of Arg16Gly, the combination of β2-adrenoceptor polymorphisms and high plasma norepinephrine levels on entry were linked to weight gain and blood pressure elevations in addition to weight gain-induced blood pressure elevations [24]. In a weight loss study over a 24-month period, the β2-adrenoceptor the Gly16 allele of Arg16Gly was associated with resistance to long term significant weight loss, and the Glu27 allele was linked to resistance to short-term weight loss [26]. Nonobese normotensive men carrying the Gly16 allele of Arg16Gly had a higher frequency of insulin resistance, as indicated by elevation in the homeostasis model assessment for insulin resistance (HOMA) index. This deterioration in insulin resistance is generally observed in obesity and hypertension [27, 36, 44, 98]. These studies provide strong evidence for the linkage between β2-adrenoceptor polymorphisms, heightened sympathetic nervous system activity, obesity, hypertension, and the development of insulin resistance.

5. Elevated Sympathetic Nervous Activity in Obesity Is a Risk Factor for Cardiovascular Complications and Renal Complications

The increased risk of cardiovascular complications in obesity, especially associated with hypertension or type 2 diabetes, has been attributed to a variety of mechanisms, including dyslipidemia, coagulation abnormalities, endothelial dysfunction, chronic sympathetic nerve activation, and repeated occurrence of excessive hyperinsulinemia [99102]. Sympathetic nerve hyperactivity leads to arterial blood pressure elevation [103105], triggers arterial damage, and results in cardiovascular events. Recent studies and reviews reported that sympathetic nerve stimulation contributes to the progression of renal disease [106, 107]. Norepinephrine infusion into the renal artery in dogs produced a reversible ischemic model of acute renal failure [108]. Another study demonstrated renal protection by β-adrenergic receptor blockade in a nephrectomized rat without any BP changes [109]. Plasma norepinephrine and heightened sympathetic nerve activity may predict mortality and incident cardiovascular events including renal injury in large cohort longitudinal studies [110] and clinical studies [111, 112]. Renal injury also predicts the development of cardiovascular disease [105, 106, 110, 111]. There is consistent evidence that elevated sympathetic nervous activity predicts mortality in cardiovascular disease such as in patients with heart failure [111] and end-stage renal disease [112, 113]. Given these observations and the recent demonstration of the effectiveness of catheter based sympathetic renal denervation for the treatment of refractory hypertension [114, 115], it may be of importance to aim antihypertensive treatments or anti-diabetic treatment not only at the reduction of raised blood pressure or blood glucose but also at the excessive sympathetic activation that may underpin these effects.

6. Conclusions

Established and emerging data emphasises the importance of the sympathetic nervous system in obesity and obesity-related illness. Sympathetic nervous system activity and β-adrenoceptor polymorphisms (mainly β2- and β3-adrenoceptor polymorphisms) may contribute to the onset and maintenance of obesity; however, the findings have been discordant. A better understanding of the pathogenesis of obesity, including an understanding of adrenoceptor polymorphisms and their impact on sympathetic nervous activity might help in the prevention of obesity and the pharmacological treatment of obesity-related illness including hypertension and insulin resistance.

Disclosure

The laboratory of Dr. Lambert GW currently receives research funding from private organisations including ARDIAN Inc, Allergan, Abbott (formerly Solvay) Pharmaceuticals, and Scientific Intake. These organizations played no role in this paper. The investigators report no conflict of interests with regards to this paper.