Circadian Rhythm in Adipose Tissue: Novel Antioxidant Target for Metabolic and Cardiovascular Diseases

WAT is the most abundant type of adipose tissue and the main energy reservoir in mammals. White adipocytes are characterized by containing a single large unilocular lipid droplet and only a few mitochondria. The primary function of WAT is to synthesize and store excess dietary energy as triacylglycerols (TAGs), and hydrolyze TAG to generate fatty acids during energy deprivation [25]. WAT is also responsible for the secretion of a huge number of hormones and adipokines that regulate energy intake, metabolism and insulin resistance [26,27]. WAT converts excess dietary fats and carbohydrates from the circulation to TAGs by lipogenesis [28]. On the other hand, TAGs are broken down into glycerol and free fatty acids (FFAs) by lipolysis to release and supply the needs of distal organs [28].

Brown adipocytes are characterized by containing multilocular lipid droplets and high mitochondrial density which facilitates thermogenesis [29]. BAT is developmentally different from WAT. BAT originates from early paired box protein 7 (Pax7)⁺ and myogenic factor 5 (Myf5)⁺ embryonic progenitor cells or postnatal myoblasts, while late Pax7 expression is restricted to the skeletal muscle lineage [30,31]. In addition, PR domain containing 16 (Prdm16) is also a known lineage determining factor and transcription cofactor for the development of brown adipocytes [31]. The major activator of BAT is the sympathetic nervous system, signaled by norepinephrine [32]. Upon stimulation, such as cold exposure, BAT is activated to promote non-shivering thermogenesis via uncoupling protein 1 (UCP1), a thermogenic mitochondrial protein that uncouples electron transport from adenosine triphosphate (ATP) production [29]. In addition to its primary role in maintaining body temperature, BAT is also important for energy metabolism, insulin sensitivity, and lipid metabolism due to its high metabolic rate [33,34].

Recent studies have identified beige adipocytes, which are mitochondria rich and express UCP1, within WAT [35,36]. Beige adipocyte can be considered phenotypically as a fat cell that possesses characteristics between those of the WAT and BAT [37], which indicate that they are energy accumulators that possess thermogenic capacity to dissipate heat through UCP1 [38].

The biogenesis of beige adipocytes or the white-to-brown transition of adipocytes is called browning/beiging, which is a temporary adaptive response to external environmental signals. Browning can be stimulated by cold exposure, adrenergic stimulation and treatments with peroxisome proliferation-activated receptor gamma (PPARγ) agonists [39,40], fibroblast growth factor 21 (FGF21) [41], atrial natriuretic peptide (ANP) [42], and bone morphogenetic proteins (BMP) [43]. Browning of adipose tissue has been shown to be beneficial in preventing metabolic and cardiovascular diseases [44]. In addition, cold exposure can stimulate glucose uptake and TG clearance in adipose tissue, which may contribute to the modulation of oxidative stress in adipose tissue [45,46]. Interestingly, FGF21 has recently been shown to have both antihypertrophic and cardioprotective actions [47,48], and has been considered as a promising new therapy target obesity and associated diseases, by activating BAT and by acting on WAT and the liver [49]. Remarkably, FGF21 can regulate circadian behavior and metabolism by acting on the nervous system [50].

Apart from the three types of adipose tissue mentioned above, perivascular adipose tissue (PVAT) is also a critical modulator of cardiovascular health [51,52]. PVAT is the ectopic fat depot surrounding most vasculature including large arteries and veins, small and resistance vessels, and skeletal muscle microvessels [52]. This intimate connection between the vascular system and PVAT highlights the importance of PVAT. PVAT controls vascular tone on vessels through releasing various PVAT-derived relaxing factors (PVRFs) [53] and PVAT-derived contracting factors (PVCFs) [54,55]. Moreover, these PVAT-derived factors closely and directly affect vascular homeostatic processes, including vascular inflammation and oxidative stress, vascular tone, smooth muscle proliferation and migration and vascular remodeling [51,56,57].

To date, PVAT has been reported to contain both WAT and BAT, while the white-to-brown ratio is different across the vascular bed. For example, PVATs surrounding larger blood vessels are more BAT-like, whereas those surrounding smaller blood vessels are WAT-like [56,58,59,60]. It is suggested that the adipocytes in PVAT may share a common smooth muscle protein 22 alpha (SM22α⁺) precursors with vascular smooth muscle cells (VSMCs) [61]. During obesity and aging, the gradual shift into WAT-like characteristics of PVAT is associated with the alteration of secretome profile, which may lead to vascular dysfunction, arterial remodeling and increase in blood pressure [62,63]. Apart from cold exposure, exercise training has been shown to induce a BAT-like shift and thermogenic response, which is associated with enhanced eNOS expression and reduced oxidative stress in PVAT [64].

Adipose tissue produces and secretes a variety of bioactive molecules, adipokines, which signals to nearby or remote target organs. Adipose tissue accumulation and altered adipokine profile are linked to chronic inflammation and metabolic and cardiovascular disorders [65]. The primary adipokines that play a role in inflammation, metabolic and cardiovascular diseases include adiponectin, leptin, resistin, visfatin, tumor necrosis factor alpha (TNF-α), interleukin-6(IL-6), plasminogen activator inhibitor-1 (PAI-1), and vascular endothelial growth factor (VEGF) [66,67]. In general, adipokine levels are positively correlated with fat mass, and the functions of adipokines are also related to their site of production. For example, BAT-derived IL-6, an adipokine that are upregulated by proinflammatory stimulation, has been shown to mediate glucose metabolism and energy balance [34]. PVAT-derived adiponectin is an important contributor to vascular function, partly by enhancing eNOS phosphorylation in the endothelium [68]. Notably, most hormones, including adipokines, display daily fluctuation of secretion during the day-night cycle. In addition to the altered adipokine profile, the disruption of this rhythmic secretion of adipokines is also an aggravating factor for the development of metabolic and cardiovascular diseases [69].

At the molecular level, circadian clock in the adipose tissue is based on interlocked transcription–translation feedback loops of clock genes and proteins [87]. These circadian proteins include important transcription factors brain and muscle aryl hydrocarbon receptor nuclear translocator-like protein 1 (BMAL1 a.k.a. ARNTL) and circadian locomotor output cycles kaput (CLOCK), and transcriptional modulator families of Period 1/2/3 (PER1/2/3) and Cryptochrome ½ (CRY1/2) [87,88]. The molecular clockwork in adipose tissue relies on the dimerization of BMAL1 and CLOCK proteins, whereas the heterodimer of CLOCK:BMAL1 binds to E-box sequence (5′-CACGTG-3′) in the promoters and activates the transcription of other circadian genes including Per1–3 and Cry1/2 [17]. When PERs and CRYs are expressed in certain amount in the cytoplasm, these proteins dimerize (PERs:CRYs) and translocate into the nucleus, which leads to the inhibition of CLOCK:BMAL1-mediated transcription [17,89].

There are also reinforcing loops that are composed by the circadian nuclear receptors, reverse ERB (REV-ERB α/β) and retinoic acid receptor-related orphan receptors (RORα/β/γ) that control the rhythmic transcription of Bmal1 and Clock. REV-ERBα negatively regulates Bmal1 and Clock expression [90], whereas RORα and RORγ positively regulate Bmal1 and Clock expression via ROR response elements at the promotor regions [91,92]. All the expression patterns of these clock genes exhibit a 24-hour oscillation in adipose tissue [93]. In human adipose tissue, the expression of BMAL1 and CLOCK peaks in the late evening, while the expression of PERs, CRY2, and REV-ERBα peak around late morning [85]. In addition, post-translational modifications also contribute to the regulation of the circadian clock [70,94].

Apart from the interlocked transcription–translation feedback loop of the clock genes, the oscillation of the circadian clock also leads to rhythmic expression of clock-controlled genes (CCGs) through activation of circadian promoter elements including E-boxes, D-boxes, and ROR response elements [85]. While the same clock machineries are found in most cells, the rhythmic expression of these CCGs are tissue-specific or even cell-type-specific [70] (Figure 1).

Apart from controlling the circadian machinery, circadian clock genes also have important functions in the metabolic and cardiovascular system. In different animal models, circadian clock disruptions generally lead to reduced lifespan, accelerated aging and dramatic effects on body weight gain, adiposity and TG metabolism [95,96,97].

Clock^Δ19 and Bmal1^−/− circadian mutant mice display low and nonrhythmic blood FFA and glycerol levels together with decreased lipolysis rates and increased sensitivity to fasting [5]. Circadian disruption promotes the accumulation of TGs in WAT which leads to increased adiposity and adipocyte hypertrophy [5]. CLOCK and BMAL are also critical in maintaining glucose homeostasis while Clock-mutant mice display phenotype of cardiovascular and metabolic diseases such as obesity and hypertension [7,98]. Deficiency of Bmal1 leads to impaired adaptive vascular remodeling and increased collagen deposition in the medial layer of blood vessels in mice [99]. Moreover, transcriptome analysis of tissue-specific Clock^Δ19 mutant mice shows altered regulation of at least 660 genes due to impaired WAT clocks, of which 26% are repressed, while the remaining 74% are induced [95]. A part of these differentially expressed genes is involved in lipogenesis, including those encodes for fatty acid transporters, fatty acid binding protein 9 (FABP9) and glycerol kinase 2 (GK2) [95]. Overexpression of BMAL1 in adipocytes has been shown to increase lipid synthesis activity and promote several factors associated with lipogenesis in vitro [100]. BMAL1 modulates adipogenesis via wingless-type MMTV integration site family (Wnt) signaling in WAT [101], while it exerts transcriptional control on the transforming growth factor-β (TGF-β) pathway in BAT. Either global ablation or adipocyte-selective inactivation of BMAL1 increases the mass of BAT and cold tolerance [102]. BMAL1 inhibits brown fat formation through direct transcriptional control of TGF-β and bone morphogenetic protein (BMP), which are known to suppress [103] and drive [104] brown adipocyte differentiation, respectively. Activation of TGF-β/Smad3 or inhibition of BMP pathways normalizes the enhanced differentiation in Bmal1-deficient brown adipocytes [102]. Interesting, antioxidant N-acetyl-L-cysteine can ameliorate symptoms of premature aging in Bmal1-deficient mice [105].

REV-ERB and ROR families are important component that link the core clock mechanism with lipid metabolism. REV-ERBs and RORs have been shown to be responsible for adipocyte differentiation [106], lipogenesis, and lipid storage [107,108]. Rev-erbα-deficient mice show increased adiposity on both normal chow and high-fat diet (HFD) as a result of increased fat uptake by adipose tissue [109]. REV-ERB agonist treatment has been shown to reduce fat mass and alleviate dyslipidemia and hyperglycemia in obese mice [110]. REV-ERB agonist can suppress orexinergic gene expression, while Rev-erbβ-deficient mice have increased orexinergic transcripts, suggesting the involvement of REV-ERB in regulating appetite [111]. On the other hand, REV-ERBα appears to have an opposite role on adiposity in BAT. Deletion of Rev-erbα results in an improved thermogenic response to cold challenge, while downregulation of Rev-erbα leads to the induction of UCP1 expression [112]. As opposed to BMAL1, REV-ERBα inhibits key components of the TGF-β signaling pathway [113], thereby promotes BAT development and adipogenesis.

Per2^−/− mice displays altered lipid metabolism, with drastic reduction of total TAGs and non-esterified fatty acids [114]. PER2 represses PPARγ-mediated transcriptions, thereby altering the expression of genes involved in adipogenesis, insulin sensitivity and inflammatory response [114]. Moreover, lack of PER2 promotes adipocyte differentiation in cultured fibroblasts [114]. PER3 has been reported to modulate adipogenesis by regulating Krüppel-like factor 15 (KLF15) expression, while deletion of Per3 promotes adipogenesis in vivo [115]. Cry1^−/−Cry2^−/− mice have reduced body weight and WAT due to higher energy expenditure and heat production compared with wild-type controls under normal chow [116]. Cry1^−/−Cry2^−/− mice also have an increased sensitivity to HFD-induced obesity, which is associated with increased insulin secretion, elevated lipogenesis and TG accumulation in WAT [117] and augmented proinflammatory cytokine levels [118]. In addition, meta-analysis indicates that genetic variants at Cry1 are associated with insulin resistance and diabetes risk in human [119].

To date, only a few studies have reported the phenotypes and effects on adipose tissue function and oxidative stress in adipose tissue-specific clock gene knockout mice (Table 1). Adipocyte-specific deletion of Bmal1 results in obesity in mice with a shift in diurnal rhythm of food intake and loss of circadian variation in plasma TG and glucose levels [120]. Deletion of the adipocyte Bmal1 is associated with a reduced number of polyunsaturated fatty acids in adipocyte triglycerides, and loss of rhythmic expression of clock and clock-output genes in both BAT and WAT [120]. In addition, adipocyte-specific Clock^Δ19 mutation increases body weight and fat mass in mice [121]. The young mortality rates of these mice are increased and the rates of glucose tolerance are reduced compared to wild type mice [121]. Moreover, brown adipocyte-selective Bmal1-deficient mice have reduced blood pressure during resting phase, associated with reduced PVAT-induced vasoconstriction [122]. Indeed, angiotensinogen mRNA and angiotensin II levels in PVAT of brown adipocyte-selective Bmal1-deficient mice are significantly reduced [122]. These studies suggest that clock aberration specifically in adipose tissue can result in significant alterations of the cardiovascular and metabolic health. Circadian clock genes in adipose tissues are important in maintaining the robust relationship between circadian rhythm and metabolic and cardiovascular health. However, most of the observations currently made are based on animal models with global ablation or mutants of circadian clock genes, the contribution of these circadian clock genes in adipose tissue function warrants further studies by using adipose tissue-specific knockout/mutant mice.

Feeding and fasting patterns have been shown to drive daily rhythms in the activities of key energy regulators including adenosine 5′-monophosphate–activated protein kinase (AMPK), cAMP-response element binding protein (CREB) and protein kinase B (AKT) [158,159], which suggest a clear connection between circadian rhythm and metabolism. Constant light causes disruptions in the rhythmic oscillation of plasma levels of glucose and TG in mice and eliminations of the circadian expression of genes involved in lipid metabolism in WAT, which can be restored by time-restricted feeding to various degrees [160]. This suggests that food intake is an important zeitgeber, which may be stronger than light-dark cycle, that regulates lipid metabolism in WAT. Feeding and restrictive meal timing have been shown to modulate circadian rhythm and generate pronounced phase shifts in circadian gene expression in different peripheral tissues [161,162]. Temporally restricted feeding in mice alters the circadian expression profile in BAT, inguinal WAT and epididymal WAT [83]. In rat, either wrong time restricted feeding or high-fat-high-sugar diet disturbs the peripheral clock rhythmicity, and alters Ucp1 and PPARγ coactivator 1 alpha (Pgc-1α) expression in BAT [163]. In mice, time restricted feeding attenuates obesity, hyperinsulinemia and inflammation, associated with improvements in circadian clock oscillation, and mTOR and AMPK pathway function [158]. In a recent study, time restricted feeding has been shown to prevent obesity and improve metabolic function in whole-body Cry1;Cry2 knockout and in liver-specific Bmal1 and Rev-erba/b knockout mice [164].

Intermittent fasting is an dietary pattern in which minimal calories are consumed 1 to 4 days per week, followed by ad libitum diet on the remaining days [165], and has been shown to reduce the risk for metabolic diseases in human [166,167,168]. Intermittent fasting has been shown to decrease energy intake, body weight, adiposity, and improve glucose tolerance in HFD-fed mice [169]. HFD-induced adipose tissue inflammation and fibrosis can also be ameliorated by intermittent fasting [169]. Diurnal intermittent fasting during Ramadan can reduce inflammation and oxidative stress [170], and affect circadian rhythms of energy expenditure and body temperature in healthy people [171]. In addition, Ramadan intermittent fasting ameliorates the expression of antioxidants (Sod2, and Nrf2), and metabolic regulatory genes (Sirt1 and Sirt3) in obese and overweight subjects [172]. A recent randomized clinical study has suggested the intermittent fasting-medicated alteration of peripheral clock genes expression in subcutaneous adipose tissue in obese women, despite intermittent fasting does not uniformly impact the expression of clock genes [173]. Nevertheless, studies on time-restricted feeding and intermittent fasting have provided strong evidence that connects circadian clock and energy metabolism.

As mentioned, the molecular clock machinery drives the circadian transcription of CCGs in peripheral tissues. These CCGs encode for many important regulatory proteins and enzymes that involve in different vital cellular processes. The circadian regulation of CCGs, however, is highly different among tissues, which complicates the research field of circadian rhythm. To date, there are only few studies focused on the circadian regulation in adipose tissue. Identification of important CGGs and pathways involved in adipose tissue function is important to improve the understanding of clock involvement in the pathophysiology of metabolic diseases. Here, we propose some important targets and summarize important findings that link circadian rhythm and oxidative stress in adipose tissue.