Brown Adipose Tissue and Its Role in Insulin and Glucose Homeostasis

✅ 全文

棕色脂肪组织及其在胰岛素与葡萄糖稳态中的作用

作者 Katarzyna Maliszewska; Adam Krętowski 期刊 International Journal of Molecular Sciences 发表日期 2021 ISSN 1422-0067 DOI 10.3390/ijms22041530 类型 原创研究 (Original Research)

📄 英文摘要 English Abstract

EN

The increased worldwide prevalence of obesity, insulin resistance, and their related metabolic complications have prompted the scientific world to search for new possibilities to combat obesity. Brown adipose tissue (BAT), due to its unique protein uncoupling protein 1 (UPC1) in the inner membrane of the mitochondria, has been acknowledged as a promising approach to increase energy expenditure. Activated brown adipocytes dissipate energy, resulting in heat production. In other words, BAT burns fat and increases the metabolic rate, promoting a negative energy balance. Moreover, BAT alleviates metabolic complications like dyslipidemia, impaired insulin secretion, and insulin resistance in type 2 diabetes. The aim of this review is to explore the role of BAT in total energy expenditure, as well as lipid and glucose homeostasis, and to discuss new possible activators of brown adipose tissue in humans to treat obesity and metabolic disorders.

📄 中文摘要 Chinese Abstract

中文
全球20-25%的成年人患有代谢综合征(MetS),其患病率显著上升,在中国高达33.9%。全球范围内关于中西医结合治疗MetS的研究正在如火如荼地进行。当代大多数关于MetS的研究与脂质代谢、脂质蓄积指数以及不同脂质的比例有关。在现代医学中,由遗传和环境因素引起的胰岛素抵抗以及与之密切相关的炎症状态和氧化应激是MetS的生理和病理基础[1]。现代医学认为腹型肥胖和胰岛素抵抗是MetS发病机制中的两个核心要素[2]。 MetS是一系列生理生化异常构成的代谢紊乱综合征,包括中心性肥胖、血脂异常、高血压、胰岛素抵抗和高血糖。其主要由遗传因素、生活方式、环境因素、内脏肥胖等引起。胰岛素抵抗、慢性炎症和神经激素激活是MetS向脑血管疾病和2型糖尿病进展和发展的重要机制[4]。脂肪细胞功能障碍导致促炎、致动脉粥样硬化和致糖尿病状态,并可能与慢性炎症、胰岛素抵抗、MetS及其他肥胖相关疾病的发展有关[4]。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Background:

20-25% of adults worldwide suffer from metabolic syndrome (MetS), and its prevalence is significantly increasing, up to 33.9% in China. The global research on MetS with combining of Chinese and Western medicine is hotly underway. Most contemporary research on MetS is related to lipid metabolism, lipid accumulation index, and the ratio of different lipids. In modern medicine, insulin resistance caused by genetic and environmental factors and the closely related inflammatory state and oxidation stress is the physiological and pathological basis of the MetS [1]. Modern medicine considers abdominal obesity and insulin resistance as the two core elements in the pathogenesis of MetS [2].

MetS is a collection of physiological and biochemical abnormalities that form a series of metabolic disorders, including central obesity, dyslipidemia, hypertension, insulin resistance and hyperglycemia. It is mainly caused by genetic factors, lifestyle, environmental factors, visceral obesity, etc. Insulin resistance, chronic inflammation and neurohormonal activation are important mechanisms for the progression and development of MetS toward cerebrovascular disease and type 2 diabetes [3]. Adipocyte dysfunction leads to pro-inflammatory, atherogenic and diabetogenic states and may be associated with the development of chronic inflammation, insulin resistance, MetS and other obesity-related diseases [4].

Methods:

In this paper, we searched the literature from 2020 to 2022 on Pubmed and Knowledgeweb using the keywords of “metabolic syndrome,” “adipose tissue” and “adipokines”. We mainly explored the mechanisms of leptin, lipocalin, resistin, brown adipose tissue and beige adipose tissue secreted by white adipose tissue in regulating insulin resistance, inhibiting inflammatory response and neurohormonal regulation of lipid and glucose metabolism. Under various studies on lipids for MetS, the metabolic mechanisms of various adipose tissues, adipocytes, and adipokines were investigated systematically and retrospectively. (Review article – approach as described.)

Results:

We mainly explored the mechanisms of leptin, lipocalin, resistin, brown adipose tissue and beige adipose tissue secreted by white adipose tissue in regulating insulin resistance, inhibiting inflammatory response and neurohormonal regulation of lipid and glucose metabolism. Adipose tissue is the core component of MetS, and its primary function is to store energy and release adipokines to regulate body metabolism [6]. White adipose tissue secretes various bioactive factors such as leptin, lipocalin and resistin. Leptin is mainly produced by white adipose tissue.

Data Summary:

20-25% of adults worldwide suffer from metabolic syndrome (MetS), and its prevalence is significantly increasing, up to 33.9% in China. To confirm the diagnosis of MetS, abdominal obesity must be satisfied first (waist circumference >94 cm for European men and >80 cm for women; >90 cm for Chinese men and >80 cm for women). At least two of the following four criteria must also be met: 1) HDL <40 mg/dl for men and <50 mg/dl for women or medication for this lipid abnormality; 2) triglycerides >150 mg/dL or medication for this abnormality; 3) systolic blood pressure >130 mmHg or diastolic blood pressure >85 mmHg or treatment for this abnormality; 4) fasting blood glucose >5.6 mmol/L or have received the corresponding treatment [5].

Conclusions:

It was found that the regulation of adipokines and, thus, treatment of MetS by drugs is less and needs further exploration.

Practical Significance:

The global research on MetS with combining of Chinese and Western medicine is hotly underway, and understanding the mechanisms of adipokine regulation may inform future therapeutic strategies for metabolic syndrome.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

全球20-25%的成年人患有代谢综合征(MetS),其患病率显著上升,在中国高达33.9%。全球范围内关于中西医结合治疗MetS的研究正在如火如荼地进行。当代大多数关于MetS的研究与脂质代谢、脂质蓄积指数以及不同脂质的比例有关。在现代医学中,由遗传和环境因素引起的胰岛素抵抗以及与之密切相关的炎症状态和氧化应激是MetS的生理和病理基础[1]。现代医学认为腹型肥胖和胰岛素抵抗是MetS发病机制中的两个核心要素[2]。

MetS是一系列生理生化异常构成的代谢紊乱综合征,包括中心性肥胖、血脂异常、高血压、胰岛素抵抗和高血糖。其主要由遗传因素、生活方式、环境因素、内脏肥胖等引起。胰岛素抵抗、慢性炎症和神经激素激活是MetS向脑血管疾病和2型糖尿病进展和发展的重要机制[4]。脂肪细胞功能障碍导致促炎、致动脉粥样硬化和致糖尿病状态,并可能与慢性炎症、胰岛素抵抗、MetS及其他肥胖相关疾病的发展有关[4]。

方法:

本文在Pubmed和Knowledgeweb上检索了2020年至2022年的文献,关键词为"代谢综合征"、"脂肪组织"和"脂肪因子"。我们主要探讨了白色脂肪组织分泌的瘦素、脂质运载蛋白、抵抗素、棕色脂肪组织和米色脂肪组织在调节胰岛素抵抗、抑制炎症反应以及脂质和葡萄糖代谢的神经激素调节中的机制。在各种针对MetS的脂质研究中,系统回顾性地研究了各种脂肪组织、脂肪细胞和脂肪因子的代谢机制。(综述文章——方法如所述。)

结果:

我们主要探讨了白色脂肪组织分泌的瘦素、脂质运载蛋白、抵抗素、棕色脂肪组织和米色脂肪组织在调节胰岛素抵抗、抑制炎症反应以及脂质和葡萄糖代谢的神经激素调节中的机制。脂肪组织是MetS的核心组成部分,其主要功能是储存能量和释放脂肪因子以调节机体代谢[6]。白色脂肪组织分泌多种生物活性因子,如瘦素、脂质运载蛋白和抵抗素。瘦素主要由白色脂肪组织产生。

数据概要:

全球20-25%的成年人患有代谢综合征(MetS),其患病率显著上升,在中国高达33.9%。确诊MetS需首先满足腹型肥胖(欧洲男性腰围>94 cm,女性>80 cm;中国男性腰围>90 cm,女性>80 cm)。同时还需满足以下四项标准中的至少两项:1)男性HDL<40 mg/dl,女性<50 mg/dl,或正在接受针对该脂质异常的治疗;2)甘油三酯>150 mg/dL,或正在接受针对该异常的治疗;3)收缩压>130 mmHg或舒张压>85 mmHg,或正在接受针对该异常的治疗;4)空腹血糖>5.6 mmol/L,或已接受相应治疗[5]。

结论:

研究发现,通过药物调节脂肪因子从而治疗MetS的研究较少,需要进一步探索。

实践意义:

全球范围内关于中西医结合治疗MetS的研究正在如火如荼地进行,了解脂肪因子调节的机制可能为未来代谢综合征的治疗策略提供参考。

📖 英文全文 English Full Text

EN

International Journal of Molecular Sciences Review

Brown Adipose Tissue and Its Role in Insulin and Glucose Homeostasis

Katarzyna Maliszewska * and Adam Kretowski 

 Citation: Maliszewska, K.; Kretowski, A. Brown Adipose Tissue and Its Role in Insulin and Glucose

Homeostasis. Int. J. Mol. Sci. 2021, 22, 1530. https://doi.org/10.3390/ ijms22041530

Academic Editor: Melania Manco Received: 16 December 2020

Accepted: 1 February 2021 Published: 3 February 2021

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affil- iations.

Copyright: © 2021 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article distributed under the terms and conditions of the Creative Commons

Attribution (CC BY) license (https:// creativecommons.org/licenses/by/

4.0/).

Department of Endocrinology, Diabetology and Internal Medicine, Medical University of Bialystok,

15-089 Bialystok, Poland; adamkretowski@wp.pl * Correspondence: maliszewska.k@gmail.com; Tel.: +48-698-443330

Abstract: The increased worldwide prevalence of obesity, insulin resistance, and their related metabolic complications have prompted the scientific world to search for new possibilities to combat obesity. Brown adipose tissue (BAT), due to its unique protein uncoupling protein 1 (UPC1) in the inner membrane of the mitochondria, has been acknowledged as a promising approach to increase energy expenditure. Activated brown adipocytes dissipate energy, resulting in heat production. In other words, BAT burns fat and increases the metabolic rate, promoting a negative energy balance.

Moreover, BAT alleviates metabolic complications like dyslipidemia, impaired insulin secretion, and insulin resistance in type 2 diabetes. The aim of this review is to explore the role of BAT in total energy expenditure, as well as lipid and glucose homeostasis, and to discuss new possible activators of brown adipose tissue in humans to treat obesity and metabolic disorders.

Keywords: brown adipose tissue; obesity; diabetes type 2; insulin resistance; metabolism

1. Introduction Brown adipose tissue (BAT) was considered, for several years, to be present only in newborns and small mammals to generate heat through non-shivering thermogenesis as protection against hypothermia. However, the abundant amount of active BAT in children declines rapidly after puberty. The exact amount (volume) of active BAT in adult humans remains highly variable, but the prevalence of brown adipose tissue in adults was estimated at 6.97% based on recently published results from a systematic review and meta-analysis [1]. The first clinical observations of BAT came from oncological patients in whom imaging scans, using positron emission tomography combined with computed tomography (PET/CT) or magnetic resonance PET/MR, revealed cervical adipose tissue characterized by high metabolic activity [2]. In 2009, functional brown fat in adult humans was confirmed after dedicated cold exposure research [3–5].

The increased worldwide prevalence of obesity has prompted the scientific world to search for new possibilities to deal with weight gain [6]. Obesity is a major health risk factor and strongly associated with the development of insulin resistance, which is a key player in the pathogenesis of metabolic complications, type 2 diabetes, and cardiovascular diseases [7]. An increased obesity rate is associated with a decrease in life expectancy and also represents a large economic burden [8].

BAT is a type of tissue designed for maintaining body temperature higher than ambient temperatures through heat production, primarily via non-shivering thermogenesis. This process is mediated by the expression of uncoupling protein 1 (UCP1) within the inner membrane of the abundant mitochondria [9]. Despite high mitochondria content and high cellular respiration rates, brown adipocytes have a remarkably low capacity for adenosine triphosphate (ATP) synthesis [10]. Brown adipocytes (in contrast to most human cells), through UCP1 expression and low ATP synthase activity, diminish the proton gradient by uncoupling cellular respiration and decrease mitochondrial ATP synthesis to stimulate heat production.

Int. J. Mol. Sci. 2021, 22, 1530. https://doi.org/10.3390/ijms22041530 https://www.mdpi.com/journal/ijms

Int. J. Mol. Sci. 2021, 22, 1530 2 of 18 Due to its unique UPC1, brown adipose tissue has been acknowledged as a promis- ing approach to increase energy expenditure [11]. In other words, BAT burns fat and increases the metabolic rate, promoting a negative energy balance [12]. Moreover, BAT alle- viates metabolic complications like dyslipidemia, impaired insulin secretion, and insulin resistance in type 2 diabetes [13].

The protective role of BAT, in terms of its metabolic consequences, prompted the molecular exploration of brown adipocyte differentiation. The most relevant molecular factors involved in brown and white adipose tissue formation are peroxisome proliferator- activated receptors (PPARs) [14]. PPARγ has a crucial role in tissue development and functions by inducing UCP1 expression during adipogenesis [15]. Moreover, PPARγ ag- onists can be used to induce the browning of white adipose tissue [16], while PPARα activation promotes beige adipogenesis via Peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC1α), which is a key regulator of mitochondrial biogenesis, adaptive thermogenesis, and oxidative metabolism. In the molecular pathways involved in white adipose tissue (WAT) browning, the key factor is PR domain-containing protein

16 (PRDM16), which controls the switch between skeletal myoblasts and brown adipocytes and stimulates adipogenesis by directly binding to PPARγ [17]. Recently, it was shown that brown and beige adipocytes release growth and differentiation factor 15 (GDF15) in response to thermogenic activity. GDF15 may mediate the downregulation of local inflam- matory pathways [18]. Moreover, in adipose tissue biology, certain microRNAs play the important role of regulating BAT and WAT functions and differentiation. Such microRNAs regulate white, brown, and beige adipogenesis by targeting key transcription factors (e.g.,

PRDM16, PPARγ, CCAAT-enhancer binding protein C/EBPB, and PGC1α) [19].

The aim of this review is to explore the role of BAT in whole-body energy expenditure and lipid and glucose homeostasis and to discuss new possible activators of brown adipose tissue in humans to treat obesity and metabolic disorders.

2. Morphology of Brown Adipocytes Brown adipose tissue (BAT) and white adipose tissue (WAT) contribute to total adipose tissue in humans. Despite having similar structural components (adipocytes), the functions of both fat tissues are different. White adipose tissue stores energy, while brown adipose tissue generates body heat. Brown adipose tissue consists of brown adipocytes (which are smaller than white adipocytes) and lipids that are located in multiple small droplets, giving brown adipocytes a multilocular histology [20] with a central nucleus and an abundant number of mitochondria. Dense vascularity and innervation by the sympathetic nervous system are characteristic features of brown adipocytes [21]. White adipocytes have a unilocular morphology, and triacylglycerols are stored in one large droplet inside the cell.

Deposits of WAT are localized mainly beneath the skin (subcutaneous adipose tissue (SAT)) and around internal organs (visceral adipose tissue (VAT)). However, a small amount of

WAT is found in the perivascular and epicardial regions, the mediastinal retro-optical space, and bone marrow [22]. The main function of white adipocytes is to act as a reserve for lipids, which can be oxidized to produce energy and protect the human body from excess glucose by storing triglycerides [23]. Among the white adipocytes are scattered beige (brite) adipocytes, which can be converted to brown adipocytes. The browning of WAT is induced by cold exposure or genetic modification. Brite adipocytes share morphological and molecular features and functions with typical BAT.

The traditional understanding of white fat tissue as passive energy storage is no longer justifiable. In recent years, adipose tissue has been recognized as a complex, highly active metabolic and endocrine organ [24], with special emphasis on visceral fat as being more prone to induce insulin resistance, type 2 diabetes, or future cardiovascular events [25]. In contrast, brown adipocytes have the ability to maintain normal body temperature in cold environments through heat production in the process of non-shivering thermogenesis [26].

Brown adipocytes, after being activated by cold exposure, start to oxidize their own lipid stores or fatty acids cleared from circulation and other substrates, e.g., glucose, to produce

Int. J. Mol. Sci. 2021, 22, 1530 3 of 18 heat and increase the metabolic rate. The unique function of brown adipocytes is due to the expression of UCP1 in the inner mitochondrial membrane [27]. UCP1 has only been found in BAT and is, therefore, an ideal marker for this tissue. Almost all human cell mitochondria (apart from brown fat mitochondria) are responsible for ATP synthesis, involving the use of lipids or glucose. This process is called respiration coupling, where the energy released during the re-oxidation of reduced coenzymes and oxygen consumption is used to phosphorylate ADP into ATP [28]. A part of respiration energy is also lost as heat.

Due to presence of UCP1, brown adipocyte mitochondria respire without being forced to phosphorylate ADP; in such a unique circumstance, energy is dissipated as heat [29].

The capacity of BAT to burn fat and enhance energy expenditure could be used as a novel therapeutic tool to combat obesity and metabolic diseases [30].

2.1. BAT and Energy Balance Thermogenesis is generally described as any metabolic process that releases heat, so whole-body thermogenesis is a counterpart of total energy expenditure (EE) [31]. Body temperature can thus be regulated at the level of thermogenesis, e.g., shivering and non- shivering thermogenesis, and heat loss, e.g., sweat production in heat and during exer- cise [32]. Thermogenesis or total daily energy expenditure (ADMR) can be divided into basal metabolic rate (BMR, roughly 55–65% of ADMR), diet-induced thermogenesis (DIT, about 10% of ADMR), and energy expenditure for physical activity (AEE). BMR remains relatively constant and is mainly determined by lean body mass [33]. A second description of total daily energy expenditure is the use of obligatory and facultative thermogenesis [34].

Obligatory thermogenesis refers to the energy expenditure needed for daily bodily func- tions, i.e., those needed for cells and organs to maintain their daily living functions. This also includes parts of DIT and AEE that are not needed for extra heat production. Facul- tative thermogenesis, in contrast, is connected with extra heat production in response to cold and diet—cold-induced thermogenesis (CIT) and DIT, respectively. In terms of human brown fat and its role in energy expenditure, the most essential process is cold-induced thermogenesis. CIT consists of shivering thermogenesis (ST) and non-shivering thermo- genesis (NST). In ST, the involuntary contraction of muscles caused by cold exposure is the main contributor to heat production in moderate to extreme cold [35]. ST can increase human energy expenditure by as much as 3–5 times the BMR. Shivering, however, is generally uncomfortable, leads to fatigue, and negatively affects the coordination of our movements. NST is carried out by the activation of brown adipose tissue (BAT) via UCP1 and the skeletal muscle via sarcolipin [36]. The important role of BAT in cold-induced thermogenesis was proven by the inhibition of BAT thermogenesis using nicotinic acid, which resulted in increased muscle shivering to combat cold temperatures [37]. Active

BAT can contribute up to 2–5% of the resting metabolic rate in humans [38,39]. Moreover, non-shivering thermogenesis can be maintained without discomfort. Considering this fact, the activation of brown adipose tissue seems to be one of the possible mechanisms responsible for increasing energy expenditure [40], thereby creating a negative energy balance. This may have large health implications, suggesting that the sustained activation of BAT may alleviate obesity and its associated disorders.

The gold standard method for identifying and assessing BAT volume is 18FDG (18 fluoro-deoxy-glucose) PET/CT [41], but BAT glucose metabolism does not accurately reflect

BAT thermogenic activity [42]. Notably, intracellular triglycerides TG are the main energy source used initially after cold-induced BAT activation in humans [37,43]. TG is the main fuel used for mitochondrial oxidative metabolism, which is why BAT glucose uptake should be disconnected from thermogenesis [44]. The glucose uptake and metabolism of BAT better illustrates BAT’s insulin sensitivity. A study using another tracer, 11C-acetate, which evaluated the Krebs’ cycle rate, more accurately verified the role of BAT in cold-induced thermogenesis in humans [45], showing a two- to three-fold increase in BAT thermogenesis via acclimation to cold [46,47] without a reduction in T2D subjects, despite a major decline in BAT glucose uptake [48]. Studies evaluating BAT oxygen consumption with the use

Int. J. Mol. Sci. 2021, 22, 1530 4 of 18 of 15O2 estimated BAT energy expenditure at a level of 15–25 kcal/day [49]. A second research group reported BAT thermogenesis, with the use of the same tracer, as ~7 kcal/day at room temperature to ~10 kcal/day during mild cold exposure in healthy subjects [50].

These are rather small amounts of data, which could be a result of the current limitations of using 18FDG PET to measure total BAT volume, especially in obese and T2D individuals.

The measurement of metabolically active BAT with the use of radiological 3D mapping estimated the highest BAT contribution to thermogenesis at 27–123 kcal per day at room temperature and at 46–211 kcal per day during mild cold exposure [51]. The same study indicated that 4.3% of the total body adipose tissue mass reflects fat tissue, with significant glucose uptake upon cold exposure. The average mass of BAT ranges from 50 to 70 g in adult humans [3]; such an amount of active BAT could increase daily energy expenditure by about 170 kcal. Outcomes from an interventional study in which patients without active

BAT at the baseline visit lost weight after six weeks of cold exposure and presented a

1.5-fold increase in BAT activity [52] support the role of brown adipose tissue in energy balance in humans. It was calculated that 63 g of fully activated supraclavicular BAT would utilize an amount of energy equivalent to 4.1 kg of WAT [3]. The appreciable influence of

BAT on energy expenditure is supported by an experimental study in which treatment with the β3-adrenergic agonist mirabegron not only increased energy expenditure (203 ±

40 kcal/day), but also increased beneficial lipoproteins (HDL and ApoA1) and antidiabetic proteins (adiponectin), and improved insulin secretion and sensitivity [53].

Recent discoveries have shown the different mechanisms for facultative energy expen- diture in BAT, including the futile cycles based on creatine [54] and succinate [55]. In beige adipocytes, cold exposure elicited mitochondrial creatine kinase activity and increased the expression of genes associated with creatine metabolism. Compensatory genes of creatine metabolism are induced when UCP1-dependent thermogenesis is ablated. Succi- nate accumulated from the extracellular milieu is rapidly taken up by brown adipocyte mitochondria, and its oxidation by succinate dehydrogenase (SDH) is required to activate thermogenesis. It was found that SDH-mediated succinate oxidation initiates reactive oxygen species (ROS) production and thereby drives UCP1-dependent thermogenic respi- ration, while SDH inhibition suppresses thermogenesis. The findings of these studies were determined using rodent models and still need to be evaluated in humans.

2.2. BAT, Obesity, and Insulin Resistance Negative energy balance is not the only factor in favor of using brown adipose tissue for the treatment of obesity; an additional significant feature is the ability of BAT to alleviate insulin resistance and disturbance in glucose homeostasis. Results from experimental studies showed that active BAT is inversely correlated with the body mass index (BMI), which additionally confirms the relationship between BAT and body mass [56]. Patients with detectable BAT had a lower body mass index and increased energy expenditure. In terms of obesity and BAT, brown adipocytes occur less often in people with central obesity and hepatic fat [5]. Visceral adipose tissue is known to be an active endocrine organ that highly contributes to insulin resistance. The negative association between BAT activity and the amount of VAT is optimistic in terms of the prevention and treatment of metabolic disease through BAT activation [57]. The removal or sympathetic denervation of murine

BAT enhances hypertriglyceridemia and obesity [58]. Serum hypertriglyceridemia with subsequent storage in WAT (ectopically stored in skeletal muscle and the liver) reduced the insulin sensitivity of these organs and increased the risk of T2D [59]. Brown adipocyte clear serum from TG is used to refill the lipid stores used for non-shivering thermogenesis.

Moreover, in animal models on a high-fat diet, BAT transplantation significantly reduced body weight and adipose tissue inflammation, and increased overall glucose tolerance and insulin sensitivity. The excision of brown adipocytes caused a significant increase in body weight, adipose tissue inflammation, and insulin resistance [60]. Moreover, the observed decline of BAT activity with aging increases excessive fat accumulation [52]. The age-associated decrease in BAT is explained by the loss of mitochondrial functions, UCP-1

Int. J. Mol. Sci. 2021, 22, 1530 5 of 18 expression, impairment of the sympathetic nervous system, and alteration in the function of brown adipogenic stem/progenitor cells [61]. In contrast, recently published findings indicate that the presence of BAT, even in those aged over 60 years old with cardiovascular disease, is still associated with a lower waist circumference and less metabolic dysfunction, such as lower triglycerides, higher HDL-c, and the absence of T2D [62]. Increased mass and activity of BAT after 10 days of cold acclimation (14–15 ◦C) in eight patients with

T2D resulted in enhanced peripheral insulin sensitivity by ~43%, which supports brown adipose tissue as a new approach for diabetes treatment [63].

A less frequent prevalence of BAT was noted in obese subjects compared to lean individuals, indicating the thermogenic effect of brown adipose tissue on body weight reduction [64]. This is also supported by the findings observed in patients after bariatric surgery [65] and in obese subjects after interventional studies [66], in whom weight loss enhanced the glucose uptake of BAT. The above-mentioned data highlight the association between BAT and body weight, with an emphasis on the beneficial effects of BAT in decreasing central adiposity, which is a metabolically harmful status.

Obesity is characterized by the chronic low-grade activation of the innate immune system. In this respect, macrophage-elicited metabolic inflammation and adipocyte– macrophage interactions have a primary importance in obesity [67]. Adipocyte hyper- trophy and local hypoxia due to adipocyte expansion are two important contributing factors to the increased accumulation of macrophages in adipose tissue in obesity. These adipocytes promote inflammation via their own cytokine and chemokine synthesis machin- ery [68]. The secretion of monocyte chemoattractant protein-1 (MCP-1) from adipocytes directly triggers the recruitment of macrophages to adipose tissue [69]. The microenvi- ronment in lean adipose tissue is composed of a 4:1 M2:M1 macrophage ratio. Indeed, diet-induced obesity leads to a shift in the activation state of adipose tissue macrophages from an M2-polarized state, which may protect adipocytes from inflammation, to an M1 proinflammatory state [70]. The primary trigger for the recruitment of M1 macrophages is thought to be the secretion of tumor necrosis factor TNF-α from hypertrophied adipocytes.

Surprisingly, in brown fat depots, the number of macrophages is rather low [16] or even undetectable [71]. Peterson et al. showed that macrophages make up only 30% of the BAT immune cell population, which is already less than 5% of all live cells. A reduction in the BAT macrophage percentage was also reported in obese mice [72]. Notably, macrophage infiltration and the secretion of inflammatory molecules in BAT were found to be significantly lower than those in WAT. Moreover, in the adipose tissue of mice with diet-induced obesity, the activation of classically activated macrophages was shown to suppress the induction of UCP-1 [71].

Brown adipocytes exhibit the intrinsic ability to impair the inflammatory profile of macrophages, while white adipocytes enhance this profile. This suggests that brown adipocytes may be less prone to adipose tissue inflammation, which is associated with obesity [73].

Recently, Fisher et al., demonstrated that the expression levels of almost all macrophage marker genes (M1 and M2) were much lower in the brown fat of mice acclimated to room temperature (middle-aged and young mice) than in the brown fat of thermoneutral mice (30 ◦C) [74]. Moreover, the expression levels of two genes related to thermogenesis (UCP1 and PGC1alfa) were found to be significantly higher in the brown fat of mice acclimated to room temperature. Neither temperature (thermoneutrality), an energy rich diet, nor increased age were found to be the factor most associated with macrophage accumulation in brown fat. The appearance of macrophages in brown fat coincides with the cessation of its thermogenic activity.

The majority of macrophages found in the brown fat of thermoneutral mice are organized into multinucleate giant crown-like structures. The authors hypothesize that the macrophages found in thermoneutral brown fat perform their conventional (but likely not their only) function: phagocytosis and degradation of dead cells. Brown fat macrophages

Int. J. Mol. Sci. 2021, 22, 1530 6 of 18 thus orchestrate tissue remodeling and enable the maintenance of metabolic homeostasis in tissue analogically to the situation in WAT [74].

The brown fat of thermoneutral mice retains full competence during the process of cold acclimation. Thus, profound macrophage accumulation does not influence the thermogenic recruitment competence of brown fat.

2.3. BAT, Glucose, and Lipid Metabolism The activation of brown adipose tissue is triggered by cold exposure. Lower tem- peratures are detected by skin receptors, which convey signals via the wider neuronal network, including the hypothalamus as a key regulator of body core temperature, through the spinal cord, and finally to the peripheral sympathetic nervous system (SNS) of BAT.

Noradrenalin is released after the activation of SNS; it then binds to adrenoreceptors (mainly the B3 receptor) and the lipolysis process of brown adipocytes is initiated. Fatty acids from triglyceride (TG) lipid droplets are the main source of oxidation by UCP1 in brown mitochondria. The reduced amount of TG needs to be restored mainly through the uptake of glucose, albumin-bound free FA, and TG-derived fatty acids from LDL and chylomicrons in the plasma. Findings from animal studies confirm the involvement of BAT in total energy expenditure and TG clearance and metabolism [75]. Moreover, in obese humans, cold exposure resulted in increased fatty acid uptake by BAT compared to muscle and white adipose tissue. BAT volume was significantly associated with lipid metabolism and adipose tissue insulin sensitivity in humans. Functional analysis of BAT and WAT demonstrated the greater thermogenic capacity of BAT compared to WAT, while molecular analysis revealed the cold-induced upregulation of genes involved in lipid metabolism only in BAT [76]. Furthermore, the increase in BAT CT radiodensity observed after acute cold exposure indicates reduced BAT triglycerides, suggesting the use of the BAT internal lipid stores [77]. Consistently, the impairment of intracellular lipids in BAT was found via necropsy in humans who had passed away from hypothermia [78] (Thus, acute BAT activation results in increased fat oxidation from the BAT lipid stores. It was estimated that with a mean total body BAT mass of 168 g [45], a reduction in BAT TG by about 8 g of TG (~72 kcal) was observed over two hours of very mild cold exposure [79], while prolonged BAT activation significantly increased TG clearance from the plasma to replenish intracellular lipids in brown adipocytes. Cold-induced BAT activation with non-esterified fatty acid (NEFA) uptake was shown to be associated with BAT thermogenesis [50] Notably, the disadvantage of using a fatty acid tracer compared to a glucose tracer is that the uptake of the fatty acid tracer is rather nonspecific, since such tracers are also largely taken up by the liver and intestines. Therefore, fatty acid tracers should be improved before they can be used in further research.

The use of the 18F-FDG tracer in imaging studies with PET confirmed glucose uptake by human BAT. The 18F-FDG tracer is a glucose analogue that is transported into cells by the same transporters as glucose. The presence of Glucose transporter type 4 GLUT-4 and GLUT-1 was first identified in brown murine adipocytes, suggesting both the insulin- dependent and insulin-independent uptake of glucose by the tissue [80] In activated BAT, glucose is utilized to refill intracellular lipid droplets and facilitate ATP generation, rather than oxidation, in non-shivering thermogenesis. The glucose clearance capacity of brown adipose tissue after cold exposure was confirmed in several studies; additionally, it was calculated that BAT accounts for ~1% of total body glucose use, compared to ~50% for skeletal muscle [48]. BAT glucose uptake in healthy individuals is responsible for the utilization of 5 g of glucose or ~23 kcal. Brown adipocytes fully oxidize the glucose that is taken up.

The insulin-mediated FDG uptake by BAT suggests that the GLUT-4 transporter participates in glucose uptake in human BAT. Consequently, BAT could be considered as an insulin-sensitive tissue [81,82]. Studies on animal models also confirmed the contribution of BAT to whole-body glucose metabolism [83]. In humans, the activity of BAT is associated with lower glycosylated hemoglobin (HbA1c) [84] and plasma insulin and glucose [85],

Int. J. Mol. Sci. 2021, 22, 1530 7 of 18 suggesting that BAT could have an impact on glucose metabolism. In warm conditions, with the use of a hyperinsulinemic euglycemic clamp, insulin was shown to stimulate BAT glucose uptake without stimulating blood flow, suggesting that insulin signaling increases

BAT glucose uptake independent of BAT thermogenic activation [80]. However, under cold exposure, as well as under conditions with a high level of insulin, glucose uptake is increased significantly, dissipating energy as a function of increased blood flow [80].

Subjects in whom brown adipocytes have been detected are more insulin sensitive, while in obese patients, despite cold-induced BAT activation, glucose uptake is blunted [66].

All data indicate that BAT activation participates in the regulation of insulin-mediated glucose disposal. Moreover, insulin seems to regulate BAT mass and function via the SNS.

In insulin-deprived animal models, the weight and thermogenic capacity of BAT declined, but re-adding insulin restored the function and mass of BAT [86]. In insulin receptor knock- out rodents, a decrease in BAT mass was observed [87]. Additionally, insulin enhances

UCP1 expression and thermogenic function in BAT via augmentation of the sympathetic nervous system [88,89]. In diabetic mice, insulin treatment was found to increase the UCP1 expression of BAT. However, denervation of the SNS seems to mediate the UCP1 content in BAT via insulin [90], indicating that an increase in UCP1 and BAT thermogenic function via insulin requires SNS activation.

The decreased activity of BAT, through impaired glucose uptake in resting conditions and reduced glucose clearance from serum, may predispose an individual to T2D. Re- cently published epidemiological outcomes indicated an association between increased glycosylated hemoglobin and an increased prevalence of diabetes with higher outdoor temperature [91]. Moreover, BAT activation with cold exposure is also associated with improved glucose homeostasis and insulin sensitivity in patients with T2D [64,92].

Another study has shown decreased BAT glucose uptake rates in overweight and T2D subjects vs. young healthy subjects with no reduced uptake of non-esterified fatty acids and thermogenic activity under cold stimulation [48].

Outcomes from a previous publication estimated a mean total volume of 18FDG- positive BAT at 150 mL in healthy adults [44], which could be due to the limitation of BAT metabolism in enhancing systemic glucose clearance. However, recently reported results featuring the three-dimensional mapping of adipose tissue depots with 18FDG PET/CT suggest that the total BAT volume may be much larger (ranging from 510 to 2358 mL) and could significantly influence glucose homeostasis.

2.4. BAT Activators The most common method of activation for brow adipocytes is cold exposure (Figure 1). The outcomes from PET/CT scans performed for various medical reasons have shown that BAT is much more commonly detectable in PET/CT scans during winter than during summer [77,93–95]. The 18 FDG uptake of BAT after acute cold exposure before scanning was higher [3,4,56] than that under warm conditions [96–98]]. Cold ac- tivates brown adipocytes through the sympathetic nervous system (SNS), which was confirmed by an increase in plasma and urinary noradrenaline levels in cold-exposed individuals [99,100]. The denervation of sympathetic nerves suppresses the cold-induced changes in BAT activity in animals [101]. To determine whether cold acclimation would also increase the amount of BAT or increase its efficiency, experimental studies evaluating two to six weeks of cold exposure noted remarkable increases in glucose uptake and the volume of active BAT, but no studies were able to confirm browning in the biopsies of subcutaneous abdominal WAT under these cooling conditions [46,56,102,103].

Int. J. Mol. Sci. 2021, 22, 1530 8 of 18 Figure 1. The interplay between brown adipocyte differentiation and activation, as well as insulin and glucose homeostasis. Classical brown adipocytes originate from mesodermal stem cells (Myf5+).

This process is mediated by the expression of molecular factors such as PRDM16, PPARγ, PGC-1a,

BMP7, IL-6, and FGF-21. Moreover, skeletal muscle cells originate from the same precursor cell.

Myf5−precursor cells are transformed into white or brite adipocytes. Beige adipocyte differentiation into classical brown adipocytes is induced by molecular factors, e.g., PRDM16 and BMP7, and environmental factors, e.g., chronic cold exposure and exercise, as well as PPARγ agonists. Brown adipocytes are activated by cold, diet, exercise, thyroid hormones, β3 agonists, increased energy expenditure, decreased fat content, and enhanced glucose and insulin homeostasis in humans, leading to a decreased rate of obesity and type 2 diabetes.

Cold exposure certainly plays the most significant role in increasing the metabolic rate via BAT activation. However, studies in both animals [104] and humans [105,106] indicated that food intake could also increase whole-body energy expenditure. This process is called diet-induce thermogenesis (DIT). Studies indicated that certain types of macronutrients can alter energy expenditure in different ways, suggesting that protein increases the metabolic rate more significantly than fats and carbohydrates [107]. The intake of food, especially carbohydrates, increases the activity of the sympathetic nervous system [107]. The idea of diet-induced BAT thermogenesis is based on observations showing that increased

SNS and BAT metabolic activities in diet-induced obesity are accompanied by lower weight gain than expected from caloric intake in rodents [108]. Recently published results showed no association between BAT activity and volume with quantified ad libitum energy intake or habitual energy intake estimated from 24 h dietary recalls in 102 young healthy humans [109].

Data from experimental studies indicate that some dietary supplements can increase the metabolic rate via the thermic effects caused by BAT; once such supplement is capsaicin derived from chili peppers. This supplement enhanced thermogenesis, accompanied by a reduction in body fat in both animals [110] and humans [111,112]. Capsaicin acts through vanilloid subtype 1 of the transient receptor potential (TRPV1) receptors on adipose tissue, inducing the brite phenotype in pre-adipocytes [113]. It also increases the central sympathetic stimulation of BAT via the activation of gastrointestinal TRPV1 receptors [114].

A similar thermic effect is also exerted by capsinoids, the non-pungent nutrients of capsaicin.

Capsinoids acutely alter resting energy expenditure only in BAT-positive subjects (but not in BAT-negative subjects) [115]. Recently, other dietary nutrients, such as polyunsaturated fatty acids (PUFAs), have been determined to induce BAT activation. In animal models, high-fat diets rich in PUFAs affected the expression of UCP1 mRNA in brown adipose tissue [116]. Outcomes from two other studies indicated that supplementation with omega n-3 long-chain polyunsaturated fatty acids enhanced thermogenesis via the activation of brown adipose tissue [117,118]. Moreover, a maternal diet rich in polyunsaturated fatty

Int. J. Mol. Sci. 2021, 22, 1530 9 of 18 acids was related to larger interscapular brown adipose tissue depots in animals [119,120].

The correct amount of brown and white adipose depots depends on maternal diet during pregnancy, and may be responsible for the development of obesity, insulin resistance, and

T2M in children later in life [121].

2.5. Brown and Brite Adipocytes Classical BAT depots are typically found in animals in interscapular, cervical, peri- aortic, peri-renal, intercostal, and mediastinal areas [122]. The brown adipocytes that are detected via PET/CT in humans, typically in supraclavicular, neck, paravertebral, and suprarenal sites [2], refer to brown-like adipocytes called brite (from brown to white) [123], beige [124], or recruitable [125]] cells rather than classical brown fat (Table 1).

Table 1. A summary of the main anatomical, cellular, and molecular differences amongst BAT, beige (brite), and WAT and their involvement in obesity and other human disorders.

Classical Brown Adipocytes Beige (Brite) Adipocytes

White Adipocytes Anatomical differences Mainly in interscapular regions

Scattered among white adipose tissue in the cervical, supraclavicular, and paravertebral regions

Subcutaneous regions, intra-abdominal region, other sites: retro-orbital, bone marrow, pericardial

Cellular differences Multilocular histology with a central nucleus and an abundant number of large mitochondria, dense vascularity, and innervation by the sympathetic nervous system

Lipid droplet size and mitochondria content is intermediary between classical brown and white adipocytes. Brite adipocytes have multiple lipid droplets and more mitochondria than white adipocytes

Unilocular morphology, triacylglycerols are stored in one large droplet inside the cell

Molecular differences UCP1-dependent UCP1-dependent

PPRGγ PGC 1α PRDM16 PPRGγ Clinical outcomes in humans

Increased metabolic rate, decreased body weight, increased insulin sensitivity

Increased metabolic rate, decreased body weight, increased insulin sensitivity

Energy storage, obesity, type 2 diabetes In adults, brown-like adipocytes with typical brown adipocytes are scattered among white adipocytes in supraclavicular regions [51] and are activated under special conditions like exposure to cold, sympathetic agonists, capsaicin, or irisin. The estimated mass of

BAT in humans is in the range of 50–70 g [126], with a small amount able to significantly increase energy expenditure. Therefore, scientific interest is focused on how to increase the current amount of BAT and profoundly enhance its activity.

Classical brown adipocytes originate from myogenic factor 5 positive (Myf5+) progeni- tor cells, similar to skeletal myocytes [127]. In contrast, brite adipocytes have been shown to be derived from Myf5 negative (Myf5−) progenitor cells, much like white adipocytes [15].

Their morphology (lipid droplet size and mitochondria content) is intermediary between that of classical brown and white adipocytes. Brite adipocytes feature multiple lipid droplets (though often larger than those seen in brown adipocytes), more mitochondria than white adipocytes, and the expression of UCP1 [128,129] (Figure 1). Classical and brite adipocytes differ in their developmental origin, but both seem to contribute to thermoge- nesis [130]. The methods used to initiate brite/beige cell formation in brown adipocytes are as follows: acclimation to severe/mild cold temperatures [131], β-adrenergic agonist treatment [132], increased PPARγ, diet, and exercise. Stimulating brite/beige adipocyte formation in humans could be another way to improve glucose homeostasis and a strategy to combat obesity.

The molecular factors that significantly participate in the adipogenesis of brown and white adipocytes are PPARγ and CCAAT-enhancer binding protein (C/EBP) [133]. These

Int. J. Mol. Sci. 2021, 22, 1530 10 of 18 transcriptional factors are responsible for adipogenic differentiation and the impairment of

PPARγ and C/EBP, decreasing BAT recruitment [134]. PPARγ is necessary for adipocyte differentiation and lipid storage and has antidiabetic effects. After RRARγ binds to its receptor, the expression of genes such as C/EBP increases. This heterodimer links to protein-containing PR domain 16 (PRDM16) and stimulates the differentiation of brown fat cells [135]. Subsequently, PPARγ activates its coactivator 1a (PGC-1α), which enhances

UCP1 expression [136]. PGC-1α is a coactivator of PPARγ in brown adipocytes; PGC-1α also regulates energy balance and mediates brown fat cell differentiation [137]. The main role of PGC-1α is to enhance the expression of UCP1, respiratory chain proteins, Krebs cycle proteins, and FA oxidative enzymes [138]. The most prominent role in the differentiation of brown adipocytes seems to be played by PRDM16, which directly interferes with PGC-1α, stimulating the interaction between PGC-1α and PPARγ. This protein promotes the switch from white pre-adipocytes to brown adipocytes [139]. Brown pre-adipocytes decrease the expression of PRDM16, resulting in differentiation into skeletal muscle cells [140]. Another essential player in the development of BAT is bone morphogenetic proteins (BMPs). Among the members of the BMP family, BMP7 is characteristic of BAT and enhances the expression of all early regulators of BAT, such as PRDM16, PGC-1α, UCP1, PPARγ, and C/EBP. A

BMP7 knockout animal model showed the depletion of UCP1 but the preservation of WAT differentiation. Conversely, the administration of exogenous BMP7 in these mice promoted

BAT but not WAT development, with a consistent increase in energy consumption and a lack of weight gain [141]. BMP-7 was also reported to induce the browning of WAT and to improve insulin sensitivity [126]. Other mediators of BAT activation with beneficial effects on glucose tolerance and insulin sensitivity are fibroblast growth factor 21 (FGF-21) and interleukin-6 (IL-6). In animals, following cold exposure, FGF21 expression was reduced in the liver (where it is produced), but enhanced in brown and white adipose tissue, where

FGF21 enhances UCP1 expression and the browning of subcutaneous tissue [142]. These findings have been confirmed in humans, where exposure to decreased temperature in- creases diurnal plasma FGF21 levels, showing a positive correlation with lipolysis and cold-induced thermogenesis [143]. PPARγ transcriptionally controls FGF21, which then acts as an autocrine or paracrine mediator to increase PPARγ transcriptional activity [144].

FGF21, by increasing UCP1 expression, seems to improve glucose metabolism. These find- ings were supported by the results from an experimental study on obese animals in which the injection of FGF21 reduced adiposity, improved glycemic control, and increased energy expenditure [145]. Interleukin-6 (IL-6), a proinflammatory cytokine mainly associated with insulin resistance and type 2 diabetes, plays an interesting role in BAT activation [146]. In obesity, IL-6 is typically secreted from visceral rather than subcutaneous adipocytes [147].

Notably, in studies evaluating BAT activity under cold conditions, a significant increase in IL-6 secretion was observed [148]. Moreover, the administration of IL-6 was shown to attenuate weight gain and visceral obesity without affecting food intake. Furthermore, in the same study, IL-6 augmented UCP1 expression in BAT via stimulation of the sympathetic nervous system [149]. This was mediated by the phosphorylation of the signal transducer and activator of transcription 3 (pSTAT3). Further confirming the association between

IL-6 and brown adipocytes is a study in which BAT transplantation caused increased insulin-stimulated glucose uptake in both brown and white adipocytes in the heart, but not in skeletal muscle. Moreover, this beneficial metabolic profile was decreased when the BAT used for transplantation came from IL-6 knockout mice, suggesting that BAT-derived IL-6 is necessary to achieve the significant effects of BAT transplantation on glucose homeostasis and insulin sensitivity [82]. Interestingly, IL-6 is a cytokine known to be secreted by skeletal muscle in response to exercise, thereby increasing its insulin sensitizing effects [150].

Skeletal muscles during physical activity are the source of another protein named irisin, which has a significant browning effect on white adipocytes in mice. Irisin is myokine-cleaved from fibronectin type III domain containing protein 5 (FNDC5), which is released by the exercising muscle. In animal models, an increase in irisin during ex- ercise or exogenous administration resulted not only in an increase in WAT browning,

Int. J. Mol. Sci. 2021, 22, 1530 11 of 18 but also in a significant reduction in body weight and an improvement in glucose tol- erance [151]. Outcomes from animal studies suggest that irisin could exert a positive metabolic effect during exercise through the browning of white adipocytes. Several stud- ies have also been performed to evaluate the role of irisin in humans. Some of these studies confirmed an acute increase in plasma irisin level after exercise [152–155], while others have not [156,157]. Moreover, the results from interventional studies assessing the influence of different types of training on irisin levels are inconsistent. Only one study showed an increase in irisin levels after 10 weeks of endurance training [151], while after

12 weeks of combined endurance and strength training, no positive association between irisin level and physical activity [155] was observed. Moreover, after long-term training with both aerobic endurance and strength endurance regimens, no effect was observed on irisin concentration [153,157,158]. Experimental studies on human adipocytes treated with irisin showed an increased expression of UCP1 mRNA predominantly in classical brown adipocytes rather than white adipocytes [156]. Irisin (encoded by FNDC5) can increase energy expenditure in humans by inducing browning. Moreover, it was noted that FNDC5 gene expression in human muscle biopsies and adipose tissue with circulating irisin levels is correlated with obesity, insulin sensitivity, and T2D. These results showed that circulating irisin could induce browning of human adipose tissue, leading to the improved function and capacity of BAT and enhancing FNDC5 gene expression in adipose tissue. Moreover, a previous study observed decreased circulating irisin concentrations and FNDC5 gene expression in adipose tissue and muscle from obese and T2D subjects, suggesting a loss of brown fat-like characteristics [159]. Therefore, the role of irisin in humans in terms of BAT activation and glucose homeostasis should be further investigated.

3. Conclusions and Future Perspectives The function of activated brown adipose tissue does not only promote negative energy balance, but also alleviates metabolic complications such as insulin resistance, dyslipidemia, and disturbances in glucose homeostasis. There is still debate around how to maintain and activate the significant number of brown adipocytes needed to exert anti-type 2 diabetic effects. Therefore, future studies will involve the search for new BAT activators.

Currently, the best-explored BAT activators are cold exposure and sympathetic ner- vous system agonists. In terms of the metabolic benefits resulting from BAT activation, the most important future perspective is to investigate the new molecular and environmental factors elucidating BAT activation, as well as the browning of WAT. The re-activation and recruitment of BAT in obese individuals is especially important because such individuals will receive the most benefit. It remains challenging to identify BAT activators that will be effective under conditions other than cold exposure. Moreover, the role of diet and nutrients is worth exploring to find new methods of BAT activation. Thus far, it has been shown that the stimulation of transient receptor potential channels via some food ingre- dients, such as capsinoids and the catechins found in green tea, exert anti-obesity effects by the activation and acquisition of new brown adipocytes. Another major goal for future research is the identification of brown adipokines or batokines that could be candidates for drug development to treat obesity or metabolic disease.

The influence of BAT on energy expenditure is underestimated due to the small volume of BAT as measured using 18FDG PET. The accurate measurement of BAT volume is a major limitation, especially in individuals with obesity and T2D. The development of novel imaging methods for the precise quantification of BAT volume and activity is required to assess the true potential of targeting BAT thermogenesis to prevent or treat metabolic disorders.

Author Contributions: Conceptualization, K.M.; original draft preparation, K.M.; review process,

K.M.; review, editing final manuscript, supervision, A.K. All authors have read and agreed to the published version of the manuscript.

Funding: This research received no external funding.

Int. J. Mol. Sci. 2021, 22, 1530 12 of 18 Conflicts of Interest: The authors declare no conflict of interest.

Abbreviations BAT Brown adipose tissue WAT White adipose tissue

UCP1 Uncoupling protein 1 TG Triglycerides EE Energy expenditure

CIT Cold-induced thermogenesis DIT Diet-induced thermogenesis

VAT Visceral adipose tissue SAT Subcutaneous adipose tissue

PPARγ Peroxisome proliferator-activated receptor γ

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# 棕色脂肪组织及其在胰岛素和葡萄糖稳态中的作用

## 摘要

全球范围内肥胖、胰岛素抵抗及其相关代谢并发症发病率的不断上升,促使科学界寻求对抗肥胖的新途径。棕色脂肪组织(BAT)因其线粒体内膜中特有的解偶联蛋白1(UCP1)而被认为是一种极具前景的增加能量消耗的方法。活化的棕色脂肪细胞以产热形式耗散能量。换言之,BAT能够燃烧脂肪并提高代谢率,从而促进负能量平衡。此外,BAT还能改善血脂异常、胰岛素分泌受损以及2型糖尿病中的胰岛素抵抗等代谢并发症。本综述旨在探讨BAT在总能量消耗以及脂质和葡萄糖稳态中的作用,并讨论在人体中激活棕色脂肪组织以治疗肥胖和代谢疾病的新可能途径。

**关键词:** 棕色脂肪组织;肥胖;2型糖尿病;胰岛素抵抗;代谢

## 1. 引言

多年来,棕色脂肪组织(BAT)一直被认为仅存在于新生儿和小型哺乳动物中,通过非颤抖性产热来产生热量以抵御低体温。然而,儿童体内大量的活跃BAT在青春期后迅速减少。成人活跃BAT的确切数量(体积)差异很大,但根据最近发表的一项系统综述和荟萃分析的结果,成人棕色脂肪组织的患病率估计为6.97%[1]。BAT的首次临床观察来自肿瘤学患者,这些患者的正电子发射断层扫描结合计算机断层扫描(PET/CT)或磁共振PET/MR成像显示颈部脂肪组织具有高代谢活性[2]。2009年,经过专门的冷暴露研究,证实了成人功能性棕色脂肪的存在[3-5]。

全球肥胖患病率的增加促使科学界寻找应对体重增加的新途径[6]。肥胖是一个主要的健康风险因素,与胰岛素抵抗的发生密切相关,而胰岛素抵抗是代谢并发症、2型糖尿病和心血管疾病发病机制中的关键因素[7]。肥胖率的增加与预期寿命的缩短相关,同时也带来了巨大的经济负担[8]。

BAT是一种通过产热来维持体温高于环境温度的组织,主要通过非颤抖性产热实现。这一过程由丰富线粒体内膜中解偶联蛋白1(UCP1)的表达所介导[9]。尽管线粒体含量高且细胞呼吸速率高,但棕色脂肪细胞的三磷酸腺苷(ATP)合成能力却非常低[10]。与大多数人类细胞不同,棕色脂肪细胞通过UCP1表达和低ATP合酶活性,解偶联细胞呼吸,降低线粒体ATP合成,从而刺激产热。

由于其独特的UCP1,棕色脂肪组织被认为是一种极具前景的增加能量消耗的方法[11]。换言之,BAT燃烧脂肪并提高代谢率,促进负能量平衡[12]。此外,BAT还能改善血脂异常、胰岛素分泌受损以及2型糖尿病中的胰岛素抵抗等代谢并发症[13]。

BAT在代谢后果方面的保护作用促使了对棕色脂肪细胞分化的分子探索。参与棕色和白色脂肪组织形成的最相关分子因子是过氧化物酶体增殖物激活受体(PPARs)[14]。PPARγ在组织发育和功能中发挥关键作用,在脂肪生成过程中诱导UCP1表达[15]。此外,PPARγ激动剂可用于诱导白色脂肪组织的褐变[16],而PPARα激活则通过过氧化物酶体增殖物激活受体γ共激活因子1α(PGC1α)促进米色脂肪生成,PGC1α是线粒体生物发生、适应性产热和氧化代谢的关键调节因子。在白色脂肪组织(WAT)褐变涉及的分子通路中,关键因子是含PR结构域蛋白16(PRDM16),它控制骨骼肌母细胞和棕色脂肪细胞之间的转换,并通过直接结合PPARγ刺激脂肪生成[17]。最近的研究表明,棕色和米色脂肪细胞在产热活动响应中释放生长和分化因子15(GDF15)。GDF15可能介导局部炎症通路的下调[18]。此外,在脂肪组织生物学中,某些microRNA在调节BAT和WAT功能及分化方面发挥重要作用。此类microRNA通过靶向关键转录因子(如PRDM16、PPARγ、CCAAT-增强子结合蛋白C/EBPβ和PGC1α)来调节白色、棕色和米色脂肪生成[19]。

本综述旨在探讨BAT在全身能量消耗以及脂质和葡萄糖稳态中的作用,并讨论在人体中激活棕色脂肪组织以治疗肥胖和代谢疾病的新可能途径。

## 2. 棕色脂肪细胞的形态学

棕色脂肪组织(BAT)和白色脂肪组织(WAT)共同构成人体的总脂肪组织。尽管两者具有相似的结构成分(脂肪细胞),但两种脂肪组织的功能不同。白色脂肪组织储存能量,而棕色脂肪组织产生体热。棕色脂肪组织由棕色脂肪细胞(比白色脂肪细胞小)和位于多个小脂滴中的脂质组成,使棕色脂肪细胞呈现多房室组织学特征[20],细胞核居中,线粒体丰富。密集的血管化和交感神经系统支配是棕色脂肪细胞的特征[21]。白色脂肪细胞具有单房室形态,三酰甘油储存在细胞内的一个大脂滴中。WAT沉积主要位于皮肤下方(皮下脂肪组织(SAT))和内脏器官周围(内脏脂肪组织(VAT))。然而,少量WAT也见于血管周围和心包区域、纵隔后隐窝空间和骨髓[22]。白色脂肪细胞的主要功能是作为脂质储备,脂质可被氧化产生能量,并通过储存甘油三酯保护人体免受过量葡萄糖的损害[23]。在白色脂肪细胞中散布着米色(brite)脂肪细胞,它们可转化为棕色脂肪细胞。WAT的褐变由冷暴露或基因修饰诱导。棕色脂肪细胞与典型BAT具有相似的形态、分子特征和功能。

传统上将白色脂肪组织视为被动能量储存的观点已不再成立。近年来,脂肪组织被认为是一个复杂、高度活跃的代谢和内分泌器官[24],特别强调内脏脂肪更容易诱发胰岛素抵抗、2型糖尿病或未来心血管事件[25]。相比之下,棕色脂肪细胞具有在寒冷环境中通过非颤抖性产热产生热量来维持正常体温的能力[26]。棕色脂肪细胞在被冷暴露激活后,开始氧化自身的脂质储存或从循环中清除的脂肪酸以及其他底物(如葡萄糖)来产生热量并提高代谢率。棕色脂肪细胞的独特功能归因于线粒体内膜中UCP1的表达[27]。UCP1仅在BAT中发现,因此是该组织的理想标志物。几乎所有人类细胞线粒体(棕色脂肪线粒体除外)都负责ATP合成,涉及脂质或葡萄糖的利用。这一过程称为呼吸偶联,其中还原型辅酶再氧化和氧消耗释放的能量用于将ADP磷酸化为ATP[28]。呼吸能量的一部分也以热量形式损失。由于UCP1的存在,棕色脂肪细胞线粒体在不必磷酸化ADP的情况下进行呼吸;在这种独特情况下,能量以热量形式耗散[29]。BAT燃烧脂肪和增强能量消耗的能力可作为对抗肥胖和代谢疾病的新型治疗工具[30]。

### 2.1. BAT与能量平衡

产热通常被描述为任何释放热量的代谢过程,因此全身产热是总能量消耗(EE)的对应物[31]。因此,体温可在产热水平(如颤抖性和非颤抖性产热)和热量损失水平(如高温和运动时的出汗)进行调节[32]。产热或每日总能量消耗(ADMR)可分为基础代谢率(BMR,约占ADMR的55-65%)、饮食诱导的产热(DIT,约占ADMR的10%)和体力活动的能量消耗(AEE)。BMR保持相对恒定,主要由瘦体重决定[33]。总每日能量消耗的另一种描述方式是必需产热和兼性产热[34]。必需产热是指日常身体功能所需的能量消耗,即细胞和器官维持日常生存功能所需的能量。这还包括DIT和AEE中不需要额外产热的部分。相比之下,兼性产热与寒冷和饮食引起的额外产热有关——分别是寒冷诱导的产热(CIT)和DIT。就人棕色脂肪及其在能量消耗中的作用而言,最重要的过程是寒冷诱导的产热。CIT由颤抖性产热(ST)和非颤抖性产热(NST)组成。在ST中,冷暴露引起的肌肉不自主收缩是中度至极端寒冷条件下产热的主要贡献者[35]。ST可使人体能量消耗增加至BMR的3-5倍。然而,颤抖通常令人不适,导致疲劳,并对我们的运动协调产生负面影响。NST通过UCP1激活棕色脂肪组织(BAT)和通过肌脂蛋白激活骨骼肌来实现[36]。使用烟酸抑制BAT产热导致肌肉颤抖增加以对抗低温,这证明了BAT在寒冷诱导产热中的重要作用[37]。活跃的BAT可贡献人体静息代谢率的2-5%[38,39]。此外,非颤抖性产热可在无不适的情况下维持。考虑到这一事实,棕色脂肪组织的激活似乎是增加能量消耗的可能机制之一[40],从而产生负能量平衡。这可能具有重要的健康意义,表明BAT的持续激活可能减轻肥胖及其相关疾病。

识别和评估BAT体积的金标准方法是18FDG(18氟-脱氧-葡萄糖)PET/CT[41],但BAT葡萄糖代谢并不能准确反映BAT产热活性[42]。值得注意的是,细胞内甘油三酯(TG)是人类寒冷诱导BAT激活后最初使用的主要能量来源[37,43]。TG是线粒体氧化代谢的主要燃料,因此BAT葡萄糖摄取应与产热解偶联[44]。BAT的葡萄糖摄取和代谢更好地反映了BAT的胰岛素敏感性。使用另一种示踪剂11C-乙酸盐(评估克雷布斯循环速率)的研究更准确地验证了BAT在人体寒冷诱导产热中的作用[45],显示通过寒冷适应BAT产热增加2-3倍[46,47],在T2D受试者中没有减少,尽管BAT葡萄糖摄取大幅下降[48]。使用15O2评估BAT氧消耗的研究估计BAT能量消耗水平为15-25千卡/天[49]。另一个研究小组报告使用相同示踪剂的BAT产热在室温下约为7千卡/天,在轻度冷暴露下健康受试者中约为10千卡/天[50]。这些数据量相当小,可能是当前使用18FDG PET测量总体积的局限性所致,尤其是在肥胖和T2D个体中。使用放射学3D映射测量代谢活跃的BAT估计,BAT对产热的最大贡献在室温下为每天27-123千卡,在轻度冷暴露下为每天46-211千卡[51]。同一研究表明,总体脂质量的4.3%反映了冷暴露后具有显著葡萄糖摄取的脂肪组织。BAT的平均质量在成人中为50-70克[3];如此数量的活跃BAT可使每日能量消耗增加约170千卡。一项介入性研究的结果支持棕色脂肪组织在人体能量平衡中的作用,该研究中在基线就诊时无活跃BAT的患者在冷暴露六周后体重减轻,BAT活性增加1.5倍[52]。据计算,63克完全激活的锁骨上BAT将消耗相当于4.1克WAT的能量[3]。一项实验研究支持BAT对能量消耗的显著影响,其中用β3-肾上腺素能激动剂米拉贝隆治疗不仅增加了能量消耗(203±40千卡/天),还增加了有益脂蛋白(HDL和ApoA1)和抗糖尿病蛋白(脂联素),并改善了胰岛素分泌和敏感性[53]。

最近的发现显示了BAT中兼性能量消耗的不同机制,包括基于肌酸[54]和琥珀酸[55]的无效循环。在米色脂肪细胞中,冷暴露引起线粒体肌酸激酶活性并增加与肌酸代谢相关的基因表达。当UCP1依赖性产热被消除时,肌酸代谢的代偿基因被诱导。从细胞外环境积累的琥珀酸被棕色脂肪细胞线粒体迅速摄取,其被琥珀酸脱氢酶(SDH)氧化是激活产热所必需的。研究发现,SDH介导的琥珀酸氧化引发活性氧(ROS)产生,从而驱动UCP1依赖性产热呼吸,而SDH抑制则抑制产热。这些研究的发现是使用啮齿动物模型确定的,仍需在人体中进行评估。

### 2.2. BAT、肥胖与胰岛素抵抗

负能量平衡并不是支持使用棕色脂肪组织治疗肥胖的唯一因素;另一个重要特征是BAT能够减轻胰岛素抵抗和葡萄糖稳态紊乱。实验研究的结果显示,活跃BAT与体重指数(BMI)呈负相关,这进一步证实了BAT与体重之间的关系[56]。可检测到BAT的患者体重指数较低,能量消耗增加。就肥胖和BAT而言,棕色脂肪细胞在中央性肥胖和肝脏脂肪患者中较少出现[5]。已知内脏脂肪组织是一个活跃的内分泌器官,对胰岛素抵抗有很大贡献。BAT活性与VAT量之间的负相关关系通过BAT激活预防和治疗代谢疾病的前景令人乐观[57]。小鼠BAT的切除或去神经支配加剧高甘油三酯血症和肥胖[58]。血清高甘油三酯血症随后在WAT中储存(异位储存在骨骼肌和肝脏中)降低了这些器官的胰岛素敏感性并增加了T2D的风险[59]。棕色脂肪细胞清除血清中的TG用于补充用于非颤抖性产热的脂质储存。此外,在高脂饮食的动物模型中,BAT移植显著减轻体重和脂肪组织炎症,并增加整体葡萄糖耐量和胰岛素敏感性。切除棕色脂肪细胞导致体重、脂肪组织炎症和胰岛素抵抗显著增加[60]。此外,BAT活性随年龄增长而下降会增加过度脂肪积累[52]。与年龄相关的BAT减少被解释为线粒体功能丧失、UCP1表达下降、交感神经系统损伤以及棕色脂肪生成干细胞/祖细胞功能改变[61]。相比之下,最近发表的研究结果表明,即使在60岁以上患有心血管疾病的个体中,BAT的存在仍与较低的腰围和较少的代谢功能障碍相关,如较低的甘油三酯、较高的HDL-c和不存在T2D[62]。8名T2D患者经过10天寒冷适应(14-15°C)后BAT质量和活性增加导致外周胰岛素敏感性提高约43%,这支持棕色脂肪组织作为糖尿病治疗的新途径[63]。

与瘦个体相比,肥胖受试者中BAT的患病率较低,表明棕色脂肪组织对体重减轻的产热作用[64]。这也得到了减重手术患者[65]和肥胖受试者介入性研究[66]中观察到的发现的支持,在这些研究中,体重减轻增强了BAT的葡萄糖摄取。上述数据强调了BAT与体重之间的关系,重点强调了BAT在减少中心性肥胖(一种代谢有害状态)方面的有益作用。

肥胖的特征是先天免疫系统的慢性低度激活。在这方面,巨噬细胞引发的代谢炎症和脂肪细胞-巨噬细胞相互作用在肥胖中具有首要重要性[67]。脂肪细胞肥大和脂肪细胞扩张导致的局部缺氧是肥胖中脂肪组织巨噬细胞积累增加的两个重要促成因素。这些脂肪细胞通过自身的细胞因子和趋化因子合成机制促进炎症[68]。脂肪细胞分泌的单核细胞趋化蛋白-1(MCP-1)直接触发巨噬细胞向脂肪组织的募集[69]。瘦脂肪组织的微环境由4:1的M2:M1巨噬细胞比例组成。事实上,饮食诱导的肥胖导致脂肪组织巨噬细胞从M2极化状态(可保护脂肪细胞免受炎症)向M1促炎状态的转变[70]。M1巨噬细胞募集的主要触发因素被认为是肥大脂肪细胞分泌的肿瘤坏死因子TNF-α。令人惊讶的是,在棕色脂肪库中,巨噬细胞数量相当低[16]甚至无法检测到[71]。Peterson等人表明,巨噬细胞仅占BAT免疫细胞群的30%,这已经不到所有活细胞的5%。肥胖小鼠中BAT巨噬细胞百分比的减少也有报道[72]。值得注意的是,BAT中巨噬细胞浸润和炎症分子的分泌显著低于WAT。此外,在饮食诱导肥胖的小鼠脂肪组织中,经典激活的巨噬细胞的激活被显示抑制UCP-1的诱导[71]。

棕色脂肪细胞表现出损害巨噬细胞炎症特征的内在能力,而白色脂肪细胞增强这一特征。这表明棕色脂肪细胞可能不易发生与肥胖相关的脂肪组织炎症[73]。

最近,Fisher等人证明,在室温适应的小鼠(中年和小鼠)的棕色脂肪中,几乎所有巨噬细胞标志物基因(M1和M2)的表达水平都远低于热中性小鼠(30°C)的棕色脂肪[74]。此外,发现与产热相关的两个基因(UCP1和PGC1α)的表达水平在室温适应小鼠的棕色脂肪中显著较高。温度(热中性)、高能量饮食或年龄增长均未被发现是与棕色脂肪中巨噬细胞积累最相关的因素。棕色脂肪中巨噬细胞的出现与其产热活动的停止相吻合。

在热中性小鼠棕色脂肪中发现的大多数巨噬细胞组织成多核巨大冠状结构。作者假设在热中性棕色脂肪中发现的巨噬细胞执行其常规(但可能不是唯一的)功能:吞噬和降解死亡细胞。因此,棕色脂肪巨噬细胞协调组织重塑并使组织中的代谢稳态维持成为可能,类似于WAT中的情况[74]。

热中性小鼠的棕色脂肪在寒冷适应过程中保持完全能力。因此,巨噬细胞的大量积累不影响棕色脂肪的产热募集能力。

### 2.3. BAT、葡萄糖和脂质代谢

棕色脂肪组织的激活由冷暴露触发。较低的温度由皮肤感受器检测,这些感受器通过更广泛的神经网络(包括作为体核温度关键调节器的下丘脑)通过脊髓将信号传递至BAT的外周交感神经系统(SNS)。SNS激活后释放去甲肾上腺素,然后与肾上腺素能受体(主要是B3受体)结合,启动棕色脂肪细胞的脂肪分解过程。来自甘油三酯(TG)脂滴的脂肪酸是棕色线粒体中UCP1氧化的主要来源。减少的TG量主要通过摄取葡萄糖、白蛋白结合的游离FA以及来自血浆中LDL和乳糜微粒的TG衍生脂肪酸来恢复。动物研究的结果证实了BAT参与总能量消耗和TG清除及代谢[75]。此外,在肥胖人群中,冷暴露导致BAT的脂肪酸摄取增加,高于肌肉和白色脂肪组织。BAT体积与人体脂质代谢和脂肪组织胰岛素敏感性显著相关。BAT和WAT的功能分析表明,BAT的产热能力大于WAT,而分子分析揭示了仅在BAT中脂质代谢相关基因的冷诱导上调[76]。此外,急性冷暴露后观察到的BAT CT放射密度增加表明BAT甘油三酯减少,提示BAT内部脂质储存的利用[77]。一致地,在死于低温症的人类尸检中通过尸检发现BAT细胞内脂质受损[78](因此,急性BAT激活导致BAT脂质储存的脂肪氧化增加。据估计,在平均总体BAT质量为168克[45]的情况下,在非常轻度冷暴露两小时内观察到BAT TG减少约8克TG(~72千卡)[79],而延长的BAT激活显著增加血浆中TG的清除以补充棕色脂肪细胞中的细胞内脂质。寒冷诱导的BAT激活与非酯化脂肪酸(NEFA)摄取被显示与BAT产热相关[50]。值得注意的是,与使用葡萄糖示踪剂相比,使用脂肪酸示踪剂的缺点是脂肪酸示踪剂的特异性相当低,因为此类示踪剂也被肝脏和肠道大量摄取。因此,脂肪酸示踪剂应在进一步研究之前进行改进。

在PET成像研究中使用18F-FDG示踪剂证实了人体BAT的葡萄糖摄取。18F-FDG示踪剂是一种葡萄糖类似物,通过与葡萄糖相同的转运蛋白转运到细胞中。葡萄糖转运蛋白4型GLUT-4和GLUT-1首先在棕色小鼠脂肪细胞中被鉴定,表明该组织对葡萄糖的胰岛素依赖性和非胰岛素依赖性摄取[80]。在活化的BAT中,葡萄糖用于补充细胞内脂滴并促进ATP生成,而非在非颤抖性产热中氧化。冷暴露后棕色脂肪组织的葡萄糖清除能力在多项研究中得到证实;此外,据计算,BAT约占全身葡萄糖利用的~1%,而骨骼肌约占~50%[48]。健康个体中的BAT葡萄糖摄取负责利用5克葡萄糖或约23千卡。棕色脂肪细胞完全氧化摄取的葡萄糖。

BAT中胰岛素介导的FDG摄取表明GLUT-4转运蛋白参与人体BAT中的葡萄糖摄取。因此,BAT可被视为胰岛素敏感组织[81,82]。动物模型的研究也证实了BAT对全身葡萄糖代谢的贡献[83]。在人体中,BAT活性与较低的糖化血红蛋白(HbA1c)[84]以及血浆胰岛素和葡萄糖[85]相关,表明BAT可能对葡萄糖代谢产生影响。在温暖条件下,使用高胰岛素-正常血糖钳夹,胰岛素被显示可在不刺激血流的情况下刺激BAT葡萄糖摄取,表明胰岛素信号传导增加BAT葡萄糖摄取独立于BAT产热激活[80]。然而,在冷暴露以及高胰岛素水平条件下,葡萄糖摄取显著增加,随着血流增加而耗散能量[80]。检测到棕色脂肪细胞的受试者胰岛素敏感性更高,而在肥胖患者中,尽管寒冷诱导BAT激活,但葡萄糖摄取减弱[66]。所有数据表明,BAT激活参与调节胰岛素介导的葡萄糖处置。此外,胰岛素似乎通过SNS调节BAT质量和功能。在胰岛素缺乏的动物模型中,BAT的重量和产热能力下降,但重新添加胰岛素恢复了BAT的功能和质量[86]。在胰岛素受体敲除的啮齿动物中,观察到BAT质量下降[87]。此外,胰岛素通过增强交感神经系统增强BAT中UCP1表达和产热功能[88,89]。在糖尿病小鼠中,发现胰岛素治疗增加BAT的UCP1表达。然而,SNS的去神经支配似乎通过胰岛素介导BAT中的UCP1含量[90],表明通过胰岛素增加UCP1和BAT产热功能需要SNS激活。

BAT活性降低,在静息条件下葡萄糖摄取受损和血清葡萄糖清除减少,可能使个体易患T2D。最近发表的流行病学结果表明,糖化血红蛋白增加和糖尿病患病率增加与较高的室外温度相关[91]。此外,冷暴露的BAT激活也与T2D患者葡萄糖稳态和胰岛素敏感性改善相关[64,92]。另一项研究显示,与年轻健康受试者相比,超重和T2D受试者的BAT葡萄糖摄取率降低,而在冷刺激下非酯化脂肪酸摄取和产热活性没有减少[48]。

先前发表的结果估计健康成人中18FDG阳性BAT的平均总体积为150毫升[44],这可能是由于BAT代谢在增强全身葡萄糖清除方面的局限性。然而,最近报道的使用18FDG PET/CT对脂肪库进行三维映射的结果表明,总体BAT体积可能大得多(范围为510至2358毫升),并可能显著影响葡萄糖稳态。

### 2.4. BAT激活剂

棕色脂肪细胞最常见的激活方法是冷暴露(图1)。为各种医学原因进行的PET/CT扫描结果显示,在冬季的PET/CT扫描中比夏季更常检测到BAT[77,93-95]。扫描前急性冷暴露后BAT的18FDG摄取[3,4,56]高于温暖条件下的摄取[96-98]。冷通过交感神经系统(SNS)激活棕色脂肪细胞,这通过冷暴露个体血浆和尿液中去甲肾上腺素水平的升高得到证实[99,100]。在动物中,交感神经的去神经支配抑制了冷诱导的BAT活性变化[101]。为了确定寒冷适应是否也会增加BAT的数量或提高效率,评估两到六周冷暴露的实验研究注意到活跃BAT的葡萄糖摄取和体积显著增加,但没有研究能够证实在这些冷却条件下皮下腹部WAT活检中的褐变[46,56,102,103]。

**图1.** 棕色脂肪细胞分化和激活与胰岛素和葡萄糖稳态之间的相互作用。经典棕色脂肪细胞起源于中胚层干细胞(Myf5+)。这一过程由PRDM16、PPARγ、PGC-1α、BMP7、IL-6和FGF-21等分子因子的表达介导。此外,骨骼肌细胞起源于相同的前体细胞。Myf5-前体细胞转化为白色或棕色脂肪细胞。米色脂肪细胞向经典棕色脂肪细胞的分化由分子因子(如PRDM16和BMP7)和环境因素(如长期冷暴露和运动)以及PPARγ激动剂诱导。棕色脂肪细胞被冷、饮食、运动、甲状腺激素、β3激动剂激活,增加能量消耗,减少脂肪含量,增强人体葡萄糖和胰岛素稳态,从而降低肥胖和2型糖尿病的发生率。

冷暴露无疑在通过BAT激活增加代谢率方面发挥最重要的作用。然而,在动物[104]和人类[105,106]中的研究表明,食物摄入也可增加全身能量消耗。这一过程称为饮食诱导的产热(DIT)。研究表明,某些类型的常量营养素可以以不同的方式改变能量消耗,表明蛋白质比脂肪和碳水化合物更显著地提高代谢率[107]。食物摄入,尤其是碳水化合物,会增加交感神经系统的活性[107]。饮食诱导的BAT产热的概念基于以下观察:在饮食诱导的肥胖中,SNS和BAT代谢活性增加伴随着比根据热量摄入预期更少的体重增加[108]。最近发表的结果显示,在102名年轻健康人中,BAT活性与体积与定量的随意能量摄入或从24小时饮食回忆估计的习惯性能量摄入之间没有关联[109]。

实验研究的数据表明,一些膳食补充剂可通过BAT引起的热效应增加代谢率;其中一种补充剂是从辣椒中提取的辣椒素。该补充剂增强了产热,并伴随着动物[110]和人类[111,112]体脂的减少。辣椒素通过脂肪组织上的瞬时受体电位香草酸亚型1(TRPV1)受体起作用,在前脂肪细胞中诱导棕色表型[113]。它还通过激活胃肠道TRPV1受体增加BAT的中枢交感神经刺激[114]。辣椒素类物质(辣椒素的非刺激性营养素)也发挥类似的热效应。辣椒素类物质仅在BAT阳性受试者中(而非BAT阴性受试者中)急性改变静息能量消耗[115]。最近,其他膳食营养素,如多不饱和脂肪酸(PUFAs),已被确定可诱导BAT激活。在动物模型中,富含PUFAs的高脂饮食影响了棕色脂肪组织中UCP1 mRNA的表达[116]。另外两项研究的结果表明,补充omega n-3长链多不饱和脂肪酸通过激活棕色脂肪组织增强了产热[117,118]。此外,富含多不饱和脂肪酸的母体饮食与动物中更大的肩胛间棕色脂肪组织库相关[119,120]。棕色和白色脂肪库的正确数量取决于妊娠期间的母体饮食,并可能负责儿童日后肥胖、胰岛素抵抗和T2D的发展[121]。

### 2.5. 棕色和棕色脂肪细胞

经典BAT库通常见于动物的肩胛间、颈部、主动脉周围、肾周围、肋间和纵隔区域[122]。在人体中通过PET/CT检测到的棕色脂肪细胞,通常在锁骨上、颈部、椎旁和肾上腺上部位[2],指的是称为brite(从棕色到白色)[123]、米色[124]或可招募[125]细胞的棕色样脂肪细胞,而非经典棕色脂肪(表1)。

**表1.** BAT、米色(brite)和WAT在解剖学、细胞学和分子学差异及其在肥胖和其他人类疾病中的参与总结。

| | 经典棕色脂肪细胞 | 米色(Brite)脂肪细胞 | 白色脂肪细胞 | |---|---|---|---| | **解剖学差异** | 主要在肩胛间区域 | 散布在颈部、锁骨上和椎旁区域的白色脂肪组织中 | 皮下区域、腹腔内区域,其他部位:眶后、骨髓、心包 | | **细胞学差异** | 多房室组织学,细胞核居中,大量大线粒体丰富,密集血管化和交感神经系统支配 | 脂滴大小和线粒体含量介于经典棕色和白色脂肪细胞之间。棕色脂肪细胞具有多个脂滴和比白色脂肪细胞更多的线粒体 | 单房室形态,三酰甘油储存在细胞内的一个大脂滴中 | | **分子差异** | UCP1依赖性、PPARγ、PGC1α、PRDM16 | UCP1依赖性、PPARγ | — | | **人体临床结果** | 代谢率增加、体重减轻、胰岛素敏感性增加 | 代谢率增加、体重减轻、胰岛素敏感性增加 | 能量储存、肥胖、2型糖尿病 |

在成人中,棕色样脂肪细胞与典型棕色脂肪细胞一起散布在锁骨上区域的白色脂肪细胞中[51],并在特殊条件下被激活,如暴露于寒冷、交感神经激动剂、辣椒素或鸢尾素。人体中BAT的估计质量在50-70克范围内[126],少量即可显著增加能量消耗。因此,科学兴趣集中在如何增加当前BAT的数量并显著增强其活性。

经典棕色脂肪细胞起源于肌源性因子5阳性(Myf5+)祖细胞,类似于骨骼肌细胞[127]。相比之下,棕色脂肪细胞被显示源自Myf5阴性(Myf5-)祖细胞,很像白色脂肪细胞[15]。它们的形态(脂滴大小和线粒体含量)介于经典棕色和白色脂肪细胞之间。棕色脂肪细胞具有多个脂滴(尽管通常比棕色脂肪细胞中看到的更大),比白色脂肪细胞更多的线粒体,以及UCP1的表达[128,129](图1)。经典和棕色脂肪细胞在发育起源上不同,但两者似乎都促进产热[130]。启动棕色脂肪细胞形成的方法如下:适应严重/轻度寒冷温度[131]、β-肾上腺素能激动剂治疗[132]、PPARγ增加、饮食和运动。刺激人体棕色脂肪细胞形成可能是改善葡萄糖稳态和对抗肥胖的另一种策略。

显著参与棕色和白色脂肪细胞脂肪生成的分子因子是PPARγ和CCAAT-增强子结合蛋白(C/EBP)[133]。这些转录因子负责脂肪生成分化,PPARγ和C/EBP的损害会减少BAT募集[134]。PPARγ对脂肪细胞分化和脂质储存是必需的,并具有抗糖尿病作用。PPARγ与其受体结合后,C/EBP等基因的表达增加。这种异二聚体与含PR结构域蛋白16(PRDM16)结合并刺激棕色脂肪细胞的分化[135]。随后,PPARγ激活其共激活因子1α(PGC-1α),增强UCP1表达[136]。PGC-1α是棕色脂肪细胞中PPARγ的共激活因子;PGC-1α还调节能量平衡并介导棕色脂肪细胞分化[137]。PGC-1α的主要作用是增强UCP1、呼吸链蛋白、克雷布斯循环蛋白和FA氧化酶的表达[138]。在棕色脂肪细胞分化中似乎发挥最突出作用的是PRDM16,它直接干扰PGC-1α,刺激PGC-1α与PPARγ之间的相互作用。这种蛋白促进白色前脂肪细胞向棕色脂肪细胞的转换[139]。棕色前脂肪细胞降低PRDM16的表达,导致分化为骨骼肌细胞[140]。BAT发育中的另一个重要参与者是骨形态发生蛋白(BMPs)。在BMP家族成员中,BMP7是BAT的特征,并增强所有早期BAT调节因子的表达,如PRDM16、PGC-1α、UCP1、PPARγ和C/EBP。BMP7敲除动物模型显示UCP1耗竭但WAT分化保留。相反,在这些小鼠中施用外源性BMP7促进BAT而非WAT发育,能量消耗持续增加且无体重增加[141]。据报道,BMP-7还可诱导WAT褐变并改善胰岛素敏感性[126]。BAT激活的其他介质对葡萄糖耐量和胰岛素敏感性有有益作用,包括成纤维细胞生长因子21(FGF-21)和白细胞介素-6(IL-6)。在动物中,冷暴露后,FGF21表达在肝脏(产生部位)中降低,但在棕色和白色脂肪组织中增强,其中FGF21增强UCP1表达和皮下组织的褐变[142]。这些发现在人体中得到证实,暴露于降低的温度会增加血浆FGF21的昼夜水平,显示与脂肪分解和寒冷诱导的产热呈正相关[143]。PPARγ转录控制FGF21,然后FGF21作为自分泌或旁分泌介质起作用以增加PPARγ转录活性[144]。FGF21通过增加UCP1表达似乎改善葡萄糖代谢。这些发现在肥胖动物的实验研究结果中得到支持,其中注射FGF21减少肥胖,改善血糖控制,并增加能量消耗[145]。白细胞介素-6(IL-6)是一种主要与胰岛素抵抗和2型糖尿病相关的促炎细胞因子,在BAT激活中发挥有趣的作用[146]。在肥胖中,IL-6通常由内脏而非皮下脂肪细胞分泌[147]。值得注意的是,在冷条件下评估BAT活性的研究中,观察到IL-6分泌显著增加[148]。此外,IL-6的施用被显示可减轻体重增加和内脏肥胖而不影响食物摄入。此外,在同一研究中,IL-6通过刺激交感神经系统增强BAT中UCP1表达[149]。这是通过信号转导子和转录激活子3的磷酸化(pSTAT3)介导的。进一步证实IL-6与棕色脂肪细胞关联的一项研究表明,BAT移植导致心脏中棕色和白色脂肪细胞以及骨骼肌中胰岛素刺激的葡萄糖摄取增加。此外,当用于移植的BAT来自IL-6敲除小鼠时,这种有益的代谢特征降低,表明BAT来源的IL-6是实现BAT移植对葡萄糖稳态和胰岛素敏感性显著效果所必需的[82]。有趣的是,IL-6是一种已知由骨骼肌在运动响应中分泌的细胞因子,从而增加其胰岛素增敏作用[150]。

骨骼肌在体力活动期间是另一种名为鸢尾素的蛋白质的来源,该蛋白质对小鼠白色脂肪细胞具有显著的褐变作用。鸢尾素是从运动肌肉释放的纤连蛋白III型结构域含蛋白5(FNDC5)切割的肌因子。在动物模型中,运动期间鸢尾素增加或外源性施用不仅导致WAT褐变增加,还显著减轻体重并改善葡萄糖耐量[151]。动物研究的结果表明,鸢尾素可通过白色脂肪细胞的褐变在运动期间发挥积极的代谢作用。还进行了多项研究来评估鸢尾素在人体中的作用。其中一些研究证实了运动后血浆鸢尾素水平的急性增加[152-155],而其他研究则没有[156,157]。此外,评估不同类型训练对鸢尾素水平影响的介入研究结果不一致。只有一项研究显示10周耐力训练后鸢尾素水平增加[151],而在12周综合耐力和力量训练后,鸢尾素水平与体力活动之间没有正相关[155]。此外,在有氧耐力和力量耐力方案的长期训练后,对鸢尾素浓度没有观察到影响[153,157,158]。用鸢尾素处理的人脂肪细胞的实验研究显示,UCP1 mRNA表达增加主要在经典棕色脂肪细胞中,而非白色脂肪细胞[156]。鸢尾素(由FNDC5编码)可通过诱导褐变增加人体能量消耗。此外,注意到人类肌肉活检和脂肪组织中的FNDC5基因表达与循环鸢尾素水平与肥胖、胰岛素敏感性和T2D相关。这些结果表明,循环鸢尾素可诱导人脂肪组织褐变,导致BAT功能和能力改善以及脂肪组织中FNDC5基因表达增强。此外,先前的一项研究观察到肥胖和T2D受试者脂肪组织和肌肉中循环鸢尾素浓度和FNDC5基因表达降低,表明棕色脂肪样特征的丧失[159]。因此,鸢尾素在人体中在BAT激活和葡萄糖稳态方面的作用应进一步研究。

## 3. 结论与未来展望

活化的棕色脂肪组织的功能不仅促进负能量平衡,还能减轻胰岛素抵抗、血脂异常和葡萄糖稳态紊乱等代谢并发症。关于如何维持和激活足够数量的棕色脂肪细胞以发挥抗2型糖尿病作用仍存在争议。因此,未来的研究将涉及寻找新的BAT激活剂。

目前,研究最充分的BAT激活剂是冷暴露和交感神经系统激动剂。就BAT激活产生的代谢益处而言,最重要的未来前景是研究阐明BAT激活以及WAT褐变的新的分子和环境因素。在肥胖个体中重新激活和募集BAT尤为重要,因为这些个体将获得最大的益处。识别在冷暴露条件下仍有效的BAT激活剂仍然具有挑战性。此外,饮食和营养素的作用值得探索以寻找BAT激活的新方法。迄今为止,已经表明通过一些食物成分(如辣椒素类物质和绿茶中发现的儿茶素)刺激瞬时受体电位通道通过激活和获得新的棕色脂肪细胞发挥抗肥胖作用。未来研究的另一个主要目标是鉴定棕色脂肪因子或batokines,它们可能成为治疗肥胖或代谢疾病的药物开发候选物。

由于使用18FDG PET测量的BAT体积较小,BAT对能量消耗的影响被低估了。准确测量BAT体积是一个主要限制,尤其是在肥胖和T2D个体中。需要开发新的成像方法来精确量化BAT体积和活性,以评估靶向BAT产热预防或治疗代谢疾病的真正潜力。

**作者贡献:** 概念化,K.M.;初稿准备,K.M.;审稿过程,K.M.;审稿、编辑最终稿件、监督,A.K。所有作者都已阅读并同意手稿的发表版本。

**资金:** 本研究未获得外部资金。

**利益冲突:** 作者声明无利益冲突。

**缩写词:**

BAT — 棕色脂肪组织 WAT — 白色脂肪组织 UCP1 — 解偶联蛋白1 TG — 甘油三酯 EE — 能量消耗 CIT — 寒冷诱导的产热 DIT — 饮食诱导的产热 VAT — 内脏脂肪组织 SAT — 皮下脂肪组织 PPARγ — 过氧化物酶体增殖物激活受体γ