Regular exercise can reduce the risks for developing obesity [1] and the metabolic complications and disease associated with obesity, including non-alcoholic fatty liver disease (NAFLD) [2] and type 2 diabetes [3]. Exercise has these powerful effects on metabolism, not only because of its well-known effects on skeletal muscle metabolism, but also as a result of the metabolic adaptations it confers in multiple other tissues. Herein we provide an overview of the evidence that exercise is a powerful tool for the prevention of metabolic disease and that it exerts its protective effects by improving the metabolic phenotype of non-skeletal-muscle tissues, including the liver, vasculature, adipose tissue and pancreas. We also highlight that these multi-tissue adaptations occur not only through exercise activating intrinsic signalling events in each tissue but also through the unique, exercise-induced integration of inter-tissue communication by a variety of signalling molecules, hormones, cytokines, changes in substrate flux and blood flow. Rather than drilling down on specific mechanisms of action, this perspective provides a broad overview. We also seek to leverage this evidence to suggest that a certain minimum volume of exercise or physical activity is required for normal metabolic function.

Overview of metabolic disease pathology

Insulin resistance, the inability of insulin to effectively stimulate glucose uptake into metabolic tissues (skeletal muscle, adipose and liver), turn off hepatic glucose production and reduce adipose lipolysis, is a primary event underlying type 2 diabetes. Insulin resistance not only contributes to hyperglycaemia in type 2 diabetes but also putatively plays a role in the inappropriate excess storage of fat (ectopic) in the liver (hepatic steatosis) [4]. In turn, higher levels of ectopic storage of lipids in muscle and the liver is also associated with insulin resistance. Causality between hepatic steatosis, intramuscular lipid storage and insulin resistance remains controversial, but evidence clearly shows that insulin resistance is often associated with greater ectopic fat storage [5]. For reasons not understood, the liver becomes selectively insulin resistant in controlling glucose output but remains highly sensitive to the lipogenic effects of insulin [6]. Finally, insulin resistance also plays a fundamental role in reduced metabolic flexibility, which is defined as the capacity to switch between metabolic substrates depending on which is most readily available [7].

Inflammation, oxidative stress and endoplasmic reticulum stress have also been linked to metabolic dysfunction through both lipid- and non-lipid-mediated pathways (for an extensive review, see [8]). In general, these pathways are believed to impair molecular insulin signalling pathways in metabolic tissues, resulting in tissue-specific and systemic metabolic alterations that, when combined with chronic positive energy balance, can lead to NAFLD and type 2 diabetes. A prevailing view is that obesity precedes and causes insulin resistance, and this is followed by hyper insulin secretion by the pancreatic beta cells to compensate for impaired insulin signalling [9]. However, emerging evidence indicates that hyperinsulinaemia is likely to contribute to metabolic dysfunction and the development of obesity in a feed-forward manner [10]. This effect is witnessed in humans who transition from highly active to very inactive lifestyles for 1–2 weeks, and display elevated insulin responses paired with rapid gains in adiposity [11, 12].

Exercise and prevention of metabolic disease

Only recently has the biomedical scientific community fully recognised the powerful effects of exercise in the prevention and treatment of metabolic disease, even proving to be more beneficial than some low-performing pharmacological agents. Type 2 diabetes and NAFLD are two primary metabolic disease states with prevalence rates that are increasing at epidemic rates but can be prevented with regular exercise.

Prevention of type 2 diabetes

A daily threshold for a relatively small volume of physical activity (>3500 steps/day or >20 min/day) [13, 14] has been shown to be protective in reducing the transition of those with impaired glucose tolerance to frank type 2 diabetes. Overall, pooled results show that 150 min/week of moderate to vigorous physical activity will reduce the risk for type 2 diabetes by 30% [15]. More information on this effect has been reviewed previously [3]. Individuals who maintain a long-term habit of moderate volume but vigorous running have a significantly reduced risk for obesity and type 2 diabetes [16] and, in a more recent report, indices of volume, distance and intensity in leisure runners were all linearly associated with reduced risk for type 2 diabetes [17]. Furthermore, studies have repeatedly shown that a threshold of measured cardiorespiratory fitness (i.e. aerobic capacity or maximum oxygen consumption [\( \dot{V}{\mathrm{O}}_{2\max } \)]) of ~9–10 metabolic equivalents (METs) also lowers risk for transitioning to a diagnosis of type 2 diabetes [18].

Prevention of NAFLD

Excessive intrahepatic fat storage (hepatic steatosis), is the entryway to NAFLD, an umbrella condition that also encompasses steatohepatitis, fibrosis and cirrhosis. The development of hepatic steatosis also increases the risk for type 2 diabetes. Despite being an important target for the pharmacological industry, NAFLD currently has no treatment other than lifestyle interventions, including weight loss and exercise. Overall, there are far less data available on how exercise impacts NAFLD because it is a newer problem and because NAFLD can only be evaluated with invasive liver biopsies or with technologically advanced imaging methodologies. However, higher volumes of physical activity have been shown to reduce intrahepatic lipid levels [19]. Cardiorespiratory fitness, a measurable marker of regular exercise, has been shown to independently reduce the risk of NAFLD [20, 21], an effect that is independent of, or only moderately impacted by, obesity status [19].

Exercise also induces a large number of other positive effects, including improved weight management, improved bone density, reduced frequency and severity of cardiovascular disease and hypertension and of depression and anxiety, reduced risk for specific forms of cancer, reduced dementia, and improved strength, mobility and healthspan. In fact, increased risk for 35 chronic disease conditions have been independently linked to physical inactivity [22], leading us to speculate that daily physical activity and exercise may be required for normal health and function. Thus, our drive for technological advances and ease of daily living is working in opposition to our biology [22]. The excessive consumption of hyperenergetic, nutrient-poor diets further synergises with inactivity to drive epidemic rates of metabolic disease.

There is no doubt that skeletal muscle adaptations to exercise are important; however, physical exercise is not possible without the orchestrated cooperation of several tissues to support muscular work and maintain metabolic homoeostasis. Exercise training therefore results in adaptations to other tissues involved in these processes, including adipose tissue, liver, endothelium and pancreas.

Muscle-centric vs integrative view of the impact of exercise on metabolic health

In the following sections, we discuss the acute (Fig. 1) and chronic (Fig. 2) effects of exercise on each of the peripheral organs involved in the regulation of whole-body insulin sensitivity and metabolic health, and the associated systemic health effects. Unless otherwise specified, only data from human studies are presented. A growing body of work implicates hundreds or even thousands of proteins secreted by the main peripheral tissues (i.e. myokines by skeletal muscle [23], hepatokines by the liver [24] and adipokines by adipose tissue [25]) involved in the regulation of energy homeostasis and whole-body insulin sensitivity. However, only a few have been characterised and had their biological function demonstrated. During exercise, some of these proteins, collectively named ‘exerkines’, are secreted, and create a complex inter-organ network that contributes to the systemic metabolic health effects of exercise [26]. We also posit that ‘substrate flux’ between organs may work in concert with exerkines or independently to induce adaptations. Here we mention the molecular factors that have been recently identified and thought to potentially coordinate the inter-organ crosstalk in response to exercise (Fig. 3). Undoubtedly, numerous other signalling molecules will be identified in the years ahead, and future research will need to delineate the respective contribution of such molecules. In addition, because this area is still relatively new, controversies exist, and whether the findings from animals can be translated to humans is questionable.

Fig. 1
figure 1

Acute metabolic effects of exercise on the key peripheral organs involved in the regulation of energy homeostasis. In response to acute exercise, muscle immediately mobilises stored glucose then fatty acids and takes up glucose and fatty acids from plasma to match energy demand. During sustained exercise, adipose tissue and the liver mobilise NEFA and synthesise glucose, respectively, to keep providing fuel to muscle. In the meantime, cardiac output is increased and microvascular perfusion of peripheral tissues, capillary recruitment, muscle membrane permeability and transport of substrates is increased. These changes are associated with changes in substrate fluxes and secretion of glucagon and insulin by the pancreas. IMTG, intramuscular triacylglyerols; TG, triacylglycerols. This figure is available as part of a downloadable slideset

Fig. 2
figure 2

Chronic effects of exercise on key peripheral organs involved in the regulation of energy homeostasis and associated whole-body metabolic effects and systemic health effects. Exercise training improves \( \dot{V}{\mathrm{O}}_{2\max } \), decreases resting heart rate and blood pressure, and increases total muscle mass. Microvascular network is expanded and microvascular dilatory response is improved. Beta cell function is improved along with a greater blood glucose uptake by muscle, adipose tissue and liver, and peripheral tissue insulin sensitivity is ameliorated. Capacity for mobilisation of NEFA from adipose tissue is improved along with a greater capacity of liver for glucose production and decrease in de novo lipogenesis. Capacity for oxidising fat in liver and muscle in association with greater mitochondrial oxidative capacity and biogenesis is also increased. This results in reduced visceral adipose tissue depots and ectopic fat storage. Altogether these structural, functional and metabolic adaptations improve aerobic capacity, whole-body insulin sensitivity, glucose control, oxidative capacity and reduce triglycerolaemia and chronic inflammation. These changes reduce the risk of developing insulin resistance, type 2 diabetes, NAFL and CV diseases, the metabolic syndrome, obesity and, ultimately, early mortality. CV, cardiovascular; IMTG, intramuscular triacylglycerols; TG, triacylglycerols. This figure is available as part of a downloadable slideset

Fig. 3
figure 3

Inter-organ crosstalk and substrate fluxes during exercise. Based on recent data in animals and humans, the following cascade of events is hypothesised to occur during exercise. ATP turnover, glycogen depletion and/or muscle contraction trigger the secretion of myokines that will act in a paracrine way and act on skeletal muscle mass and metabolism including IL-6 and IL-15, apelin, musclin and BDNF or in an endocrine fashion on metabolism and function of liver (myonectin, IL-6), pancreas (IL-6), microvasculature (VEGF-B, NO) and adipose tissue (IL-6, FGF21, irisin, GDF15) or other tissues (SPARC and decorin). Pancreatic secretion of glucagon is increased and insulin is decreased, catecholamines are secreted by the sympathetic nervous system and ANP by the heart. These multiple actions concertedly contribute to activate skeletal muscle use of intramuscular fatty acid, fat oxidation, plasma glucose uptake and insulin sensitivity, stimulates adipose tissue NEFA mobilisation, and activates hepatic endogenous glucose production. Together these molecular factors are likely to contribute to the exercise health benefits, i.e. increase in muscle mass, reduced triacylglycerolaemia, improved insulin sensitivity and glucose control. Substrate fluxes are indicated by dotted red lines. ANGPTL4, angiopoietin-like 4; BDNF, brain-derived neurotrophic factor; FGF-21, fibroblast growth factor 21; GDF15, growth and differentiation factor 15; SNS, sympathetic nervous system; SPARC, secreted protein acidic and enriched in cysteine; TG, triacylglycerols; VEFG-B, vascular endothelial growth factor B. This figure is available as part of a downloadable slideset

Skeletal muscle adaptations

Skeletal muscle is the largest metabolic tissue in the human body and a critical site for glucose disposal both at rest and during exercise [27]. During exercise, skeletal muscle uses both muscle glycogen stores and circulating plasma glucose as sources of fuel. Muscle contractions, even at low intensity and low volume [28], activate both oxidative and non-oxidative glucose disposal and glucose uptake via insulin-dependent and -independent mechanisms [29], optimising insulin action and both glucose oxidation and storage. Continuation of regular exercise further augments skeletal muscle oxidative capacity, mitochondrial biogenesis [30] and mitochondrial quality control mechanisms (mitophagy, fission, fusion), although this has been less well examined [31, 32]. Endurance training promotes the trafficking of dietary fatty acids away from storage and towards oxidation via an increased capacity for myocyte fatty acid transport paired with increased fatty acid oxidation in mitochondria in both normal weight and overweight adults [33]. In addition, exercise training increases intramuscular triacylglycerol turnover and reduces lipid intermediate (diacylglycerols and ceramides) content [34]. Importantly, increased glucose utilisation by muscle during exercise would lead to hypoglycaemia if it was not paired with a rapid upregulation of hepatic glucose output. Thus, exercise also drives critical acute and chronic adaptations to hepatic metabolism.

As previously reviewed [26, 35], the skeletal muscle secretory response, including a constellation of myokines, extracellular vesicles and their cargo, and metabolites, has recently been implicated in exercise-mediated multisystemic adaptations that improve metabolic health. They can act in a paracrine/autocrine or endocrine manner. Although numerous molecular analytes have been detected, the functions of only a few are well established. For example, levels of brain-derived neurotrophic factor (BDNF), proteins belonging to the natriuretic peptide family (e.g. B-type natriuretic peptide [BNP]), musclin, IL-15, IL-6, apelin, secreted protein acidic and rich in cysteine (SPARC), fibroblast growth factor 21 (FGF-21), decorin, myonectin and irisin have been shown to increase in the circulation in response to exercise and these molecules are likely to play a role in the control of muscle mass and skeletal muscle metabolism in an autocrine fashion, as reviewed elsewhere [36, 37]. The effect of some of these molecular factors have been studied in rodents or in in vitro studies but have not been (fully) confirmed in human studies. Circulating levels of IL-6, the first myokine to be discovered [38], rapidly increase in response to an acute bout of exercise [39]. Its secretion seems to be influenced by the mechanical workload of the exercise [39], skeletal muscle glycogen content [40] and, potentially, glucose ingestion and/or plasma glucose levels [41]. IL-6 may therefore act as an energy sensor. In humans, exercise-released IL-6 stimulates the mobilisation of intramuscular triacylglycerol [42], fatty acid oxidation [42], translocation of GLUT4 from the cytosol to the membrane [43] and improves skeletal muscle insulin sensitivity [43].

Liver adaptations

During short bouts of activity and high-intensity exercise, muscles rely predominantly on intramuscular stores of glucose and fat. However, when exercise is sustained, a larger supply of substrates from outside the muscle is required [44]. The requirement of glucose uptake for the working muscle must be paired with increased rates of hepatic glucose output to maintain euglycaemia [44]. Exercise therefore increases hepato-splanchnic glucose flux, an effect that is not seen by sampling blood glucose, but, rather, requires tracer methodology to measure glucose turnover/flux. Exercise first increases the mobilisation of hepatic glycogen (the biggest glycogen store in the body) into plasma, and this is followed by increased rates of gluconeogenesis during longer exercise bouts [45]. To fuel these processes, exercise also increases the uptake of the gluconeogenic precursors (lactate, pyruvate, glycerol) [46]. Exercise-induced changes in gluconeogenesis are dependent on the rise in glucagon and the drop in insulin that occur during exercise [44]. During each bout, the exercise-induced decrease in insulin sensitises the liver to the effects of glucagon. Exercise training, in the absence of weight loss, improves the ability of insulin to suppress glucose production by the liver [45]. As in skeletal muscle, exercise stimulates a reduction in lipogenic processes and a simultaneous increase in lipid oxidation [47,48,49], which is likely to underlie the effects of habitual exercise in the prevention of NAFLD and maintenance of reduced intrahepatic lipid storage [19].

The liver faces other challenges during exercise, such as recycling metabolites, clearing toxic compounds, and buffering the by-products of lipid oxidation released by the muscle during exercise (e.g. medium-chain acylcarnitines) [45, 46]. The liver also produces ketones, which fuel neuronal tissues during exercise if there has been a prolonged period since the last meal [50]. Thus, via adaptive responses in glucose and fatty acid metabolism, a well-controlled crosstalk exists between the liver and muscles to exchange substrates and maintain metabolic homeostasis during exercise.

Changes in liver metabolism during exercise are regulated, at least in part, by exercise-released myokines. IL-6 enhances hepatic fat oxidation and glucose production during exercise [51]. Myonectin also improves systemic lipid metabolism. It does so by increasing liver fatty acid uptake through upregulation of fatty acid transporter genes, at least in rodents [52]. In addition, during and immediately after exercise, liver hepatokines are released, including FGF21, follastin and angiopoietin-like 4 (ANGPTL4), which are involved in the regulation of circulating triacylglycerol concentrations, skeletal muscle mass and strength, and metabolism in rodents and humans [45, 53].

Adipose tissue adaptations

Whole-body fat oxidation rates increase with prolonged exercise or physical activity, particularly in postabsorptive conditions. The energy demands of muscles and the liver are met by NEFA mobilisation from adipose tissues, the largest source of stored energy in the human body. Increased mobilisation of NEFA from adipose, paired with increased oxidation, permits sustained exercise by delaying hypoglycaemia [54]. Moreover, increased NEFA oxidation in the liver during exercise is necessary to fuel the high energy costs of gluconeogenesis. Storage and mobilisation of NEFA are under the control of insulin (lipogenic and anti-lipolytic hormone) and catecholamines (epinephrine and norepinephrine, lipolytic hormones) and the atrial natriuretic peptide (ANP, lipolytic factor) [55]. During exercise, levels of circulating catecholamines, via sympathetic nervous system activation, and ANP release by the heart are enhanced and the plasma insulin level is decreased [56]. The combined action of these factors induces lipolysis. Even low-intensity exercise is sufficient to increase adipose tissue NEFA mobilisation [57]. Exercise training improves the sensitivity of adrenergic receptors to catecholamines in adipose tissue [58], while also enhancing markers of mitochondrial biogenesis and function [59], blood flow and glucose uptake [60]. However, the improvements in adipose tissue metabolism and in blood flow in response to acute exercise are less pronounced in overweight and obese adults than in their lean healthy counterparts [61]. An acute bout of exercise also increases lipoprotein lipase (LPL) activity [62]. Although this may appear counterintuitive given that LPL stimulates fat storage in adipose tissue, it makes sense given the effect of an increase in systemic and muscle LPL activity [63] is the promotion of fat uptake by muscle. Importantly, because this latter effect is long lasting (12–18 h) after a single bout of activity [64], prior exercise reduces the net delivery of dietary fat to adipose tissue (arterial triacylglycerol) [64] and, potentially, fat storage. In line with this, exercise training leads to a modest reduction in adiposity even in the absence of weight loss [65]. Furthermore, it decreases two variables with negative metabolic health outcomes, namely, central adiposity (at least in men) [65] and fat cell size (at least when associated with energy deficit). Although some studies suggested a greater effect of exercise on visceral than subcutaneous adipose tissue mass, potentially because visceral adipose tissue mass is more responsive to adrenergic activation [66], meta-analysis and reviews failed to report a differential effect on fat depots [67]. The existence of an independent effect of regular exercise on visceral adipose tissue is currently debated. Finally, exercise in rodents has been shown to lower adipose inflammation, which tracks with improved whole-body insulin sensitivity [68]; however, data in humans suggest that exercise-induced changes in adipose inflammation are minimal unless paired with caloric restriction-induced weight loss [69]. In summary, adipose tissue adaptations to exercise together contribute to improved systemic metabolic homeostasis and improved exercise performance.

Muscle–adipose tissue crosstalk also exists. As reviewed elsewhere [26], skeletal muscle release of IL-6, FGF-21 and irisin increases in response to exercise and influences adipose tissue metabolism, oxidative capacity and glucose uptake. Following the depletion of glycogen stores, IL-6 is released by the contracting muscles during exercise. IL-6 may stimulate adipose tissue lipolysis and NEFA mobilisation during exercise, and plays a major role in the reduction of visceral adipose tissue in response to exercise training in humans [70]. However, other in vivo and in vitro studies are not as conclusive, and the role of IL-6 in adipose tissue biology is still under investigation. Similarly, the effects of muscle-released FGF-21 and irisin on adipose tissue in humans are either still unknown or under debate. A novel exerkine produced by skeletal muscle contraction has recently been identified that targets human adipose tissue to promote lipolysis, namely, growth and differentiation factor 15 (GDF15) [71]. In terms of adipose tissue, adipokines modulate inflammation, lipid and glucose metabolism, blood pressure and atherosclerosis [56]. Via its effect on fat mass, exercise can indirectly modulate levels of leptin and adiponectin, the two most well-studied adipokines, which are positively and negatively associated with fat mass, respectively. Although leptin and adiponectin have been associated with insulin sensitivity, the specific effect of exercise training on leptin and adiponectin is unclear [56]. Recently, TGF-β2 has been shown to be secreted from adipose tissue in response to exercise and play a role in glucose homeostasis in mice [72]. Results still need to be confirmed in humans.

Pancreas adaptations

Pancreatic glucagon and insulin orchestrate the regulation of blood glucose by facilitating glucose disposal in insulin-sensitive tissues and hepatic gluconeogenesis. Insulin secretion is primarily adjusted according to the amount of glucose taken up by beta cells. Insulin secretion during a glucose challenge is dramatically altered by exercise undertaken during the previous days and hours in both healthy individuals and in those with insulin resistance and type 2 diabetes [73]. Exercise cessation drives up insulin secretion, while one bout of exercise can lower insulin secretion, showing that insulin secretion is tightly regulated by exercise-driven pathways [74]. The pancreas contributes to the capacity of acute exercise to increase hepatic glucose production by reducing insulin secretion (hepatic insulin clearance is also likely to be important) and increasing glucagon secretion [44]. In adults with impaired glucose tolerance and type 2 diabetes, exercise improves peripheral sensitivity and pancreatic beta cell function (greater insulin secretion in response to circulating glucose) [75]. The combination of enhanced insulin sensitivity and improved beta cell function is defined as the disposition index, which is the product of insulin sensitivity multiplied by the amount of insulin secreted in response to blood glucose [76]. Unlike drug therapies for type 2 diabetes, which typically only influence one component of the index independently, exercise has the capacity to improve the disposition index by enhancing both components [77]. Emerging evidence shows that factors secreted from contracting skeletal muscle boost beta cell insulin secretion and that the improvements in glucose homeostasis in type 2 diabetes patients in response to chronic aerobic exercise may be more closely related to improved beta cell function than insulin sensitivity [78]. Although controversies still exist and mechanisms have not been fully elucidated as yet, crosstalk between skeletal muscle and pancreatic alpha and beta cells seems to exist via myokines. Two of the proteins that have been proposed to play a role in the muscle–pancreas crosstalk are muscle-released IL-6, because of its link with the protective effect of exercise against proinflammatory-induced beta cell loss [79], and the peroxisome proliferator-activated receptor γ coactivator 1α (PGC1α)-dependent myokine irisin (precursor protein fibronectin type III domain-containing protein 5 [FNDC5]), because of its protective effect against beta cell apoptosis induced by lipotoxic conditions [80]. Other unknown exercise-induced myokines may also play a role in modulating beta cell function. Further work in this area could highlight novel therapeutic targets for type 2 diabetes.

Endothelium and cardiovascular system adaptations

The skeletal muscle microvascular ensures that delivery of oxygen and substrates (NEFA, triacylglycerols-rich lipoproteins and glucose) matches the metabolic demands of the muscle fibres (and other metabolic tissues) under resting conditions and during exercise. The microvasculature of human skeletal muscles has a complex 3D structure and is subject to a large number of complementary blood-flow regulation mechanisms, but the exact cascade of events and regulatory processes remain unknown, especially in humans [81, 82]. Because of accessibility to tissues and the capacity to perform ex vivo preparations, rodents have served as an important model to explore the regulation of endothelial function and blood flow in the control of skeletal muscle metabolism.

Under resting conditions, insulin increases microvascular perfusion through both vasodilatory and vasoconstrictory activities. On the one hand, insulin acts on terminal arterioles and increases nutritive blood flow to skeletal muscle [83], which can also result in increased blood flow in upstream conduit arteries. On the other hand, data from rodents shows that insulin-mediated endothelin-1 (ET-1) [84] increases the vasoconstriction of arterioles that control access to the nutritive capillary beds of muscle, which receive little or no blood flow in the basal state. ET-1 in skeletal muscle arterioles is increased in individuals with obesity or type 2 diabetes compared with healthy control individuals [85]. In addition, there is evidence in humans [86] and rodents [87] that increasing insulin resistance is associated with reduced capillary density. Although the vascular effects of insulin seem to be markedly compromised in type 2 diabetes, exercise-mediated pathways are likely to be maintained [88].

During exercise, there are increases in cardiac output, via a rise in cardiac stroke and heart rate, and blood pressure. Acute exercise increases muscle insulin sensitivity by a coordinated increase in insulin-stimulated microvascular perfusion and molecular signalling that improves glucose delivery and increases muscle glucose uptake and disposal [89]. This insulin-stimulated increase in microvascular perfusion is likely to be linked to the exercise-mediated increases in muscle membrane permeability to glucose and muscle blood flow [90]. The increased haemodynamic forces, i.e. shear forces exerted by blood flow, are also translated by the glycocalyx layer (glycoproteins and proteoglycans) located on the luminal surface of endothelium into a vasodilatory response. This pulsatile flow-induced shear stress and release of nitric oxide induces a dynamic regulation of vascular tone via ET-1 synthesis/release [91], which could also potentiate the non-nutritive route of the blood flow. Vasodilation and additional microvascular units expand the endothelial surface area, thus enabling the delivery of nutrients to the muscle. Exercise training reduces resting blood pressure, heart rate and cardiac hypertrophy, improves the vasodilator response of the muscle microvasculature to insulin and exercise [88] and enlarges the microvascular network via angiogenesis and arteriogenesis [81]. These adaptations have been linked to a variety of changes in tissue metabolism and signalling, including the production and release of nitric oxide and prostacyclin from the vascular endothelium [82]. The finding that vascular endothelial growth factor B (VEGF-B) produced by skeletal muscle links endothelial NEFA uptake to the oxidative capacity of skeletal muscle by controlling the expression of fatty acid transporter proteins in the capillary endothelium represents a major recent discovery [92]. Regulation of the expression of these proteins may prevent lipotoxic NEFA accumulation, the dominant cause of insulin resistance in muscle fibres. The effects of exercise on endothelial adaptations and the underlying mechanisms continue to be explored and much is yet to be learnt, especially related to how adaptations occur in those with obesity or type 2 diabetes vs a non-diseased state [93, 94]. The ability of exercise to influence endothelial transport of insulin and glucose [44] and to mediate enhanced insulin-stimulated blood flow via both the nutritive and non-nutritive routes [88] is likely to be particularly important for the prevention of type 2 diabetes. Finally, emerging data from rodents indicate that exercise also positively impacts endothelial function and vascular biology in adipose depots [95] and is likely to play a role in other key organs, such as the brain, liver and pancreas.


Regular exercise and/or moderate to vigorous physical activity has a pronounced protective effect against metabolic disease. We posit that the multi-tissue adaptations induced by exercise underly its powerful disease-modifying impact. Detailed studies blocking individual effects in each tissue using reductionist approaches may be needed to provide greater mechanistic insight. That being said, because exercise activates so many pathways in so many tissues, it may be that target knockdown studies would not reveal that one metabolic pathway is essential, but, rather like the layers of an onion, multiple factors with built in redundancies contribute to the metabolic protection provided by regular exercise. Nevertheless, it is an exciting time to investigate and observe how exercise mediates metabolic benefits beyond the mechanisms found in skeletal muscle.