Chronic noncommunicable diseases (CNCDs), which include cardiovascular disease, some cancers, for example, colon cancer, breast cancer, and type 2 diabetes, are reaching epidemic proportions worldwide. It has now become clear that low-grade chronic inflammation is a key player in the pathogenesis of most CNCDs. Given that regular exercise offers protection against all causes of mortality, primarily by protection against atherosclerosis and insulin resistance, we suggest that exercise may exert some of its beneficial health effects by inducing anti-inflammatory actions. Recently, IL-6 was introduced as the first myokine, defined as a cytokine, which is produced and released by contracting skeletal muscle fibres, exerting its effects in other organs of the body. We suggest that skeletal muscle is an endocrine organ and that myokines may be involved in mediating the beneficial effects against CNCDs associated with low-grade inflammation.
1. Introduction
Chronic noncommunicable diseases (CNCDs) which include cardiovascular
conditions (mainly heart diseases and stroke), some cancers, chronic respiratory conditions, and type 2
diabetes, affect people of all nationalities and classes and are reaching
epidemic proportions worldwide [1–4].
CNCDs cause the greatest global share of death and
disability, accounting for around 60% of all deaths worldwide. Approximately,
80% of chronic-disease deaths occur in low- and middle-income countries and
account for 44% of premature deaths worldwide. It is estimated that the number
of deaths from these diseases is double the number of deaths that result from a
combination of infectious diseases (including HIV/AIDS, tuberculosis, and
malaria), maternal and perinatal conditions, and nutritional deficiencies [1].
From a historical perspective,
inflammation has been considered as the natural host response to an acute
infectious episode, whereas chronic inflammation has been considered a sign of
chronic infection. It has now become clear that low-grade chronic inflammation
is a key player in the pathogenesis of most NCDCs. There has been an increasing appreciation of
the role of inflammation both in the pathogenesis of atherosclerosis [5, 6] and as a key factor
in insulin resistance [7]. Low-grade chronic
inflammation is characterized by increased systemic levels of some cytokines
and C-reactive protein (CRP) and a number of studies have confirmed an
association between low-grade systemic inflammation on one hand and
atherosclerosis and type 2 diabetes on the other [8].
Physical inactivity has been identified
as a stronger predictor of these chronic
diseases than risk factors such as hypertension, hyperlipidemia, diabetes, and
obesity for all-cause mortality [9]. Moreover, regular
physical activity appears to protect against premature death independent
of obesity [10, 11].
Regular physical activity offers protection against,
and may be useful as a treatment for a wide variety of, chronic diseases
associated with low-grade inflammation [12]. The protective effects of
regular exercise against diseases such as cardiovascular disease, type 2
diabetes, colon cancer, and breast cancer have been reviewed extensively [13–16].
Recent findings demonstrate that physical activity
induces an increase in the systemic levels of a number of cytokines with
anti-inflammatory properties [8, 17] and skeletal muscle has
recently been identified as an endocrine organ, which produces and releases
cytokines (also called myokines) [18, 19].
The discovery of contracting muscle as a
cytokine-producing organ opens a new paradigm; skeletal muscle is an endocrine
organ that, by contraction, stimulates the production and release of myokines,
which may influence metabolism and modify cytokine production in tissue and
organs.
2. Chronic Low-Grade Systemic Inflammation and Its Consequences
In response to
an acute infection or trauma, the cytokines and cytokines inhibitors will increase [20]. The initial cytokines as they appear in the
circulation in relation to an acute infection consist of the following: TNF-α,
IL-1β, IL-6, IL-1 receptor antagonist (IL-1ra), and soluble TNF-α-receptors
(sTNF-R), and IL-10. The systemic
response known as the acute-phase response includes the production of a large
number of hepatocyte-derived acute phase proteins, such as C-reactive protein
(CRP) that is known to be a sensitive marker of systemic inflammation. The
response can be mimicked by the injection of the cytokines TNF-α, IL-1β, and
IL-6 into laboratory animals or humans [8, 21]. Chronic low-grade systemic
inflammation has been characterized by a 2- to 3-fold elevation in the systemic
concentrations of proinflammatory and anti-inflammatory cytokines, natural
occurring cytokine antagonists, and the acute phase reactant C-reactive protein
(CRP) [13, 22]. In the latter case, the stimuli for
the cytokine production are not known, but it is assumed that the origin of TNF
in chronic low-grade systemic inflammation is mainly the adipose tissue [23–26].
Type 2 diabetes, obesity, and cardiovascular
disease are related to a state of low-grade systemic inflammation [7, 27–29]. Despite the fact that the changes
in acute-phase reactants are much smaller than those in acute infections, the
chronicity of low-grade inflammation is strongly associated with increasing
age, lifestyle factors such as smoking and obesity, together with increased
risk of cardiovascular disease and type 2 diabetes [22, 25, 30]. Plasma concentrations of
IL-6 [31] and TNF-α have been shown to
predict the risk of myocardial infarction in several studies [32], and CRP has emerged as a
particularly stronger independent risk factor for cardiovascular disease than
the low-density lipoprotein cholesterol level [13, 33, 34].
3. The Direct Metabolic Roles of TNF
Growing evidence suggests that TNF-α plays a direct
role in metabolic syndrome, via direct effect of TNF-α on insulin signaling [35, 36]. Patients with diabetes demonstrate high expression of TNF-α in
skeletal muscle and in plasma, and it is likely that adipose tissue, which
produces TNF-α, is the main source of the circulating TNF-α [37–39].
Thus, a
number of studies indicate that elevated TNF-α is not secondary to the
pathological conditions associated with insulin resistance, but that TNF-α
plays a direct pathogenic role in glucose metabolism [29, 40]. After
adjustment for multiple confounders, including IL-6, high plasma TNF
concentrations are associated with insulin resistance [40].
In cultured cells, TNF-α
induces insulin resistance through increased serine phosphorylationof insulin receptor substrate-1 (IRS-1), which subsequently converts
IRS-1 to an inhibitor of insulin receptor tyrosinekinase activity [41].
TNF-α has been shown to have a direct (insulin-independent) effecton S6K
and ERK-1/2 in cultured cells [42, 43].
In
addition, evidence for a direct role of TNF-α in insulin resistance in
humans in vivo has been obtained [44]. When TNF-α was
infused into healthy humans, we found that TNF-α induces insulin resistance in
skeletal muscle, without an effect on endogenous glucose production. TNF-α
directly impaired glucose uptake and metabolism by altering insulin signal
transduction. TNF-alpha infusion increased phosphorylation of p70 S6 kinase,
extracellular signal-regulated kinase-1/2, and c-Jun NH(2)-terminal kinase,
concomitant with increased serine and reduced tyrosine phosphorylation of
insulin receptor substrate-1. These signalling effects were associated with
impaired phosphorylation of Akt substrate 160, the most proximal step identified
in the canonical insulin signalling cascade regulating GLUT4 translocation and
glucose uptake. Thus, excessive concentrations of TNF-alpha negatively regulate
insulin signalling and whole-body glucose uptake in humans.
Moreover, it was recently
demonstrated that TNF-alpha infusion increases whole-body lipolysis by 40% with a concomitant
increase in FFA clearance, but with no changes in skeletal muscle FFA uptake,
release, or oxidation [45].
The
findings with regard to an effect of TNF on both glucoseand fat metabolism
provide a direct molecular link between low-grade systemic inflammation and the
metabolic syndrome [44, 45].
4. The Direct Metabolic Roles of IL-6
With regard to IL-6, its role in insulin resistance
is highly controversial. In humans, circulating IL-6 levels may [46] or may not [47] be associated with
insulin resistance.
Infusion of recombinant human (rh) IL-6 into resting
healthy humans does not impair whole body, lower limb, or subcutaneous adipose
tissue glucose uptake or endogenous glucose production [48, 49]. When diabetes patients were given an rhIL-6
infusion, plasma concentrations of insulin decreased to levels comparable with
that in age and BMI (body mass index)-matched healthy controls, indicating that
the IL-6 enhanced insulin sensitivity [50].
In
vitro studies demonstrate that IL-6 can induce insulin resistance in
isolated 3T3-L1 adipocytes [51, 52] and in mice [53]. However, the IL-6 dose applied in the latter
studies was supraphysiological, and is therefore probably not relevant to human
physiology. Interestingly, IL-6 knockout mice develop impaired glucose
tolerance that is reverted by IL-6. Thus, accumulating data suggest that IL-6
enhances glucose uptake in myocytes [54–57].
A number of studies indicate that
IL-6 enhances lipolysis, as well as fat oxidation [50, 58].
Consistent with this idea, Wallenius et al. 2002 demonstrated that IL-6
deficient mice developed mature-onset obesity and insulin resistance. In
addition, when the mice were treated with IL-6, there was a significant
decrease in body fat mass in the IL-6 knockout but not in the wild-type mice.
Recently, we demonstrated that IL-6 increased the glucose infusion rate [56] and glucose oxidation without
affecting the suppression of endogenous glucose production during a
hyperinsulinemic euglycemic clamp in healthy humans. Infusion of rhIL-6 into
healthy humans to obtain physiological concentrations of IL-6 increased
lipolysis in the absence of hypertriacylglyceridemia or changes in
catecholamines, glucagon, insulin, or any adverse effects in healthy individuals as well as patients with type 2 diabetes [49, 50, 58]. These findings, together with cell
culture experiments demonstrating that IL-6 alone markedly increases both
lipolysis and fat oxidation, identify IL-6 as a novel lipolytic factor.
Taken together, it is apparent that
in vivo studies in humans provide little or no evidence that IL-6 is a direct
player in the metabolic syndrome.
5. TNF/IL-6-Interaction
Of note, whereas it is known that
both TNF-α and IL-6 induce lipolysis [40, 49], only IL-6 appears to induce fat
oxidation [19, 59].
Given the different biological profiles of TNF-α and IL-6, and given that TNF-α
can trigger IL-6 release, one theory holds that it is the adipose
tissue-derived TNF-α that actually is the “driver” behind the metabolic
syndrome [36] and that locally produced TNF-α
causes increased systemic levels of IL-6.
6. Cytokine Responses to Exercise
Though
an acute bout of physical activity is accompanied by responses that in many
respects are similar to those induced by infection and sepsis, there are some
important differences in the cytokine response to exercise from that elicited
by severe infection [27, 60, 61].
The striking difference between exercise and sepsis with regard to cytokine
responses is that the classical proinflammatory cytokines, TNF-α and IL-1β, in
general do not increase with exercise.
Typically,
IL-6 is the first cytokine present in the circulation during exercise, and the
appearance of IL-6 in the circulation is by far the most marked and its
appearance precedes that of the other cytokines. The level of circulating IL-6
increases in an exponential fashion (up to 100 fold) in response to exercise,
and declines in the postexercise period [60–62].
Taken
together, exercise provokes an increase primarily in IL-6, followed by an
increase in IL-1ra and IL-10. The IL-6 response to exercise has recently been
reviewed [13, 18, 60, 63]. A marked increase in circulating
levels of IL-6 after exercise without muscle damage has been a remarkably
consistent finding. The magnitude by which plasma IL-6 increases is related to
exercise duration, intensity, and muscle mass involved in the mechanical work [13, 18, 60, 62].
7. Anti-Inflammatory Effects of IL-6
Interleukin-6 is most often
classified as a proinflammatory cytokine, although data also suggest that IL-6
and IL-6-regulated acute phase proteins are anti-inflammatory and
immunosuppressive, and may negatively regulate the acute-phase response [20].
A
number of studies have demonstrated that working muscle produces IL-6. Thus
muscle biopsies obtained before and after exercise in humans and rats
demonstrate very little IL-6 mRNA in resting muscle, but up to a 100-fold
increase in exercising skeletal muscle [18, 64, 65]. In addition, it has been demonstrated
that the IL-6 protein is expressed in contracting muscle fibres and that IL-6
is released from skeletal muscle during exercise [28]. Data
suggest that IL-6 exerts inhibitory effects on TNF-α and IL-1 production. IL-6
inhibits lipopolysaccharide (LPS)-induced TNF-α production both in cultured
human monocytes and in the human monocytic line U937 [66], and levels of TNF-α are markedly
elevated in anti-IL-6-treated mice and in IL-6-deficient knockout mice [67, 68],
indicating that circulating IL-6 is involved in the regulation of TNF-α levels.
In addition, rhIL-6 infusion inhibits the endotoxin-induced increase in
circulating levels of TNF-α in healthy humans [69]. Furthermore, IL-6 stimulates the
release of soluble TNF-α receptors, but not IL-1β and TNF-α, and appears to be
the primary inducer of the hepatocyte-derived acute-phase proteins, many of
which have anti-inflammatory properties.
The exercise-induced increase in
plasma IL-6 levels is followed by increased circulating levels of well-known
anti-inflammatory cytokines such as IL-1ra and IL-10 [28, 48].
It has been suggested that IL-6
promotes insulin resistance due to the observation that plasma IL-6 is often
elevated in patients with metabolic disease [70].
From a simplistic physiological
point of view, it seems paradoxical that working muscle would release a factor
that inhibits insulin signalling when insulin sensitivity is enhanced in the
immediate postexercise period [28].
8. Anti-Inflammatory Effects of Exercise
A number of studies suggest that
regular exercise has anti-inflammatory effects. Cross-sectional studies
demonstrate an association between physical inactivity and low-grade systemic
inflammation in healthy subjects [71–75], in
elderly people [76, 77],
and in patients with intermittent claudication [78].
Moreover, the finding in longitudinal studies that regular training induces a
reduction in CRP level suggests that the physical activity as such may suppress
systemic low-grade inflammation [74, 75, 79, 80].
To study whether acute exercise
induces a true anti-inflammatory response, a model of “low-grade inflammation"
was established in which we injected a low dose of Escherichia coli endotoxin to healthy volunteers, who had been
randomized to either rest or exercise prior to endotoxin administration. In
resting subjects, endotoxin induced a 2- to 3-fold increase in circulating
levels of TNF-α. In contrast, when the subjects performed 3 hours of ergometer
cycling and received the endotoxin bolus at 2.5 hours, the TNF-α response was totally blunted. Moreover, the effect of
exercise could be mimicked by infusion of IL-6, suggesting that IL-6 may be
involved in mediating the anti-inflammatory effects of exercise [69].
9. Conclusion
Regular exercise protects
against diseases associated with chronic low-grade systemic inflammation. Muscle
contraction-induced factors, so-called myokines, may be involved in mediating
the health beneficial effects of exercise and play important roles in the
protection against CNCDs, which include
cardiovascular conditions, some cancers, and type 2 diabetes. In particular, the long-term effect of exercise may to some extent be
ascribed to the anti-inflammatory response elicited by an acute bout of
exercise, which is partly mediated by muscle-derived IL-6 [8, 20, 81]. The possibility exists that, with regular exercise, the
anti-inflammatory effects of an acute bout of exercise will protect
against chronicsystemic low-grade inflammation and thereby offer
protection against insulin resistance and the development of atherosclerosis,
but such a link between the acute effects of exercise and the
long-term benefits has not yet been proven. Given that the
atherosclerotic process is characterized by inflammation, one alternative
explanation would be that regular exercise, which offers protection
against atherosclerosis, indirectly offers protection against
vascular inflammation and hence systemic low-grade inflammation.
Acknowledgments
The Centre of Inflammation and Metabolism
(CIM) is supported by a grant from the Danish National Research Foundation (no. 02-512-55). The authors’ research was further supported
by the Danish Medical Research Council and the Commission of the European
Communities (Contract no. LSHM-CT-2004-005272 EXGENESIS). The Copenhagen Muscle
Research Centre is supported by grants from the Capital Region of Denmark and
the University of Copenhagen.
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K.bkp@rh.dkThe role of IL-6 in mediating the anti-inflammatory effects of exercise200657supplement 104351