Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-22T16:35:53.515Z Has data issue: false hasContentIssue false

n-3 PUFA: bioavailability and modulation of adipose tissue function

Symposium on ‘Frontiers in adipose tissue biology’

Published online by Cambridge University Press:  24 August 2009

Jan Kopecky*
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Martin Rossmeisl
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Pavel Flachs
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Ondrej Kuda
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Petr Brauner
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Zuzana Jilkova
Affiliation:
Department of Adipose Tissue Biology, Institute of Physiology of the Academy of Sciences of the Czech Republic, Videnska 1083, 142 20 Prague, Czech Republic
Barbora Stankova
Affiliation:
Charles University in Prague, 1st Faculty of Medicine, 4th Department of Medicine, U Nemocnice 2, 128 08 Prague, Czech Republic
Eva Tvrzicka
Affiliation:
Charles University in Prague, 1st Faculty of Medicine, 4th Department of Medicine, U Nemocnice 2, 128 08 Prague, Czech Republic
Morten Bryhn
Affiliation:
Silentia AS, Svelvik, Norway
*
*Corresponding author: Professor Jan Kopecky, fax +420 241062599, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Adipose tissue has a key role in the development of metabolic syndrome (MS), which includes obesity, type 2 diabetes, dyslipidaemia, hypertension and other disorders. Systemic insulin resistance represents a major factor contributing to the development of MS in obesity. The resistance is precipitated by impaired adipose tissue glucose and lipid metabolism, linked to a low-grade inflammation of adipose tissue and secretion of pro-inflammatory adipokines. Development of MS could be delayed by lifestyle modifications, while both dietary and pharmacological interventions are required for the successful therapy of MS. The n-3 long-chain (LC) PUFA, EPA and DHA, which are abundant in marine fish, act as hypolipidaemic factors, reduce cardiac events and decrease the progression of atherosclerosis. Thus, n-3 LC PUFA represent healthy constituents of diets for patients with MS. In rodents n-3 LC PUFA prevent the development of obesity and impaired glucose tolerance. The effects of n-3 LC PUFA are mediated transcriptionally by AMP-activated protein kinase and by other mechanisms. n-3 LC PUFA activate a metabolic switch toward lipid catabolism and suppression of lipogenesis, i.e. in the liver, adipose tissue and small intestine. This metabolic switch improves dyslipidaemia and reduces ectopic deposition of lipids, resulting in improved insulin signalling. Despite a relatively low accumulation of n-3 LC PUFA in adipose tissue lipids, adipose tissue is specifically linked to the beneficial effects of n-3 LC PUFA, as indicated by (1) the prevention of adipose tissue hyperplasia and hypertrophy, (2) the induction of mitochondrial biogenesis in adipocytes, (3) the induction of adiponectin and (4) the amelioration of adipose tissue inflammation by n-3 LC PUFA.

Type
Research Article
Copyright
Copyright © The Authors 2009

Abbreviations:
ACC

acetyl-CoA carboxylase

ALA

α-linolenic acid

AMPK

AMP-activated protein kinase

cHF

maize oil-based high-fat

LC

long chain

MS

metabolic syndrome

Many studies indicate the key role of hypertrophic adipose tissue in the development of various morbidities in obese individuals, including type 2 diabetes, dyslipidaemia and hypertension, i.e. the major components of metabolic syndrome (MS). Insulin resistance, the central defect underlying the MS, most probably results from increased accumulation of lipids in the peripheral tissues (lipotoxicity) as a result of enhanced release of fatty acids from hypertrophic fat cells(Reference Kopelman1, Reference Kahn, Hull and Utzschneider2). In addition to other lifestyle interventions(Reference Tuomilehto, Lindstrom and Eriksson3, Reference Knowler, Barrett-Connor and Fowler4), adjustment of the quality of dietary lipids is also important for the prevention and treatment of MS. In particular, long-chain (LC) PUFA of the n-3 series, DHA (22: 6n-3) and EPA (20: 5n-3), which are abundant in marine fish, lower TAG while increasing HDL-cholesterol levels in plasma, prevent the development of heart disease and exert anti-inflammatory properties in human subjects(Reference Ruxton, Reed and Simpson5Reference Singer, Shapiro and Theilla7). Studies in rats and mice fed a high-fat or lipogenic sucrose-rich diet have shown that n-3 LC PUFA counteract the development of both obesity and insulin resistance(Reference Ikemoto, Takahashi and Tsunoda8Reference Kuda, Jelenik and Jilkova13). Also, in human subjects n-3 LC PUFA could reduce fat accumulation and improve glucose metabolism(Reference Mori, Bao and Burke14Reference Kunesova, Braunerova and Hlavaty16). Although n-3 LC PUFA appear to have little effect on glycaemic control in patients with type 2 diabetes, these fatty acids are considered to be healthy dietary constituents for this type of patients as a result of the beneficial effect on the plasma lipid profile(Reference MacLean, Konica and Morton17, Reference Nettleton and Katz18).

Animals and human subjects cannot synthesize PUFA, which contain double bonds at C-6 and C-3 from the methyl end of the molecule. Precursors for the synthesis of n-6 and n-3 LC PUFA are linoleic acid (18: 2 n-6) and α-linolenic acid (ALA; 18: 3 n-3) respectively. The conversion of ALA to EPA and DHA occurs primarily in the liver. Linoleic acid and ALA compete for the enzyme Δ6 desaturase, which is required for their further metabolism. Thus, an excessive amount of linoleic acid slows down the formation of EPA and DHA. Even without this inhibitory effect, the synthesis of EPA and DHA from ALA, the major proportion of which is rapidly oxidized, is quite inefficient. Thus, (1) supplementation of diets with n-3 LC PUFA results in a much higher increase in the plasma and tissue EPA and DHA content when compared with supplementation of the diet with ALA (for reviews, see Arterburn et al.(Reference Arterburn, Hall and Oken19) and Brenna et al.(Reference Brenna, Salem and Sinclair20)) and (2) the effects of n-3 LC PUFA also depend on dietary n-6 PUFA:n-3 PUFA, which was lower in the diet of ancient hunter–gatherers compared with that of modern humans and is still increasing in affluent societies(Reference Eaton, Eaton and Konner21, Reference Massiera, Saint-Marc and Seydoux22). EPA, DHA, ALA and arachidonic acid (20: 4n-6) are incorporated into cellular membranes through their binding to the sn-2 position in the phospholipid molecule. These fatty acids thus influence the fluidity of plasma membranes and the function of membrane proteins. Moreover, the competition for binding to phospholipids also affects the availability of n-3 LC PUFA as substrates for cyclooxygenases and lipoxygenases after their release by the action of phospholipases, as well as the formation of their active metabolites, eicosanoids and other lipid mediators(Reference Arterburn, Hall and Oken19, Reference Flachs, Rossmeisl and Bryhn23, Reference Gonzalez-Periz, Horrillo and Ferre24). In general, eicosanoids derived from n-3 LC PUFA have anti-inflammatory effects, while the equivalent eicosanoids derived from n-6 PUFA promote inflammation(Reference James, Gibson and Cleland25). Lipid mediators derived from EPA and DHA, resolvins and protectins, are potent locally-acting agents in processes of acute inflammation and its resolution. They possess anti-inflammatory effects, as well as providing protection against tissue damage(Reference Schwab, Chiang and Arita26).

The biological effects of n-3 LC PUFA and their metabolites are largely mediated by PPAR, with PPARα and PPARδ (-β) representing the main targets(Reference Sanderson, de Groot and Hooiveld27Reference Madsen, Petersen and Kristiansen29). However, PPARγ, liver X receptor-α, hepatic nuclear factor-4, sterol regulatory element-binding protein-1 and NF-κB(Reference Singer, Shapiro and Theilla7) are also involved(Reference Neschen, Morino and Dong30Reference Neschen, Morino and Rossbacher32). The hypolipidaemic and anti-obesity effects of n-3 LC PUFA probably depend on the in situ suppression of lipogenesis and increase in fatty acid oxidation in several tissues including liver, intestine, and adipose tissue(Reference Flachs, Horakova and Brauner12, Reference Jump31, Reference Teran-Garcia, Adamson and Yu33, Reference van Schothorst, Flachs and Franssen-van Hal34). This metabolic switch may reduce the accumulation of toxic fatty acid derivatives, while protecting the insulin signalling in liver and muscle(Reference Storlien, Kraegen and Chisholm9, Reference Kuda, Jelenik and Jilkova13, Reference Gonzalez-Periz, Horrillo and Ferre24, Reference Neschen, Morino and Dong30, Reference Jucker, Cline and Barucci35). Part of the metabolic effects of n-3 LC PUFA in the liver(Reference Suchankova, Tekle and Saha36), and possibly also in other tissues(Reference Gonzalez-Periz, Horrillo and Ferre24, Reference Gabler, Radcliffe and Spencer37) (also, see later), is mediated by the stimulation of AMP-activated protein kinase (AMPK), a metabolic sensor controlling intracellular metabolic fluxes, i.e. the partitioning between lipid oxidation and lipogenesis (for review, see Flachs et al.(Reference Flachs, Rossmeisl and Bryhn23) and Carling(Reference Carling38)). Thus, n-3 LC PUFA by multiple mechanisms of action modulate the functions of all major tissues involved in the development of MS, i.e. the liver, adipose tissue and skeletal muscle(Reference Flachs, Rossmeisl and Bryhn23).

The aim of the present report is to characterize adipose tissue as a target for n-3 LC PUFA in the prevention and treatment of pathological conditions associated with MS. Despite a relatively small increase in n-3 LC PUFA concentrations in adipose tissue lipids in response to dietary intake of these fatty acids, adipose tissue is specifically linked to the beneficial effects of n-3 LC PUFA on health. This relationship is indicated by (1) the prevention of adipose tissue hyperplasia and hypertrophy, (2) the induction of mitochondrial biogenesis in adipocytes, (3) the induction of adiponectin secretion and (4) the amelioration of adipose tissue inflammation by n-3 LC PUFA. The present report represents an extension of a review published recently(Reference Flachs, Rossmeisl and Bryhn23), as it contains new results relating to bioavailability (i.e. incorporation of EPA and DHA administered in the diet into plasma lipids) and tissue accumulation of n-3 LC PUFA, as well as describing the effects of n-3 LC PUFA on AMPK activity and low-grade inflammation of adipose tissue. All the experiments described in the present report were performed using adult male C57BL/6 mice fed a maize oil-based high-fat (cHF; approximately 35% (w/w) fat) diet, free of DHA and EPA and containing a low level of ALA (approximately 2–4% (w/w) of total fatty acids (Reference Ruzickova, Rossmeisl and Prazak11, Reference Kuda, Jelenik and Jilkova13)), which induces the MS phenotype in the mice within several weeks of feeding. The effects of n-3 LC PUFA were studied using a concentrate (w/w; approximately 46% DHA and 14% EPA; EPAX 1050 TG; EPAX AS, Aalesund, Norway) to replace 5, 15 or 44% (w/w) dietary fat in the cHF diet(Reference Ruzickova, Rossmeisl and Prazak11).

Bioavailability of n-3 long-chain PUFA and capacity of adipose tissue for n-3 long-chain PUFA storage

Despite the low rate of conversion of ALA to EPA and DHA, both animal and human studies indicate that (1) diets containing only ALA as a source of n-3 fatty acids support the formation of limited amounts of both EPA and DHA, resulting in a relatively low plasma and tissue content of these fatty acids and (2) increased supply of dietary ALA results in increases in ALA and EPA content in plasma and tissues, but has no effect on plasma DHA concentration(Reference Arterburn, Hall and Oken19, Reference Muoio and Newgard39). Dietary intake of fish oil or concentrates containing both EPA and DHA results in increased incorporation of both fatty acids into plasma lipids, a measure of the bioavailability of the administered compounds. In human subjects steady-state levels of n-3 LC PUFA in total plasma lipids are reached within approximately 1 month, while incorporation of n-3 LC PUFA into erythrocytes (and presumably tissues) exhibits slower kinetics(Reference Arterburn, Hall and Oken19, Reference Brenna, Salem and Sinclair20). The experiments with mice have investigated both the bioavailability (Fig. 1(A and B)) and the incorporation of EPA and DHA into total adipose tissue lipids (Fig. 1(C and D)), liver TAG (Fig. 1(E and F)) and phospholipid (Fig. 1(G and H)) fractions and brain phospholipids (Fig. 1(I and J)). In mice fed cHF at the 5 or 15% (w/w) level of substitution for 9 weeks both the DHA and EPA contents of plasma and tissue lipids are increased in response to increasing doses of n-3 LC PUFA in the diets. Plasma fatty acid levels remain similar between 2 and 9 weeks of the treatment (not shown), indicating relatively fast kinetics in relation to the equilibration of the total lipid pool in this compartment. The DHA:EPA in plasma is similar to that in the diet; however, a relatively high accumulation of DHA is observed in the tissue lipids, with the most dramatic difference between accumulation of DHA and EPA observed in brain phospholipid fraction (Fig. 1(I and J))(Reference Sastry40). These differences indicate different metabolism of DHA and EPA, as well as specific transport mechanisms for these fatty acids in various body compartments(Reference Arterburn, Hall and Oken19, Reference Heath, Karpe and Milne41). EPA accumulates proportionally to its dietary content, except for liver TAG (Fig. 1(F)) and phospholipid (Fig. 1(H)) fractions, suggesting saturation at higher dietary intakes of EPA. Except for a linear dose response in total adipose tissue lipids (Fig. 1(C)) and brain phospholipids (when the values measured in the cHF-mice are subtracted; Fig. 1(I)), DHA incorporation in total plasma lipids (Fig. 1(A)), liver TAG (Fig. 1(E)) and phospholipid (Fig. 1(G)) fractions is saturable in relation to the dietary content of DHA. Importantly, even in the absence of any EPA or DHA in the cHF diet, substantial amounts of DHA are detected in liver (Fig. 1(G)) and especially in the brain (Fig. 1(I)) phospholipids, indicating quite efficient formation of EPA from ALA contained in the diet and preferential deposition of DHA in these tissues. The linear correlation between the accumulation of both EPA and DHA in total adipose tissue lipids and the dietary content of these fatty acids could reflect different molar concentrations of n-3 LC PUFA in adipose tissue lipids as compared with, for example, liver TAG, which are several-fold lower in the case of adipose tissue(Reference Heath, Karpe and Milne41). However, despite a relatively low specific content of n-3 LC PUFA in adipose tissue, which has also been observed in human subjects(Reference Arterburn, Hall and Oken19), adipose tissue provides high storage capacity for these fatty acids. Thus, in lean adult human subjects adipose tissue accounts for 15–25% body weight (this percentage can increase to 50% in morbidly-obese patients), while approximately 70% of the adipose tissue mass comprises lipids(Reference Covaci, de Boer and Ryan42). Accordingly, adipose tissue is known to serve as a buffer for LC PUFA in nursing mothers, thus preventing large fluctuations of LC PUFA concentration in breast milk(Reference Fidler, Sauerwald and Pohl43).

Fig. 1. Bioavailability of DHA and EPA and incorporation of these fatty acids into total lipids (TL) in white adipose tissue (C, D), liver TAG (E, F) and phospholipid (PL; G, H) fractions and brain PL (I, J). At 3 months of age mice were placed on a maize-based high-fat (cHF) diet or the cHF diet with 5% (w/w; D5) or 15% (w/w; D15) of its lipid replaced by the n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). After 9 weeks of treatment the mice were killed and plasma and tissues collected for analysis of DHA (•) and EPA (○) content. (A, C, E, G, I), The relationship between measured dietary DHA concentration (n 3) and measured DHA content (n 4–7) in plasma and various tissues; (B, D, F, H, J), corresponding results for EPA. (A, B), DHA and EPA respectively in plasma TL. The fold increases in the corresponding fatty acid as a result of actual measured 3·1-fold increase in DHA or EPA concentration in dietary lipids (from 5% (w/w) to 15% (w/w) in D5 and D15 diet respectively; basal values measured in cHF-fed mice were subtracted) are also shown. Values are means with their standard errors represented by vertical bars.

Extrapolation of the results relating to the dose dependence of various effects of n-3 LC PUFA from mice to human subjects is problematic for several reasons including, for example, a large difference in specific metabolic rate between the two species. In this context the results describing saturability of various plasma and tissue compartments with DHA may provide a useful lead, since a saturation of the plasma (phospholipid) pool by DHA has also been observed in human subjects(Reference Arterburn, Hall and Oken19). Thus, it could be inferred that n-3 LC PUFA effects observed in mice fed the cHF diet at the 15% (w/w) level of substitution (35% (w/w) fat; with 15% of its lipids replaced by the n-3 LC PUFA concentrate, corresponding to approximately 9 g DHA+EPA/100 g dietary lipids) are relevant for human subjects treated with about 2 g DHA (in a mixture with EPA)/d, since under these conditions the plasma lipid pool is close to saturation with DHA in both mice and human subjects(Reference Arterburn, Hall and Oken19) (see Fig. 1(A)). A decrease in the DHA:EPA(Reference Arterburn, Hall and Oken19) or in the fat content of the diet should result in the lower DHA intake needed for saturation of the plasma pool.

Prevention of body fat accumulation by n-3 long-chain PUFA

In accordance with other studies (for review, see Ruzickova et al.(Reference Ruzickova, Rossmeisl and Prazak11)), the experiments on C57BL/6 mice have also demonstrated that substitution of 15% (w/w) lipids in cHF diets by the n-3 LC PUFA concentrate EPAX 1050 TG prevents fat accumulation with a preferential reduction in abdominal fat depots(Reference Ruzickova, Rossmeisl and Prazak11Reference Kuda, Jelenik and Jilkova13). Using semi-synthetic high-fat diets a stronger anti-obesity effect has been observed with increasing DHA:EPA in the diets(Reference Ruzickova, Rossmeisl and Prazak11). The reduction in adipose tissue growth results in part from the inhibition of fat cell proliferation(Reference Ruzickova, Rossmeisl and Prazak11). In vitro, DHA inhibits adipocyte differentiation and induces apoptosis in post-confluent preadipocytes(Reference Kim, Della-Fera and Lin44). DHA also induces apoptosis in several models of cancer(Reference Stillwell, Shaikh and Zerouga45). The mechanism of the anti-proliferative effect of n-3 LC PUFA on adipose tissue is not completely understood and may reflect modulation of in situ eicosanoid production(Reference Okuno, Kajiwara and Imai46Reference Darimont, Vassaux and Ailhaud48). The anti-proliferative effect of n-3 LC PUFA may be involved in the reduced adiposity of pups born to rat or mouse dams fed diets supplemented with n-3 LC PUFA(Reference Korotkova, Gabrielsson and Lonn49) or ALA(Reference Massiera, Saint-Marc and Seydoux22) during gestation and suckling, and even in the anti-obesity(Reference Arenz, Ruckerl and Koletzko50) and anti-diabetic effects(Reference Knip and Akerblom51) of breast-feeding. Moreover, all these studies indicate that reduction in both hyperplasia of adipose tissue cells and hypertrophy of adipocytes (also, see later) contribute to the reduced accumulation of body fat as a result of n-3 LC PUFA intake.

Induction of a metabolic switch in adipose tissue and small intestine by n-3 long-chain PUFA

It has been found previously that feeding C57BL/6 mice a cHF diet supplemented with n-3 LC PUFA (i.e. 15% (w/w) lipids in cHF diets substituted by n-3 LC PUFA concentrate EPAX 1050 TG) induces mitochondrial biogenesis in white fat, with a stronger effect in epididymal fat in the abdomen than in subcutaneous adipose tissue(Reference Flachs, Horakova and Brauner12). The effect in abdominal fat is associated with a 3-fold increase in the expression of genes for regulatory factors for mitochondrial biogenesis and oxidative metabolism, PPARγ co-activator 1α and nuclear respiratory factor-1 respectively. A marked down-regulation of the stearoyl-CoA desaturase gene, Scd-1, is observed in white fat(Reference Flachs, Horakova and Brauner12), consistent with the induction of lipid oxidation by n-3 LC PUFA in the tissue(Reference Flachs, Horakova and Brauner12) and the role of Scd-1 (Reference Paton and Ntambi52) in the control of lipid oxidation. Expression of PPARγ co-activator 1α and nuclear respiratory factor-1 genes is also stimulated by n-3 LC PUFA in 3T3-L1 adipocytes(Reference Flachs, Horakova and Brauner12). Similar to the effect in adipose tissue, mitochondrial biogenesis is also induced by n-3 LC PUFA in the small intestine(Reference van Schothorst, Flachs and Franssen-van Hal34) but not in the liver(Reference Flachs, Horakova and Brauner12) or in the skeletal muscle (P Flachs and J Kopecky, unpublished results). Also, in the adipose tissue and in the intestine, as in the liver (see earlier), n-3 LC PUFA increase fatty acid oxidation, while in situ lipogenesis is suppressed(Reference van Schothorst, Flachs and Franssen-van Hal34). Thus, in the liver, adipose tissue and intestine dietary intake of n-3 LC PUFA induces a switch toward lipid catabolism and suppressed lipogenesis. Moreover, n-3 LC PUFA could depress basal lipolysis in adipose tissue of obese and insulin-resistant rats fed a sucrose-rich diet(Reference Lombardo, Hein and Chicco53).

The effect of n-3 LC PUFA on lipolysis may reflect restoration of the anti-lipolytic effect of insulin, while the induction of the metabolic switch in adipocytes could depend on transcriptional control mediated by PPARα and PPARγ(Reference Sanderson, de Groot and Hooiveld27Reference Madsen, Petersen and Kristiansen29). It has been hypothesized previously(Reference Flachs, Rossmeisl and Bryhn23) that the AMPK regulatory axis(Reference Carling38) could also be involved in the induction of the metabolic switch, including up-regulation of mitochondrial biogenesis and suppression of basal lipolysis in adipocytes. As indicated in a recent review(Reference Flachs, Rossmeisl and Bryhn23), induction of AMPK activity in adipose tissue(Reference Matejkova, Mustard and Sponarova54) is the key mechanism that induces (1) the metabolic switch toward lipid catabolism and suppressed lipogenesis in adipocytes and (2) the lean phenotype of mice with respiratory uncoupling induced by the aP2-Ucp1 transgene in adipocytes; AMPK in adipose tissue is also activated by phosphorylation in response to the anti-diabetic drugs the thiazolidinediones, the adipokines leptin and adiponectin, starvation and physical activity, i.e. under conditions promoting the metabolic switch in white fat. Phosphorylation of AMPK is required for the full activation of the enzyme and the phosphorylated:unphosphorylated form reflects the actual enzymic activity. To evaluate possible activation of the AMPK regulatory cascade(Reference Carling38) in white fat by n-3 LC PUFA the content of α1 AMPK and phosphorylated AMPK, as well as total acetyl-CoA carboxylase (ACC) and its phosphorylated form was evaluated by Western blotting in epididymal fat of mice fed cHF substituted with n-3 LC PUFA at the 15% or 44% (w/w) level for 5 weeks (Fig. 2(A and B)). ACC is the target for AMPK and its activity is inhibited by AMPK-mediated phosphorylation. Both α1 AMPK and phosphorylated AMPK contents tend to increase in response to the 15% (w/w) level of substitution (not shown) and their contents increase significantly in mice fed diet at the 44% (w/w) level of substitution, while the phosphorylated AMPK: total α1 AMPK remains unchanged (Fig. 2(A)). The contents of both total ACC and phosphorylated ACC, as well as the phosphorylated ACC: total ACC increase in response to the cHF diet at the 44% (w/w) level of substitution (Fig. (2B)). The status of AMPK phosphorylation is known to change in response to various immediate stimuli, while corresponding changes in ACC phosphorylation are more stable and could serve as a better marker of the metabolic switch. Activation of AMPK has also recently been observed in genetically-obese ob/ob mice (B6.V-Lepob/J) fed a low-fat (7% (w/w) fat) diet supplemented with n-3 LC PUFA(Reference Gonzalez-Periz, Horrillo and Ferre24). Thus, although no difference in phosphorylated AMPK:AMPK was detected in the experiment, the results together suggest activation of the AMPK intracellular regulatory pathway by n-3 LC PUFA. As shown in the case of the activation of AMPK in adipocytes under other conditions (see earlier), n-3 LC PUFA can also promote the conversion of white adipocytes into ‘fat burning cells’ by this mechanism(Reference Orci, Cook and Ravazzola55, Reference Zhou, Wang and Higa56). Activation of AMPK could increase the mitochondrial content of adipocytes, which is consistent with the suggestion that the number and activity of mitochondria within adipocytes contribute to the threshold at which fatty acids are released into the circulation, leading to insulin resistance and type 2 diabetes(Reference Maassen, Romijn and Heine57).

Fig. 2. AMP-activated protein kinase (AMPK) and acetyl-CoA carboxylase (ACC) phosphorylation. At 3 months of age mice were randomly assigned to a maize-based high-fat (cHF) diet or the cHF diet with 44% (w/w; D44) of its lipid replaced by n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). After 5 weeks of feeding the mice were killed and epididymal adipose tissue collected for the analysis of AMPK and ACC phosphorylation(Reference Matejkova, Mustard and Sponarova54, Reference Sponarova, Mustard and Horakova76). (A), Total α1 AMPK-immunoreactive protein, phosphorylated form of AMPK (pAMPK) and pAMPK:total AMPK, measured as a signal intensity using Western blotting. (B), Total ACC-immunoreactive protein, phosphorylated form of ACC (pACC) and pACC: total ACC, measured as a signal intensity using Western blotting. (□), Control cHF diet; (▪), experimental D44 diet. Values are mean with their standard errors represented by vertical bars for five to eight mice. AU, arbitrary units.

The AMPK-dependent induction of the metabolic switch in white fat should contribute to a decrease in the size of mature adipocytes, as observed in mice treated with n-3 LC PUFA or thiazolidinediones(Reference Ruzickova, Rossmeisl and Prazak11, Reference Okuno, Tamemoto and Tobe58, Reference Todoric, Loffler and Huber59) and even in patients with diabetes whose diet is supplemented with n-3 LC PUFA(Reference Skurnick-Minot, Laromiguiere and Oppert60). Compared with large adipocytes, small cells are more insulin sensitive and less lipolytic, release lower levels of inflammatory cytokines (for review, see Yang & Smith(Reference Yang and Smith61) ) and secrete higher levels of adiponectin(Reference Gahceci, Gokalp and Bahceci62). The small cells could also serve as a ‘buffer’ for lipids and protect tissues against the lipotoxicity(Reference Kintscher and Law63, Reference Danforth64). Thus, n-3 LC PUFA would enhance insulin action in adipose tissue by counteracting adipose tissue hypertrophy. Despite a minimal contribution of adipose tissue to the whole-body glucose uptake, impairment of glucose transport in adipocytes results in insulin resistance in the skeletal muscle and liver(Reference Abel, Peroni and Kim65); the insulin-sensitizing effect of n-3 LC PUFA in adipocytes may be crucial for the beneficial effect of these lipids on whole-body glycaemic control. Importantly, in addition, induction of the metabolic switch in the small intestine by n-3 LC PUFA could be mediated by AMPK and limit accretion of body fat(Reference van Schothorst, Flachs and Franssen-van Hal34, Reference Gabler, Radcliffe and Spencer37).

Amelioration of low-grade inflammation of adipose tissue and induction of adiponectin by n-3 long-chain PUFA

In accordance with the general anti-inflammatory action of n-3 LC PUFA(Reference Calder6) (possibly mediated by NF-κB(Reference Singer, Shapiro and Theilla7, Reference van Schothorst, Flachs and Franssen-van Hal34)) low-grade inflammation of adipose tissue, which is associated with obesity, is also reduced by n-3 LC PUFA supplementation in obese diabetic db/db mice(Reference Todoric, Loffler and Huber59), as well as in the experiments on C57BL/6 mice fed the cHF diet at the 15% (w/w) level of substitution(Reference Kuda, Jelenik and Jilkova13). The inflammation is suppressed even more potently by a DHA derivative (α-ethyl DHA ethyl ester) replacing only 1·5% (w/w) lipids in the cHF diet(Reference Rossmeisl, Jelenik and Jilkova66). As shown in Fig. 3, the cHF diet-induced adipose tissue hypertrophy is associated with infiltration of adipose tissue by macrophages immunoreactive for MAC-2 (β-galactoside-binding lectin expressed on activated macrophages), which aggregate in crown-like structures surrounding adipocytes(Reference Cinti, Mitchell and Barbatelli67). Numerous crown-like structures are detected in cHF diet-fed mice (Fig. 3(A and E)) but not in chow diet-fed (Fig. 3(C)) mice. In accordance with the previous study(Reference Cinti, Mitchell and Barbatelli67), adipocytes surrounded by crown-like structures are not viable, based on the absence of perilipin staining. Viable adipocytes, not surrounded by macrophages, are positive for perilipin (Fig. 3(D)). n-3 LC PUFA prevent, in part, the macrophage infiltration (Fig. 3(B)). It should be investigated whether n-3 LC PUFA not only decrease the total number of macrophages in adipose tissue but could also change their polarity, while suppressing specifically M1 pro-inflammatory macrophages and activating M2 macrophages secreting anti-inflammatory cytokines(Reference Lumeng, Delproposto and Westcott68). Such an effect has recently been demonstrated for thiazolidinediones, affecting macrophages in adipose tissue(Reference Tobe, Fujisaka and Ishiki69) and peripheral blood(Reference Bouhlel, Derudas and Rigamonti70).

Fig. 3. Immunodetection of macrophages in epididymal adipose tissue. At 3 months of age mice were placed on a maize-based high-fat diet (cHF) or the cHF diet with 15% (w/w; D15) of its lipid replaced by n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). Some mice were maintained on a chow diet. After 20 weeks of treatment, mice were killed and adipose tissue samples processed for immunohistological analysis(Reference Cinti, Mitchell and Barbatelli67). (A, B, C), MAC-2 (β-galactoside-binding lectin expressed on activated macrophages)-immunoreactive macrophages were detected in 5 μm thick sections (darkly-stained cells). Note that almost all macrophages are localized within crown-like structures surrounding individual adipocytes. (A), cHF diet; (B), D15 diet; (C), chow diet; (D, E), detailed view of adipose tissue from the cHF-fed mice with visualized perilipin and MAC-2 respectively. ––, 200 μm.

The suppression of the low-grade inflammation of adipose tissue by n-3 LC PUFA in mice is associated with induction of adiponectin(Reference Neschen, Morino and Rossbacher32, Reference Rossi, Lombardo and Lacorte71, Reference Flachs, Mohamed-Ali and Horakova72), the major adipokine exerting an insulin-sensitizing effect, possibly as a result of activation of AMPK in various tissues(Reference Yamauchi, Kamon and Minokoshi73, Reference Nawrocki, Rajala and Tomas74). The induction of adiponectin is stronger in the epididymal fat in the abdomen than in the subcutaneous fat(Reference Neschen, Morino and Rossbacher32, Reference Flachs, Mohamed-Ali and Horakova72) and it is probably mediated by PPARγ(Reference Neschen, Morino and Rossbacher32) in fully-differentiated(Reference Flachs, Mohamed-Ali and Horakova72) fat cells. A recent clinical study has demonstrated the induction of plasma adiponectin in response to a daily intake of 1·3 g EPA and 2·9 g DHA (administered as EPAX 2050 TG; EPAX AS) in overweight patients who were simultaneously undertaking a weight-loss programme(Reference Krebs, Browning and McLean75). The induction of adiponectin could contribute to the beneficial effect of n-3 LC PUFA on systemic insulin sensitivity.

It has recently been investigated whether combined treatment with DHA+EPA and the thiazolidinedione rosiglitazone would provide additive beneficial effects on various features of MS in the cHF diet-fed mice(Reference Kuda, Jelenik and Jilkova13). DHA+EPA administered at the 15% (w/w) level of substitution and a low dose of rosiglitazone exert additive effects in the prevention of obesity, adipocyte hypertrophy, low-grade adipose tissue inflammation, induction of adiponectin, dyslipidaemia and insulin resistance. The combined treatment also reverses dietary obesity, dyslipidaemia and impaired glucose tolerance in the mice. These results suggest that DHA+EPA and thiazolidinediones could be used as complementary therapies to counteract various pathologies associated with MS and that adipose tissue represents an important target in this strategy.

Conclusion

Adipose tissue metabolism, inflammatory status and secretion of adipokines play an important role in the development of the pathological conditions associated with MS. Despite a relatively small increase in n-3 LC PUFA concentrations in adipose tissue lipids in response to dietary intake of these fatty acids, adipose tissue possesses a substantial capacity for n-3 LC PUFA storage, and it is specifically linked to the beneficial effects of n-3 LC PUFA on health. Surprisingly strong suppression of adipose tissue hyperplasia and hypertrophy by n-3 LC PUFA supplementation, reflecting induction of lipid catabolism and suppression of lipogenesis in adipocytes, as well as amelioration of adipose tissue inflammation and increased secretion of adiponectin, help to explain the beneficial effects of n-3 LC PUFA in the prevention and treatment of various components of MS. Modulation of adipose tissue metabolism, cellular composition and secretion of adipokines by n-3 LC PUFA has a prominent role in the multiple mechanisms of action of these lipids and should be explored further in combination therapies for various pathologies in human subjects.

Acknowledgements

This work was supported by the grants from the Ministry of Education, Youth and Sports (MSM 0021620820) and the Czech Science Foundation (303/08/0664). Further support included a research project AV0Z50110509 and grants from the European Commission (LSHM-CT-2004–005272, EXGENESIS) and from EPAX AS (Norway). The authors declare no conflict of interest. J. K., M. R. and P. F. were engaged in most of the animal experiments described and J. K. also coordinated all the studies. M. B. served as an advisor to the studies. J. K., M. R., P. F. and M. B. wrote the manuscript. O. K. performed most of the studies on the combined treatment of mice with n-3 LC PUFA and rosiglitazone and performed the statistical analysis of all the results. Z. J. performed the immunohistochemical analysis of adipose tissue. P. B. conducted the Western blot analysis of adipose tissue. B. S. and E. T. carried out the analysis of fatty acid composition. All the authors read and approved the manuscript.

References

1.Kopelman, PG (2000) Obesity as a medical problem Nature 404, 635643.CrossRefGoogle ScholarPubMed
2.Kahn, SE, Hull, RL & Utzschneider, KM (2006) Mechanisms linking obesity to insulin resistance and type 2 diabetes. Nature 444, 840846.CrossRefGoogle ScholarPubMed
3.Tuomilehto, J, Lindstrom, J, Eriksson, JG et al. (2001) Prevention of type 2 diabetes mellitus by changes in lifestyle among subjects with impaired glucose tolerance. N Engl J Med 344, 13431350.CrossRefGoogle ScholarPubMed
4.Knowler, WC, Barrett-Connor, E, Fowler, SE et al. (2002) Reduction in the incidence of type 2 diabetes with lifestyle intervention or metformin. N Engl J Med 346, 393403.Google ScholarPubMed
5.Ruxton, CH, Reed, SC, Simpson, MJ et al. (2004) The health benefits of omega-3 polyunsaturated fatty acids: a review of the evidence. J Hum Nutr Diet 17, 449459.CrossRefGoogle ScholarPubMed
6.Calder, PC (2006) n-3 polyunsaturated fatty acids, inflammation, and inflammatory diseases. Am J Clin Nutr 83, 1505S1519S.CrossRefGoogle ScholarPubMed
7.Singer, P, Shapiro, H, Theilla, M et al. (2008) Anti-inflammatory properties of omega-3 fatty acids in critical illness: novel mechanisms and an integrative perspective. Intensive Care Med 34, 15801592.CrossRefGoogle Scholar
8.Ikemoto, S, Takahashi, M, Tsunoda, N et al. (1996) High-fat diet-induced hyperglycemia and obesity in mice: Differential effects of dietary oils. Metabolism 45, 15391546.CrossRefGoogle ScholarPubMed
9.Storlien, LH, Kraegen, EW, Chisholm, DJ et al. (1987) Fish oil prevents insulin resistance induced by high-fat feeding in rats. Science 237, 885888.CrossRefGoogle ScholarPubMed
10.Libby, P, Plutzky, J (2007) Inflammation in diabetes mellitus: role of peroxisome proliferator-activated receptor-alpha and peroxisome proliferator-activated receptor-gamma agonists. Am J Cardiol 99, 27B40B.CrossRefGoogle ScholarPubMed
11.Ruzickova, J, Rossmeisl, M, Prazak, T et al. (2004) Omega-3 PUFA of marine origin limit diet-induced obesity in mice by reducing cellularity of adipose tissue. Lipids 39, 11771185.CrossRefGoogle ScholarPubMed
12.Flachs, P, Horakova, O, Brauner, P et al. (2005) Polyunsaturated fatty acids of marine origin upregulate mitochondrial biogenesis and induce beta-oxidation in white fat. Diabetologia 48, 23652375.CrossRefGoogle ScholarPubMed
13.Kuda, O, Jelenik, T, Jilkova, Z et al. (2009) n-3 Fatty acids and rosiglitazone improve insulin sensitivity through additive stimulatory effects on muscle glycogen synthesis in mice fed a high-fat diet. Diabetologia 52, 941951.CrossRefGoogle ScholarPubMed
14.Mori, TA, Bao, DQ, Burke, V et al. (1999) Dietary fish as a major component of a weight-loss diet: effect on serum lipids, glucose, and insulin metabolism in overweight hypertensive subjects. Am J Clin Nutr 70, 817825.CrossRefGoogle Scholar
15.Couet, C, Delarue, J, Ritz, P et al. (1997) Effect of dietary fish oil on body fat mass and basal fat oxidation in healthy adults. Int J Obes (Lond) 21, 637643.CrossRefGoogle ScholarPubMed
16.Kunesova, M, Braunerova, R, Hlavaty, P et al. (2006) The influence of n-3 polyunsaturated fatty acids and very low calorie diet during a short-term weight reducing regimen on weight loss and serum fatty acid composition in severely obese women. Physiol Res 55, 6372.CrossRefGoogle ScholarPubMed
17.MacLean, CH, Konica, WA, Morton, SC et al. (2004) Effects of Omega-3 Fatty Acids on Lipids and Glycemic Control in Type II Diabetes and the Metabolic Syndrome and on Inflammatory Bowel Disease, Rheumatoid Arthritis, Renal Disease, Systemic Lupus Erythrematousus, and Osteoporosis. Evidence Report/Technology Assessment no. 89. AHRQ Publication no. 04-E012–1. 2004. Rockville, MD: Agency for Healthcare Research and Quality.Google Scholar
18.Nettleton, JA & Katz, R (2005) n-3 long-chain polyunsaturated fatty acids in type 2 diabetes: a review. J Am Diet Assoc 105, 428440.CrossRefGoogle ScholarPubMed
19.Arterburn, LM, Hall, EB & Oken, H (2006) Distribution, interconversion, and dose response of n-3 fatty acids in humans. Am J Clin Nutr 83, 1467S1476S.CrossRefGoogle ScholarPubMed
20.Brenna, JT, Salem, N Jr, Sinclair, AJ et al. (2009) alpha-Linolenic acid supplementation and conversion to n-3 long-chain polyunsaturated fatty acids in humans. Prostaglandins Leukot Essent Fatty Acids 80, 8591.CrossRefGoogle ScholarPubMed
21.Eaton, SB, Eaton, SB III, Konner, MJ et al. (1996) An evolutionary perspective enhances understanding of human nutritional requirements. J Nutr 126, 17321740.CrossRefGoogle ScholarPubMed
22.Massiera, F, Saint-Marc, P, Seydoux, J et al. (2003) Arachidonic acid and prostacyclin signaling promote adipose tissue development: a human health concern? J Lipid Res 44, 271279.CrossRefGoogle ScholarPubMed
23.Flachs, P, Rossmeisl, M, Bryhn, M et al. (2009) Cellular and molecular effects of n-3 polyunsaturated fatty acids on adipose tissue biology and metabolism. Clin Sci (Lond) 116, 116.CrossRefGoogle ScholarPubMed
24.Gonzalez-Periz, A, Horrillo, R, Ferre, N et al. (2009) Obesity-induced insulin resistance and hepatic steatosis are alleviated by omega-3 fatty acids: a role for resolvins and protectins. FASEB J (Epublication ahead of print version; doi: 10.1096/fj.08–125674).CrossRefGoogle ScholarPubMed
25.James, MJ, Gibson, RA & Cleland, LG (2000) Dietary polyunsaturated fatty acids and inflammatory mediator production. Am J Clin Nutr 71, 343S348S.CrossRefGoogle ScholarPubMed
26.Schwab, JM, Chiang, N, Arita, M et al. (2007) Resolvin E1 and protectin D1 activate inflammation-resolution programmes. Nature 447, 869874.CrossRefGoogle ScholarPubMed
27.Sanderson, LM, de Groot, PJ, Hooiveld, GJ et al. (2008) Effect of synthetic dietary triglycerides: a novel research paradigm for nutrigenomics. PLoS ONE 3, e1681.CrossRefGoogle ScholarPubMed
28.Luquet, S, Gaudel, C, Holst, D et al. (2005) Roles of PPAR delta in lipid absorption and metabolism: a new target for the treatment of type 2 diabetes. Biochim Biophys Acta 1740, 313317.CrossRefGoogle ScholarPubMed
29.Madsen, L, Petersen, RK & Kristiansen, K (2005) Regulation of adipocyte differentiation and function by polyunsaturated fatty acids. Biochim Biophys Acta 1740, 266286.CrossRefGoogle ScholarPubMed
30.Neschen, S, Morino, K, Dong, J et al. (2007) n-3 Fatty acids preserve insulin sensitivity in vivo in a PPAR-alpha-dependent manner. Diabetes 56, 10341041.CrossRefGoogle Scholar
31.Jump, DB (2004) Fatty acid regulation of gene transcription. Crit Rev Clin Lab Sci 41, 4178.CrossRefGoogle ScholarPubMed
32.Neschen, S, Morino, K, Rossbacher, JC et al. (2006) Fish oil regulates adiponectin secretion by a peroxisome proliferator-activated receptor-dependent mechanism in mice. Diabetes 55, 924928.CrossRefGoogle Scholar
33.Teran-Garcia, M, Adamson, AW, Yu, G et al. (2007) Polyunsaturated fatty acid suppression of fatty acid synthase (FASN): evidence for dietary modulation of NF-Y binding to the Fasn promoter by SREBP-1c. Biochem J 402, 591600.CrossRefGoogle Scholar
34.van Schothorst, EM, Flachs, P, Franssen-van Hal, NL et al. (2009) Induction of lipid oxidation by polyunsaturated fatty acids of marine origin in small intestine of mice fed a high-fat diet. BMC Genomics 10, 110.CrossRefGoogle ScholarPubMed
35.Jucker, BM, Cline, GW, Barucci, N et al. (1999) Differential effects of safflower oil versus fish oil feeding on insulin-stimulated glycogen synthesis, glycolysis, and pyruvate dehydrogenase flux in skeletal muscle: a 13C nuclear magnetic resonance study. Diabetes 48, 134140.CrossRefGoogle ScholarPubMed
36.Suchankova, G, Tekle, M, Saha, AK et al. (2005) Dietary polyunsaturated fatty acids enhance hepatic AMP-activated protein kinase activity in rats. Biochem Biophys Res Commun 326, 851858.CrossRefGoogle ScholarPubMed
37.Gabler, NK, Radcliffe, JS, Spencer, JD et al. (2009) Feeding long-chain n-3 polyunsaturated fatty acids during gestation increases intestinal glucose absorption potentially via the acute activation of AMPK. J Nutr Biochem 20, 1725.CrossRefGoogle ScholarPubMed
38.Carling, D (2004) The AMP-activated protein kinase cascade – a unifying system for energy control. Trends Biochem Sci 29, 1824.CrossRefGoogle ScholarPubMed
39.Muoio, DM & Newgard, CB (2008) Mechanisms of disease: molecular and metabolic mechanisms of insulin resistance and beta-cell failure in type 2 diabetes. Nat Rev Mol Cell Biol 9, 193205.CrossRefGoogle ScholarPubMed
40.Sastry, PS (1985) Lipids of nervous tissue: composition and metabolism. Prog Lipid Res 24, 69–176.CrossRefGoogle Scholar
41.Heath, RB, Karpe, F, Milne, RW et al. (2003) Selective partitioning of dietary fatty acids into the VLDL TG pool in the early postprandial period. J Lipid Res 44, 20652072.CrossRefGoogle ScholarPubMed
42.Covaci, A, de Boer, J, Ryan, JJ et al. (2002) Distribution of organobrominated and organochlorinated contaminants in Belgian human adipose tissue. Environ Res 88, 210218.CrossRefGoogle ScholarPubMed
43.Fidler, N, Sauerwald, T, Pohl, A et al. (2000) Docosahexaenoic acid transfer into human milk after dietary supplementation: a randomized clinical trial. J Lipid Res 41, 13761383.CrossRefGoogle ScholarPubMed
44.Kim, HK, Della-Fera, M, Lin, J et al. (2006) Docosahexaenoic acid inhibits adipocyte differentiation and induces apoptosis in 3T3-L1 preadipocytes. J Nutr 136, 29652969.CrossRefGoogle ScholarPubMed
45.Stillwell, W, Shaikh, SR, Zerouga, M et al. (2005) Docosahexaenoic acid affects cell signaling by altering lipid rafts. Reprod Nutr Dev 45, 559579.CrossRefGoogle ScholarPubMed
46.Okuno, M, Kajiwara, K, Imai, S et al. (1997) Perilla oil prevents the excessive growth of visceral adipose tissue in rats by down-regulating adipocyte differentiation. J Nutr 127, 17521757.CrossRefGoogle ScholarPubMed
47.Gregoire, FM, Smas, CM & Sul, HS (1998) Understanding adipocyte differentiation. Physiol Rev 78, 783809.CrossRefGoogle ScholarPubMed
48.Darimont, C, Vassaux, G, Ailhaud, G et al. (1994) Differentiation of preadipose cells: paracrine role of prostacyclin upon stimulation of adipose cells by angiotensin-II. Endocrinology 135, 20302036.CrossRefGoogle ScholarPubMed
49.Korotkova, M, Gabrielsson, B, Lonn, M et al. (2002) Leptin levels in rat offspring are modified by the ratio of linoleic to alpha-linolenic acid in the maternal diet. J Lipid Res 43, 17431749.CrossRefGoogle ScholarPubMed
50.Arenz, S, Ruckerl, R, Koletzko, B et al. (2004) Breast-feeding and childhood obesity – a systematic review. Int J Obes Relat Metab Disord 28, 12471256.CrossRefGoogle ScholarPubMed
51.Knip, M & Akerblom, HK (2005) Early nutrition and later diabetes risk. Adv Exp Med Biol 569, 142150.CrossRefGoogle ScholarPubMed
52.Paton, CM & Ntambi, JM (2008) Biochemical and physiological function of stearoyl-CoA desaturase. Am J Physiol Endocrinol Metab (Epublication ahead of print version; doi:10.1152/ajpendo.90897.2008).Google ScholarPubMed
53.Lombardo, YB, Hein, G & Chicco, A (2007) Metabolic syndrome: effects of n-3 PUFAs on a model of dyslipidemia, insulin resistance and adiposity. Lipids 42, 427437.CrossRefGoogle Scholar
54.Matejkova, O, Mustard, KJ, Sponarova, J et al. (2004) Possible involvement of AMP-activated protein kinase in obesity resistance induced by respiratory uncoupling in white fat. FEBS Lett 569, 245248.CrossRefGoogle ScholarPubMed
55.Orci, L, Cook, WS, Ravazzola, M et al. (2004) Rapid transformation of white adipocytes into fat-oxidizing machines. Proc Natl Acad Sci U S A 101, 20582063.CrossRefGoogle ScholarPubMed
56.Zhou, Y-T, Wang, Z-W, Higa, M et al. (1999) Reversing adipocyte differentiation: Implications for treatment of obesity. Proc Natl Acad Sci U S A 96, 23912395.CrossRefGoogle ScholarPubMed
57.Maassen, JA, Romijn, JA & Heine, RJ (2007) Fatty acid-induced mitochondrial uncoupling in adipocytes as a key protective factor against insulin resistance and beta cell dysfunction: a new concept in the pathogenesis of obesity-associated type 2 diabetes mellitus. Diabetologia 50, 20362041.CrossRefGoogle ScholarPubMed
58.Okuno, A, Tamemoto, H, Tobe, K et al. (1998) Troglitazone increases the number of small adipocytes without the change of white adipose tissue mass in obese Zucker rats. J Clin Invest 101, 13541361.CrossRefGoogle ScholarPubMed
59.Todoric, J, Loffler, M, Huber, J et al. (2006) Adipose tissue inflammation induced by high-fat diet in obese diabetic mice is prevented by n-3 polyunsaturated fatty acids. Diabetologia 49, 21092119.CrossRefGoogle ScholarPubMed
60.Skurnick-Minot, G, Laromiguiere, M, Oppert, JM et al. (2004) Whole-body fat mass and insulin sensitivity in type 2 diabetic women: effect of n-3 polyunsaturated fatty acids. Diabetes 53, 154.Google Scholar
61.Yang, X & Smith, U (2007) Adipose tissue distribution and risk of metabolic disease: does thiazolidinedione-induced adipose tissue redistribution provide a clue to the answer? Diabetologia 50, 11271139.CrossRefGoogle Scholar
62.Gahceci, M, Gokalp, D, Bahceci, S et al. (2007) The correlation between adiposity and adiponectin, tumor necrosis factor alpha, interleukin-6 and high sensitivity C-reactive protein levels. Is adipocyte size associated with inflammation in adults? J Endocrinol Invest 30, 210214.Google Scholar
63.Kintscher, U & Law, RE (2005) PPARgamma-mediated insulin sensitization: the importance of fat versus muscle. Am J Physiol Endocrinol Metab 288, E287E291.CrossRefGoogle ScholarPubMed
64.Danforth, E Jr (2000) Failure of adipocyte differentiation causes type II diabetes mellitus? Nature Genetics 26, 13.CrossRefGoogle ScholarPubMed
65.Abel, ED, Peroni, O, Kim, JK et al. (2001) Adipose-selective targeting of the GLUT4 gene impairs insulin action in muscle and liver. Nature 409, 729733.CrossRefGoogle ScholarPubMed
66.Rossmeisl, M, Jelenik, T, Jilkova, Z et al. (2009) Prevention and reversal of obesity and glucose intolerance in mice by DHA-derivatives. Obesity 17, 10231031.CrossRefGoogle ScholarPubMed
67.Cinti, S, Mitchell, G, Barbatelli, G et al. (2005) Adipocyte death defines macrophage localization and function in adipose tissue of obese mice and humans. J Lipid Res 46, 23472355.CrossRefGoogle ScholarPubMed
68.Lumeng, CN, Delproposto, JB, Westcott, DJ et al. (2008) Phenotypic switching of adipose tissue macrophages with obesity is generated by spatiotemporal differences in macrophage subtypes. Diabetes 57, 32393246.CrossRefGoogle ScholarPubMed
69.Tobe, K, Fujisaka, S, Ishiki, M et al. (2009) Regulatory mechanisms for adipose tissue M1 and M2 macrophages in diet-induced obese mice. Keystone Symposium on Type 2 Diabetes and Insulin Resistance (J3), Fairmont Banff Springs, Alberta, Canada, Abstr. Silverthorne, CO: Keystone Symposia.CrossRefGoogle Scholar
70.Bouhlel, MA, Derudas, B, Rigamonti, E et al. (2007) PPARgamma activation primes human monocytes into alternative M2 macrophages with anti-inflammatory properties. Cell Metab 6, 137143.CrossRefGoogle ScholarPubMed
71.Rossi, AS, Lombardo, YB, Lacorte, JM et al. (2005) Dietary fish oil positively regulates plasma leptin and adiponectin levels in sucrose-fed, insulin-resistant rats. Am J Physiol Regul Integr Comp Physiol 289, R486R494.CrossRefGoogle ScholarPubMed
72.Flachs, P, Mohamed-Ali, V, Horakova, O et al. (2006) Polyunsaturated fatty acids of marine origin induce adiponectin in mice fed high-fat diet. Diabetologia 49, 394397.CrossRefGoogle Scholar
73.Yamauchi, T, Kamon, J, Minokoshi, Y et al. (2002) Adiponectin stimulates glucose utilization and fatty-acid oxidation by activating AMP-activated protein kinase. Nat Med 8, 12881295.CrossRefGoogle ScholarPubMed
74.Nawrocki, AR, Rajala, MW, Tomas, E et al. (2006) Mice lacking adiponectin show decreased hepatic insulin sensitivity and reduced responsiveness to peroxisome proliferator-activated receptor gamma agonists. J Biol Chem 281, 26542660.CrossRefGoogle ScholarPubMed
75.Krebs, JD, Browning, LM, McLean, NK et al. (2006) Additive benefits of long-chain n-3 polyunsaturated fatty acids and weight-loss in the management of cardiovascular disease risk in overweight hyperinsulinaemic women. Int J Obes (Lond) 30, 15351544.CrossRefGoogle ScholarPubMed
76.Sponarova, J, Mustard, KJ, Horakova, O et al. (2005) Involvement of AMP-activated protein kinase in fat depot-specific metabolic changes during starvation. FEBS Lett 579, 61056110.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Bioavailability of DHA and EPA and incorporation of these fatty acids into total lipids (TL) in white adipose tissue (C, D), liver TAG (E, F) and phospholipid (PL; G, H) fractions and brain PL (I, J). At 3 months of age mice were placed on a maize-based high-fat (cHF) diet or the cHF diet with 5% (w/w; D5) or 15% (w/w; D15) of its lipid replaced by the n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). After 9 weeks of treatment the mice were killed and plasma and tissues collected for analysis of DHA (•) and EPA (○) content. (A, C, E, G, I), The relationship between measured dietary DHA concentration (n 3) and measured DHA content (n 4–7) in plasma and various tissues; (B, D, F, H, J), corresponding results for EPA. (A, B), DHA and EPA respectively in plasma TL. The fold increases in the corresponding fatty acid as a result of actual measured 3·1-fold increase in DHA or EPA concentration in dietary lipids (from 5% (w/w) to 15% (w/w) in D5 and D15 diet respectively; basal values measured in cHF-fed mice were subtracted) are also shown. Values are means with their standard errors represented by vertical bars.

Figure 1

Fig. 2. AMP-activated protein kinase (AMPK) and acetyl-CoA carboxylase (ACC) phosphorylation. At 3 months of age mice were randomly assigned to a maize-based high-fat (cHF) diet or the cHF diet with 44% (w/w; D44) of its lipid replaced by n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). After 5 weeks of feeding the mice were killed and epididymal adipose tissue collected for the analysis of AMPK and ACC phosphorylation(54,76). (A), Total α1 AMPK-immunoreactive protein, phosphorylated form of AMPK (pAMPK) and pAMPK:total AMPK, measured as a signal intensity using Western blotting. (B), Total ACC-immunoreactive protein, phosphorylated form of ACC (pACC) and pACC: total ACC, measured as a signal intensity using Western blotting. (□), Control cHF diet; (▪), experimental D44 diet. Values are mean with their standard errors represented by vertical bars for five to eight mice. AU, arbitrary units.

Figure 2

Fig. 3. Immunodetection of macrophages in epididymal adipose tissue. At 3 months of age mice were placed on a maize-based high-fat diet (cHF) or the cHF diet with 15% (w/w; D15) of its lipid replaced by n-3 long-chain PUFA concentrate EPAX 1050 TG (EPAX AS, Aalesund, Norway). Some mice were maintained on a chow diet. After 20 weeks of treatment, mice were killed and adipose tissue samples processed for immunohistological analysis(67). (A, B, C), MAC-2 (β-galactoside-binding lectin expressed on activated macrophages)-immunoreactive macrophages were detected in 5 μm thick sections (darkly-stained cells). Note that almost all macrophages are localized within crown-like structures surrounding individual adipocytes. (A), cHF diet; (B), D15 diet; (C), chow diet; (D, E), detailed view of adipose tissue from the cHF-fed mice with visualized perilipin and MAC-2 respectively. ––, 200 μm.