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Mechanisms underlying the immunomodulatory effects of n-3 PUFA

Published online by Cambridge University Press:  14 June 2010

Parveen Yaqoob*
Affiliation:
Hugh Sinclair Unit of Human Nutrition, Department of Food and Nutritional Sciences, and Institute of Cardiovascular and Metabolic Research, The University of Reading, ReadingRG6 6AP, UK
*
Corresponding author: Professor Parveen Yaqoob, fax +44 118 931 0800, email P.Yaqoob@reading.ac.uk
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Abstract

The enrichment of immune cell membranes with n-3 PUFA is associated with modulation of immune function. The degree of incorporation of n-3 PUFA (and therefore the impact of dietary n-3 PUFA on immune function) appears to depend on a number of factors including species and age. The mechanisms involved are still largely unclear, but recent work has focused on two areas; lipid rafts and eicosanoids. In vitro studies suggest that lipid rafts could play a role in the immunomodulatory effects of n-3 PUFA, but there is still little information regarding the extent to which membrane microdomains in human lymphocytes are modulated by dietary supplementation. The enrichment of cell membranes with n-3 PUFA also modulates the production of eicosanoids, the full extent of which has not yet been realized; this represents a key area for future research.

Type
3rd International Immunonutrition Workshop
Copyright
Copyright © The Author 2010

Abbreviations:
AA

arachidonic acid

PE

phosphatidylethanolamine

Fatty acids play diverse roles in all cells. They are important as a source of energy, as structural components of cell membranes which influence the physical and functional properties of membranes and as signalling molecules and regulators of gene expression(Reference Calder, Burdge, Nicolaou and Kokotos1). In addition, some PUFA including dihomo-γ-linolenic acid (20:3n-6), arachidonic acid (AA), EPA and DHA can serve as precursors for the synthesis of bioactive lipid mediators, such as PG, leukotrienes, lipoxins and resolvins(Reference Lewis, Austen and Soberman2Reference Calder6). Since the 1980s, a large body of evidence has evolved that suggests that fatty acids are capable of modulating immune function(Reference Yaqoob and Calder7). Initially, many of the effects were demonstrated in animals, but studies are now increasingly being conducted in either healthy human subjects or in patients suffering from specific immune-related diseases. However, human studies investigating the relationship between dietary fatty acids and the immune response have been disappointingly inconsistent. There are likely to be several reasons for this. First, the doses of fatty acids tested in human studies, even when administered at levels many-fold higher than normal dietary intakes, do not compare with the very high levels employed in most animal studies. Second, in studies investigating the effects of fish oil on immune function, preparations of fish oil have varied considerably in their relative contents of EPA and DHA, which might have resulted in different effects. Third, the majority of human studies have been insufficiently powered to take into account the enormous variation in the parameters of immune function, for example, ex vivo cytokine production, which we now recognize to be influenced by genotypic variation(Reference Grimble, Howell and O'Reilly8). The issue of dose is clearly an important one in view of potential public health policy and recommendations. The considerable inconsistency in the previous reports on the effects of n-3 PUFA on ex vivo production of inflammatory cytokines was thought to be due to differences in administered doses(Reference Calder9). However, this does not fully account for the inconsistency, since some studies employing high doses of n-3 PUFA showed no effect on cytokine production, whereas others using low doses reported inhibition. Mantzioris et al.(Reference Mantzioris, Cleland and Gibson10) adopted the approach of setting target tissue concentrations of EPA, rather than target dietary intakes; they aimed to increase the mononuclear cell EPA content to 1·5% total fatty acids by 2 weeks of dietary modification. Although this resulted in individual subjects consuming different quantities of n-3 PUFA, the strategy was based on the observation by Caughey et al.(Reference Caughey, Mantzioris and Gibson11) that the EPA content of mononuclear cells is strongly associated with ex vivo production of IL-1β and TNFα and that 1·5% EPA results in maximum suppression of cytokine synthesis. However, Thies et al.(Reference Thies, Miles and Nebe-von-Caron12) reported that fish oil supplementation, providing 0·72 g EPA/d and 0·28 g DHA/d, failed to inhibit ex vivo cytokine production in healthy subjects, even though the mononuclear cell EPA content reached 1·5% of total fatty acids. Furthermore, a study using a much higher dose of 2·1 g EPA/d plus 1·1 g DHA/d also showed no effect of fish oil supplementation on ex vivo production of cytokines, despite achieving mononuclear cell EPA levels of 2·5% total fatty acids after 4 weeks and 3·3% at 12 weeks(Reference Yaqoob and Calder13). It is likely that many of the studies described above lacked sufficient power and may therefore have missed the subtle effects of n-3 PUFA.

Is there a relationship between fatty acid composition and function of immune cells?

In vitro studies have clearly demonstrated that alterations in the phagocyte membrane fatty acid composition are associated with altered phagocytic capacity(Reference Calder14). Dietary studies have tended to be contradictory, but it has been demonstrated that the phagocytic activity of neutrophils and monocytes is positively related to the membrane content of n-3 PUFA(Reference Kew, Banerjee and Minihane15) and that supplementation with n-3 PUFA enhances phagocytic activity(Reference Kew, Banerjee and Minihane16). For other functional outcomes, the picture is less clear. Fritsche(Reference Fritsche17) recently conducted a cross-study meta-regression dose–response analysis of the effect of dietary n-3 PUFA on the AA content of human, murine and rat immune cells, citing the accumulation of AA in tissues as a key factor in the biosynthesis of eicosanoids with pro-inflammatory activity. Baseline fatty acid profiles of human peripheral blood mononuclear cells and rat splenocytes appear to be remarkably similar in terms of AA content, while n-3 PUFA content is more variable. Rodent immune cells typically contain 15–20% AA as a proportion of total fatty acids, and very little EPA or DHA. Human immune cell phospholipids, on the other hand contain about 1% EPA and 2·5% DHA in addition to 20% AA(Reference Calder14, Reference Fritsche17). As the long chain n-3 PUFA content of the diet increases, lymphocyte AA decreases in a curvilinear fashion(Reference Fritsche17). In human studies, dietary n-3 PUFA never exceeded 3%, whereas in the animal studies the intake was considerably higher, but even when this is taken into account, it is apparent that rodent lymphocytes are much more responsive to the impact of n-3 PUFA on AA content than are human lymphocytes. n-3 PUFA do not appear to lower AA or enrich cell membranes with n-3 PUFA in human blood monocytes as much as in tissue macrophages from either rats or mice(Reference Fritsche17). Furthermore, murine lymphocytes, which already contain more DHA than rat or human lymphocytes, accumulate DHA more readily in response to dietary enrichment than these species(Reference Fritsche17). Fritsche(Reference Fritsche17) suggests that this may help explain the discrepancies that exist between animal and human studies investigating the immunomodulatory effects of n-3 PUFA. However, it remains unclear how much n-3 PUFA is required for biological effects in human subjects.

It is apparent from the literature that fish oil has a greater impact on immune function in the elderly compared with young subjects(Reference Thies, Miles and Nebe-von-Caron12, Reference Meydani, Endres and Woods18, Reference Thies, Nebe-von-Caron and Powell19). The mechanistic basis for this is not understood, but it is interesting to note that older subjects appear to incorporate EPA into plasma and peripheral blood mononuclear cells more readily than younger subjects(Reference Rees, Miles and Banerjee20). This was associated with a dose-dependent decrease in the neutrophil respiratory burst in older, but not younger subjects(Reference Rees, Miles and Banerjee20). However, PGE2 production by peripheral blood mononuclear cells was decreased in both groups and phagocytosis and cytokine production was not affected in either group(Reference Rees, Miles and Banerjee20). This highlights the fact that age is likely to be an important factor when considering the impact of n-3 PUFA on immunity, not only because of the influence of immunosenescence but also because immune cells from older subjects appear to be more responsive to the availability of n-3 PUFA. Recent work suggests that the cholesterol content of T-lymphocytes from healthy elderly subjects is higher than that of young subjects and that membrane fluidity is subsequently decreased(Reference Larbi, Douziech and Dupuis21). Furthermore, the coalescence of lipid rafts at the site of T-cell receptor engagement was impaired in elderly subjects(Reference Larbi, Douziech and Dupuis21, Reference Fulop, Larbi and Douziech22). The impact of ageing on lipid raft composition and function was most evident in the CD4+ T-cell population and affected cytokine signalling(Reference Fulop, Larbi and Douziech22, Reference Larbi, Dupuis and Khalil23). Thus, enriching T-cell membranes of older subjects with n-3 PUFA could modulate the immune function via effects on the lipid raft structure which are distinct from those in younger subjects.

Are lipid rafts responsible for the immunomodulatory effects of n-3 PUFA?

The lipid raft hypothesis suggests that there is a degree of self-organization within the cell membranes such that dynamic microenvironments are created within the exoplasmic leaflets of the phospholipid bilayer of plasma membranes to preferentially group transmembrane proteins according to their function(Reference Katagiri, Kiyokawa and Fujimoto24). These rafts have been proposed to serve as platforms to facilitate apical sorting, the association of signalling molecules and interactions between cell types(Reference Katagiri, Kiyokawa and Fujimoto24, Reference Harder, Scheiffele and Verkade25). Despite a large body of work, some doubts still persist regarding the existence and nature of lipid rafts(Reference Heerklotz26Reference Shaw29). These doubts have arisen mainly due to limitations in the interpretation of the methods available to study rafts. The most widely used technique is the preparation of detergent-resistant membranes which are suggested to represent raft domains, since they contain the glycosylphosphatidylinositol-anchored proteins, cholesterol and sphingolipids characteristic of lipid rafts. In support of this idea, the liquid-ordered phases rich in cholesterol and sphingolipids in artificial membranes are resistant to detergent extraction(Reference Schroeder, Ahmed and Zhu30). However, there is a possibility that detergent solubilization could induce non-physiological rearrangements in the bilayer structure, and in particular that the detergent could induce the formation of holes in the membrane, which allow mixing of the inner and outer leaflet and the appearance of cell-signalling proteins in detergent-resistant membrane fractions(Reference Heerklotz26, Reference Munro27). Thus, while in vitro studies using the detergent extraction procedure for isolation of lipid rafts have demonstrated that treatment with EPA at a concentration of 50 μm results in marked enrichment of both EPA and docosapentaenoic acid in lipids isolated from rafts and the subsequent displacement of acylated proteins(Reference Stulnig, Huber and Leitinger31). If raft formation and stability are based on interactions between saturated acyl chains and cholesterol, then the observations that PUFA incorporated into these detergent-resistant fractions is somewhat contrary to expectations. Although a limited number of animal studies support the role of lipid rafts in mediating the effects of PUFA on immune function, it is still largely unclear whether the displacement of key signalling proteins from putative lipid rafts and the down-regulation of signalling pathways by n-3 PUFA are physiological phenomena that could explain the immunomodulatory properties of fish oil in human subjects(Reference Calder32). Clearly, direct visualization of rafts would resolve uncertainties about their existence and structure, but fluorescence microscopy studies have tended to produce mixed results(Reference Munro27) and it is argued that rafts are too small to be resolved by conventional microscopy techniques(Reference Shaw29). The size, stability and functionality of putative membrane microdomains including rafts are therefore still very much in debate. It has been suggested that although some domains are macroscopic and stable for extended periods, others are tiny and unstable, existing only momentarily and as a result are very poorly understood(Reference Pike33, Reference Siddiqui, Harvey and Zaloga34). Kenworthy(Reference Kenworthy35) suggests that mechanistic models linking the microdomain structure and function are required to systematically evaluate how the structural and dynamic features of lipid rafts influence protein diffusion and reaction kinetics.

Both linoleic acid and DHA increased the clustering of a lipid raft probe compared with oleic acid and untreated cells, demonstrating that PUFA appear to specifically increase the clustering of proteins in cholesterol-dependent microdomains(Reference Chapkin, Seo and McMurray36). The authors suggest that the poor affinity of long-chain PUFA for cholesterol provides a lipid-driven mechanism for lateral phase separation of cholesterol-rich microdomains and alters the dynamic partitioning of acylated proteins(Reference Chapkin, Seo and McMurray36). Similarly, Shaikh and Edidin(Reference Shaikh and Edidin37, Reference Shaikh and Edidin38) suggest that phospholipids containing highly disordered polyunsaturated acyl chains that exhibit low affinity to cholesterol would be expected to phase separate from rafts. They further demonstrated that an oleic acid-containing phosphatidylethanolamine (PE) and a DHA-containing PE phase separated differently from the lipid raft molecules, sphingomyelin and cholesterol in monolayer and bilayer membranes(Reference Shaikh, Brzustowicz and Gustafson39, Reference Shaikh, Dumaual and Castillo40). The interactions between DHA-containing PE and cholesterol were less favourable, and as a result, these PE species were less likely to be found in detergent-resistant membrane fractions than oleic acid-containing PE(Reference Shaikh, Dumaual and Castillo40).

Membrane microdomains have been studied extensively with respect to T-lymphocyte responses to activation(Reference Katagiri, Kiyokawa and Fujimoto24, Reference Harder, Scheiffele and Verkade25, Reference Razzaq, Ozegbe and Jury41). There is visual evidence of clustering of signalling components at T-lymphocyte synapses using the non-toxic B subunit of cholera toxin, which binds the glycosphingolipid, GM1, a putative raft reporter(Reference Harder, Scheiffele and Verkade25). A novel approach whereby anti-T-cell receptor-coated microbeads were attached to T-cells and then stripped away, along with patches of membrane, has demonstrated the presence of the T-cell receptor and associated signalling molecules including linker for activation of T-cells, but there did not appear to be an increase in cholesterol, as might be expected on the basis of its presence in putative lipid rafts(Reference Harder42). The authors concluded that protein–protein interactions, rather than protein–lipid interactions, and subsequent clustering are the key features of signalling assemblies(Reference Harder and Kuhn43). This view is supported by Douglas and Vale(Reference Douglas and Vale44), who used sophisticated imaging techniques to track individual fluorescent proteins involved in T-cell receptor signalling to show that linker of activated T-cells mutants lacking residues specifically required for protein–protein interactions did not cluster. Other studies by the Harder group have used fluorescence techniques to show that condensation of the plasma membrane occurs at the T-cell receptor activation site, suggesting the formation of ordered lipid phases(Reference Gaus, Chklovskaia and Fazekas de St Groth45, Reference Gaus, Zech and Harder46). These studies used a dye, Laurdan, which is incorporated into the membrane and undergoes changes in its emission spectrum, corresponding to the level of lipid ordering, allowing quantification of the condensation(Reference Gaus, Chklovskaia and Fazekas de St Groth45, Reference Gaus, Zech and Harder46). In vitro treatment of Jurkat T-cells with EPA impaired membrane condensation of T-cell receptor activation sites, which was directly related to perturbation of the fatty acid composition of phospholipid species in the immuno-isolated membrane fractions(Reference Zech, Ejsing and Gaus47). This is the first study relating to PUFA modification of membrane domains which is not based on detergent extraction. Recently, fat-1 transgenic mice have been used to gain further insight into the impact of n-3 PUFA on lipid rafts in T-cells. These mice bear the Caenorhabditis elegans desaturase gene capable of converting n-6 PUFA into n-3 PUFA, resulting in substantially elevated levels of n-3 PUFA in tissues including T-cells. Kim et al.(Reference Kim, Fan and Barhoumi48) investigated the effect of this n-3 PUFA enrichment of lipid raft formation at the immunological synapse by co-culturing Laurdan-labelled CD4+ T-cells with anti-CD3 hybridoma cells (serving as antigen-presenting cells). They reported that raft formation was enhanced in the fat-1 cells compared to wild-type, but the relocalization of several signalling molecules into the immunological synapse and cell proliferation were suppressed(Reference Kim, Fan and Barhoumi48). The enhanced raft formation can be explained by the low affinity of DHA for cholesterol which effectively causes the coalescence of cholesterol-rich domains, consistent with immunogold data showing increased lipid raft clustering in response to DHA enrichment(Reference Kim, Fan and Barhoumi48, Reference Chapkin, McMurray and Dvaidson49). There is no information regarding the extent to which membrane microdomains in human lymphocytes are modulated by dietary supplementation with n-3 PUFA, although lymphocyte lipids (in a whole-cell extract) are readily modified by fish oil supplementation(Reference Kew, Mesa and Tricon50) and murine T-lymphocyte rafts have been shown to be responsive to dietary fish oil(Reference Geyeregger, Zeyda and Zlabinger51, Reference Switzer, Fan and Wang52). Interestingly, peripheral blood T-cells from patients with systemic lupus erythamatosus, an autoimmune disorder, contain higher levels of the ganglioside, GM1 and cholesterol, which may alter membrane organization and potentially create an impact on signalling homeostasis(Reference Kabouridis and Jury53). Higher levels of CD45 in lipid rafts in autoimmune lymphocytes have also been documented(Reference Kabouridis and Jury53). In an experimental model of colitis, n-3 PUFA prevented inflammation-induced exit of tight junction proteins from lipid rafts and decreased disruption of tight junctions in the intestinal mucosa(Reference Li, Zhang and Wang54). This suggests that the reported beneficial effects of n-3 PUFA in inflammatory bowel disease (and perhaps other inflammatory disorders), may be mediated, at least in part, through the modulation of membrane microdomains. Clearly, there is some compelling evidence from in vitro and animal experiments indicating that n-3 PUFA modulate the immune function by effects on membrane microdomains, yet direct evidence that this is physiologically relevant in human subjects is still lacking and should be considered for future research.

Fatty acid-derived mediators

Immune cell membranes typically have a high content of AA, which acts as a precursor for the synthesis of eicosanoids, the exact nature of which depends upon the cell type. It is well documented that the enrichment of cell membranes with EPA and DHA decreases the production of AA-derived eicosanoids, such as PGE2, in a dose-dependent fashion(Reference Rees, Miles and Banerjee20). Incorporation of n-3 PUFA also results in the generation of a wider range of eicosanoids, since these fatty acids can also act as precursors for cyclooxygenase and lipoxygenase enzymes. These n-3 PUFA-derived eicosanoids are often (but not always) biologically less active than those derived from AA(Reference Calder14). The transgenic fat-1 mice, which have tissue greatly enriched with n-3 PUFA, generate large amounts of PGE3 in the colonic tissue after the induction of inflammation by dextran sodium sulphate(Reference Hudert, Weylandt and Lu55). The full extent of the number and nature of eicosanoids has not yet been realized, as evidenced by the increasing number of EPA- and DHA-derived eicosanoids which have been shown to be produced under physiological or pathological conditions and to have anti-inflammatory activities(Reference Serhan56). These include the emerging family of lipoxins, resolvins, protectins and most recently maresins, which appear to have important roles in the resolution of inflammation and return to homeostasis(Reference Serhan, Yang and Martinod57). A recent study demonstrated that deuterium-labelled or radioactively labelled n-3 PUFA could be identified in inflammatory exudates in a murine model of peritonitis within 2 h of induction(Reference Kasuga, Yang and Porter58). However, since DHA-derived resolvin D1, but not DHA itself, inhibited neutrophil movement and protected lung tissue from excessive leucocyte infiltration, the authors concluded that the resolution of inflammation required conversion to resolvins(Reference Kasuga, Yang and Porter58).

Conclusion

Recent studies have focused on the central role of fatty acids in immune cell regulation, highlighting the fact that their location and organization within cellular lipids has a direct influence on the behaviour of a number of proteins involved in immune cell activation and on fatty acid-derived inflammatory mediator production. Key areas for future work include further characterization of the impact of n-3 PUFA on lipid raft structure and composition, extrapolation of in vitro lipid raft data to human dietary studies and further characterization of novel eicosanoid pathways involved in the resolution of inflammatory responses.

Acknowledgement

The author declares no conflict of interest.

References

1.Calder, PC & Burdge, GC (2004) Fatty acids. In Bioactive Lipids, pp. 136 [Nicolaou, A and Kokotos, G, editors]. Bridgewater: The Oily Press.Google Scholar
2.Lewis, RA, Austen, KF & Soberman, RJ (1990) Leukotrienes and other products of the 5-lipoxygenase pathway: biochemistry and relation to pathobiology in human diseases. New Engl J Med 323, 645655.Google ScholarPubMed
3.Tilley, SL, Coffman, TM & Koller, BH (2001) Mixed messages: modulation of inflammation and immune responses by prostaglandins and thromboxanes. J Clin Invest 108, 1523.CrossRefGoogle Scholar
4.Vachier, I, Chanez, P, Bonnans, C et al. (2002) Endogenous anti-inflammatory mediators from arachidonate in human neutrophils. Biochem Biophys Res Commun 290, 219224.CrossRefGoogle ScholarPubMed
5.Serhan, CN, Arita, M, Hong, S et al. (2004) Resolvins, docosatrienes, and neuroprotectins, novel omega-3-derived mediators, and their endogenous aspirin-triggered epimers. Lipids 39, 11251132.CrossRefGoogle ScholarPubMed
6.Calder, PC (2006) N-3 polyunsaturated fatty acids, inflammation, and inflammatory diseases. Am J Clin Nutr 83, 1505S1519S.CrossRefGoogle ScholarPubMed
7.Yaqoob, P & Calder, PC (2007) Fatty acids and immune function: new insights into mechanisms. Br J Nutr 98, S41S45.CrossRefGoogle ScholarPubMed
8.Grimble, RF, Howell, WM, O'Reilly, G et al. (2002) The ability of fish oil to suppress tumour necrosis factor a production by peripheral blood mononuclear cells in healthy men is associated with polymorphisms in genes that influence tumour necrosis factor α production. Am J Clin Nutr 76, 454459.CrossRefGoogle Scholar
9.Calder, PC (2001) Polyunsaturated fatty acids, inflammation and immunity. Lipids 36, 10071024.CrossRefGoogle ScholarPubMed
10.Mantzioris, E, Cleland, LG, Gibson, RA et al. (2000) Biochemical effects of a diet containing foods enriched with n-3 fatty acids. Am J Clin Nutr 72, 4248.CrossRefGoogle ScholarPubMed
11.Caughey, GE, Mantzioris, E, Gibson, RA et al. (1996) The effect on human tumour necrosis factor α and interleukin 1β production of diets enriched in n-3 fatty acids from vegetable oil or fish oil. Am J Clin Nutr 63, 116122.CrossRefGoogle ScholarPubMed
12.Thies, F, Miles, EA, Nebe-von-Caron, G et al. (2001) Influence of dietary supplementation with long-chain n-3 or n-6 polyunsaturated fatty acids on blood inflammatory cell populations and functions and on plasma soluble adhesion molecules in healthy adults. Lipids 36, 11831193.CrossRefGoogle ScholarPubMed
13.Yaqoob, P & Calder, PC (2007) Lipid rafts-composition, characterization, and controversies. J Nutr 137, 548553.Google Scholar
14.Calder, PC (2008) The relationship between the fatty acid composition of immune cells and their function. Prostaglandins Leukot Essent Fatty Acids 79, 101108.CrossRefGoogle ScholarPubMed
15.Kew, S, Banerjee, T, Minihane, AM et al. (2003) Relation between the fatty acid composition of peripheral blood mononuclear and measures of immune cell function in healthy, free-living subjects aged 25–72 yr. Am J Clin Nutr 77, 12781286.CrossRefGoogle Scholar
16.Kew, S, Banerjee, T, Minihane, AM et al. (2003) Lack of effect of foods enriched with plant- or marine-derived n-3 fatty acids on human immune function. Am J Clin Nutr 77, 12871295.CrossRefGoogle ScholarPubMed
17.Fritsche, K (2007) Important differences exist in the dose-response relationship between diet and immune cell fatty acids in human subjects and rodents. Lipids 42, 961979.CrossRefGoogle Scholar
18.Meydani, SN, Endres, S, Woods, NM et al. (1991) Oral n-3- fatty acid supplementation suppresses cytokine production and lymphocyte proliferation- comparison between young and older women. J Nutr 121, 547555.CrossRefGoogle Scholar
19.Thies, F, Nebe-von-Caron, G, Powell, JR et al. (2001) Dietary supplementation with eicosapentaenoic acid, but not with other long-chain n-3 or n-6 polyunsaturated fatty acids, decreases natural killer cell activity in healthy subjects aged >55 y. Am J Clin Nutr 73, 539548.CrossRefGoogle ScholarPubMed
20.Rees, D, Miles, EA, Banerjee, T et al. (2006) Dose-related effects of eicosapentaenoic acid on innate immune function in healthy human subjects: a comparison of young and older men. Am J Clin Nutr 83, 331342.CrossRefGoogle Scholar
21.Larbi, A, Douziech, N, Dupuis, G et al. (2004) Age-associated alterations in the recruitment of signal-transduction proteins to lipid rafts in human T lymphocytes. J Leukoc Biol 75, 373381.CrossRefGoogle ScholarPubMed
22.Fulop, T, Larbi, A, Douziech, N et al. (2006) Cytokine receptor signaling and aging. Mech Ageing Dev 127, 526537.CrossRefGoogle ScholarPubMed
23.Larbi, A, Dupuis, G, Khalil, A et al. (2006) Differential role of lipid rafts in the functions of CD4+ and CD8+ human T lymphocytes with aging. Cell Signal 18, 10171030.CrossRefGoogle Scholar
24.Katagiri, YU, Kiyokawa, N, Fujimoto, J (2001) A role for lipid rafts in immune cell signaling. Microbiol Immunol 45, 18.CrossRefGoogle ScholarPubMed
25.Harder, T, Scheiffele, P, Verkade, P et al. (1998) Lipid domain structure of the plasma membrane revealed by patching of membrane components. J Cell Biol 141, 929942.CrossRefGoogle ScholarPubMed
26.Heerklotz, H (2002) Triton promotes domain formation in lipid raft mixtures. Biophys J 83, 26932701.CrossRefGoogle ScholarPubMed
27.Munro, S (2003) Lipid rafts: Elusive or Illusive? Cell 115, 377388.CrossRefGoogle ScholarPubMed
28.Nichols, B (2005) Cell biology without a raft. Nature 436, 638639.CrossRefGoogle ScholarPubMed
29.Shaw, AS (2006) Lipid rafts: now you see them, now you don't. Nat Immunol 7, 11391142.CrossRefGoogle ScholarPubMed
30.Schroeder, RJ, Ahmed, SN, Zhu, Y et al. (1998) Cholesterol and sphingolipid enhance the Triton X-100 insolubility of glycosylphosphatidylinositol-anchored proteins by promoting the formation of detergent-insoluble ordered membrane domains. J Biol Chem 273, 11501157.CrossRefGoogle ScholarPubMed
31.Stulnig, TM, Huber, J, Leitinger, N et al. (2001) Polyunsaturated eicosapentaenoic acid displaces proteins from membrane rafts by altering raft lipid composition. J Biol Chem 276, 3733537340.CrossRefGoogle ScholarPubMed
32.Calder, PC. Immunomodulation by omega-3 fatty acids. Prostaglandins Leukot Essent Fatty Acids 77, 327335.CrossRefGoogle Scholar
33.Pike, LJ (2003) Lipid rafts: bringing order to chaos. J Lipid Res 44, 655667.CrossRefGoogle ScholarPubMed
34.Siddiqui, RA, Harvey, KA, Zaloga, GP et al. (2007) Modulation of lipid rafts by ω-3 fatty acids in inflammation and cancer: implications for use of lipids during nutritional support. Nutr Clin Pract 22, 7488.CrossRefGoogle Scholar
35.Kenworthy, AK (2008) Have we become overly reliant on lipid rafts? EMBO Rep 9, 531535.CrossRefGoogle ScholarPubMed
36.Chapkin, RS, Seo, J, McMurray, DN et al. (2008) Mechanisms by which docosahexaenoic acid and related fatty acids reduce colon cancer risk and inflammatory disorders of the intestine. Chem Phys Lipids 153, 1423.CrossRefGoogle ScholarPubMed
37.Shaikh, SR & Edidin, M (2006) Polyunsaturated fatty acids, membrane organization, T cells and antigen presentation. Am J Clin Nutr 84, 12771289.CrossRefGoogle ScholarPubMed
38.Shaikh, SR & Edidin, M (2008) Polyunsaturated fatty acids and membrane organization: elucidating mechanisms to balance immunotherapy and susceptibility to infection. Chem Phys Lipids 153, 2433.CrossRefGoogle ScholarPubMed
39.Shaikh, SR, Brzustowicz, MR, Gustafson, N et al. (2002) Monounsaturated PE does not phase-separate from lipid raft molecules sphingomyelin and cholesterol: role for polyunsaturation? Biochemistry 41, 1059310602.CrossRefGoogle Scholar
40.Shaikh, SR, Dumaual, AC, Castillo, A et al. (2004) Oleic and docosahexaenoic acid differentially phase separate from lipid raft molecules: a comparative NMR, DSC, AFM and detergent extraction study. Biophys J 87, 17521766.CrossRefGoogle ScholarPubMed
41.Razzaq, TM, Ozegbe, P, Jury, EC et al. (2004) Regulation of T cell receptor signalling by membrane microdomains. Immunology 113, 413426.CrossRefGoogle ScholarPubMed
42.Harder, T (2004) Lipid raft domains and protein networks in T cell receptor signal transduction. Curr Opin Immunol 16, 353359.CrossRefGoogle ScholarPubMed
43.Harder, T & Kuhn, M (2000) Selective accumulation of raft-associated membrane protein LAT in T cell receptor signaling assemblies. J Cell Biol 151, 199207.CrossRefGoogle Scholar
44.Douglas, AD & Vale, RD (2005) Single-molecule microscopy reveals plasma membrane microdomains created by protein-protein networks that exclude or trap signaling molecules in T cells. Cell 121, 937950.CrossRefGoogle Scholar
45.Gaus, K, Chklovskaia, E, Fazekas de St Groth, B et al. (2005) Condensation of the plasma membrane at the site of T lymphocyte activation. J Cell Biol 171, 121131.CrossRefGoogle ScholarPubMed
46.Gaus, K, Zech, T & Harder, T (2006) Visualizing membrane microdomains by Laurdan 2-photon microscopy. Mol Membr Biol 23, 4148.CrossRefGoogle ScholarPubMed
47.Zech, T, Ejsing, CS, Gaus, K et al. (2009) Accumulation of raft lipids in T cell plasma membrane domains engaged in TCR signaling. EMBO J 28, 466476.CrossRefGoogle Scholar
48.Kim, K, Fan, Y-Y, Barhoumi, R et al. (2008) N-3 Polyunsaturated fatty acids suppress the localization and activation of signaling proteins at the immunological synapse in murine CD4+ T cells by affecting lipid raft formation. J Immunol 181, 62366243.CrossRefGoogle ScholarPubMed
49.Chapkin, RS, McMurray, DN, Dvaidson, LA et al. (2008) Bioactive dietary long-chain fatty acids: emerging mechanisms of action. Br J Nutr 100, 11521157.CrossRefGoogle ScholarPubMed
50.Kew, S, Mesa, MD, Tricon, S et al. (2004) Effects of eicosapentaenoic and docosahexaenoic acid-rich oils on immune cell composition and function in healthy human subjects. Am J Clin Nutr 79, 674681.CrossRefGoogle Scholar
51.Geyeregger, R, Zeyda, M, Zlabinger, GJ et al. (2005) Polyunsaturated fatty acids interfere with formation of the immunological synapse. J Leukoc Biol 77, 680688.CrossRefGoogle ScholarPubMed
52.Switzer, KC, Fan, YY, Wang, NY et al. (2004) Dietary n-3 polyunsaturated fatty acids promote activation-induced cell death in Th1-polarized murine CD4+ T cells. J Lipid Res 45, 14821492.CrossRefGoogle ScholarPubMed
53.Kabouridis, PS & Jury, ES (2008) Lipid rafts and T-lymphocyte function: Implications for autoimmunity. FEBS Lett 582, 37113718.CrossRefGoogle ScholarPubMed
54.Li, Q, Zhang, Q, Wang, C et al. (2008) Effect of n-3 polyunsaturated fatty acids on membrane microdomain localization of tight junction proteins in experimental colitis. FEBS J 275, 411420.CrossRefGoogle Scholar
55.Hudert, CA, Weylandt, KH, Lu, J et al. (2003) Transgenic mice rich in endogenous omega-3 fatty acids are protected from colitis. Proc Natl Acad Sci USA 103, 1127611281.CrossRefGoogle Scholar
56.Serhan, CN (2009) Systems approach to inflammation resolution: identification of novel anti-inflammatory and pro-resolving mediators. J Thromb Haemost 7, 4448.CrossRefGoogle ScholarPubMed
57.Serhan, CN, Yang, YR, Martinod, K et al. (2009) Maresins: novel macrophage mediators with potent anti-inflammatory and pro-resolving actions. J Exp Med 206, 1523.CrossRefGoogle Scholar
58.Kasuga, K, Yang, R, Porter, TF et al. (2008) Rapid appearance of resolving precursors in inflammatory exudates: novel mechanisms in resolution. J Immunol 181, 86778687.CrossRefGoogle Scholar