Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-23T15:30:40.547Z Has data issue: false hasContentIssue false

Influence of a high-fat diet on gut microbiota, intestinal permeability and metabolic endotoxaemia

Published online by Cambridge University Press:  16 April 2012

Ana Paula Boroni Moreira*
Affiliation:
Nutrition and Health Department, Federal University of Viçosa, Minas Gerais, Avenida PH Rolfs, s/n, CEP 36570-000, Viçosa, MinasGerais, Brazil
Tatiana Fiche Salles Texeira
Affiliation:
Nutrition and Health Department, Federal University of Viçosa, Minas Gerais, Avenida PH Rolfs, s/n, CEP 36570-000, Viçosa, MinasGerais, Brazil
Alessandra Barbosa Ferreira
Affiliation:
Nutrition and Health Department, Federal University of Viçosa, Minas Gerais, Avenida PH Rolfs, s/n, CEP 36570-000, Viçosa, MinasGerais, Brazil
Maria do Carmo Gouveia Peluzio
Affiliation:
Nutrition and Health Department, Federal University of Viçosa, Minas Gerais, Avenida PH Rolfs, s/n, CEP 36570-000, Viçosa, MinasGerais, Brazil
Rita de Cássia Gonçalves Alfenas
Affiliation:
Nutrition and Health Department, Federal University of Viçosa, Minas Gerais, Avenida PH Rolfs, s/n, CEP 36570-000, Viçosa, MinasGerais, Brazil
*
*Corresponding author: A. P. B. Moreira, fax +55 31 38992541, email [email protected]; [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Lipopolysaccharide (LPS) may play an important role in chronic diseases through the activation of inflammatory responses. The type of diet consumed is of major concern for the prevention and treatment of these diseases. Evidence from animal and human studies has shown that LPS can diffuse from the gut to the circulatory system in response to the intake of high amounts of fat. The method by which LPS move into the circulatory system is either through direct diffusion due to intestinal paracellular permeability or through absorption by enterocytes during chylomicron secretion. Considering the impact of metabolic diseases on public health and the association between these diseases and the levels of LPS in the circulatory system, this review will mainly discuss the current knowledge about high-fat diets and subclinical inflammation. It will also describe the new evidence that correlates gut microbiota, intestinal permeability and alkaline phosphatase activity with increased blood LPS levels and the biological effects of this increase, such as insulin resistance. Although the majority of the studies published so far have assessed the effects of dietary fat, additional studies are necessary to deepen the understanding of how the amount, the quality and the structure of the fat may affect endotoxaemia. The potential of food combinations to reduce the negative effects of fat intake should also be considered in future studies. In these studies, the effects of flavonoids, prebiotics and probiotics on endotoxaemia should be investigated. Thus, it is essential to identify dietetic strategies capable of minimising endotoxaemia and its postprandial inflammatory effects.

Type
Review Article
Copyright
Copyright © The Authors 2012

The role of gut microbiota in the development of diseases such as obesity(Reference Cani and Delzenne1), diabetes(Reference Larsen, Vogensen and van den Berg2) and atherosclerosis(Reference Caesar, Fåk and Bäckhed3) has received increased attention from researchers worldwide. These diseases share a common mechanism because the activation of the immune system leads to greater inflammation(Reference Herder, Schneitler and Rathmann4Reference Libby, Ridker and Maseri9). Components originating from gut microbiota, such as lipopolysaccharide (LPS), lipoteichoic acid, peptidoglycan, flagellin and bacterial DNA, can cause immune system activation. LPS is thought to be a major inducer of the inflammatory response, suggesting a possible association between intestinal LPS and these metabolic diseases(Reference Cani, Neyrinck and Fava10Reference Wiedermann, Kiechl and Dunzendorfer13).

LPS is one of the main components of the external cell wall of Gram-negative bacteria. Therefore, the gut microbiota is a huge reservoir of this endotoxin(Reference Elin and Wolff14). There are 1012 bacterial cells in each gram of faeces(Reference Hattori and Taylor15). Consequently, it is possible to detect more than 1 g of LPS in the intestinal lumen(Reference Brun, Castagliuolo and Leo16, Reference Berg17). Under normal conditions, the presence of LPS in the intestinal lumen does not cause negative health effects(Reference Bayston and Cohen18). However, some factors can favour the transfer of LPS into the circulatory system. It has been suggested that the type of diet consumed, especially high-fat diets, can contribute to endotoxaemia, which is caused by elevated LPS levels in blood plasma(Reference Laugerette, Vors and Geloen19).

Thus, considering the impact of metabolic diseases on public health and the association between these diseases and the levels of LPS in the circulatory system, this review will focus on the current understanding of high-fat diets and subclinical inflammation and the new evidence that correlates gut microbiota and intestinal permeability alterations with the increase in blood LPS levels and its biological effects.

Methods

Medline/PubMed, Scielo and Lilacs were searched using the following terms: lipids, high-fat diet, LPS, endotoxins, metabolic endotoxaemia, inflammation, intestinal or gut permeability, gut microbiota, chronic diseases, alkaline phosphatase, pro-inflammatory cytokines, obesity, diabetes, atherosclerosis and inflammatory mediators. For data searches, the terms in English, Spanish and Portuguese were used either alone or in association. Review and original articles were selected according to their titles and abstracts. Each selected manuscript was then studied critically.

The role of diet in the transfer of lipopolysaccharide to the circulatory system

It was once believed that the movement of LPS from the intestinal lumen to the circulatory system would be effectively inhibited by the intestinal epithelia, such that LPS would be present in the circulation only in diseased states. However, LPS has been detected even in the blood of healthy animals(Reference Ghoshal, Witta and Zhong20) and in the plasma of healthy human subjects at low concentrations (between 1 and 200 pg/ml)(Reference Laugerette, Vors and Geloen19, Reference Ghanim, Sia and Upadhyay21, Reference Erridge, Attina and Spickett22), suggesting that small amounts of LPS are constantly passing through the intestines. The biological relevance of low circulatory levels of LPS seems to be related to immune modulation. The increase in phagocytic capacity, lymphocyte proliferation and the secretion of lymphokines are some effects of the stimulation of the immune system by LPS. The level of mediators produced by the activated cells determines the beneficial effects, such as resistance to infections, or the negative effects, such as increased inflammation(Reference Heine, Rietschel and Ulmer23, Reference Rietschel, Kirikae and Schade24).

The greater inflammation observed in individuals with metabolic diseases(Reference Herder, Schneitler and Rathmann4Reference Libby, Ridker and Maseri9) could be a consequence of the excessive production of mediators by immune cells stimulated by LPS. Patients with obesity, diabetes, CVD and non-alcoholic steatohepatitis have higher circulating LPS levels than healthy individuals(Reference Pussinen, Havulinna and Lehto25Reference Creely, McTernan and Kusminski29). Diet has been shown to play a role in increasing circulatory LPS levels(Reference Laugerette, Vors and Geloen19, Reference Ghanim, Sia and Upadhyay21, Reference De Bandt, Waligora-Dupriet and Butel30, Reference Laparra and Sanz31). Excessive fat intake may favour an increase in circulatory LPS, leading to metabolic endotoxaemia(Reference Cani, Neyrinck and Fava10, Reference Erridge, Attina and Spickett22, Reference Delzenne and Cani32Reference Amar, Burcelin and Ruidavets35). Therefore, excessive fat intake is considered to be one of the triggering factors that increase LPS in the circulatory system.

The oral administration of oil or water to mice confirmed the role of fat intake in LPS movement into the circulatory system; increases in plasma LPS levels were observed only after the ingestion of oil. The higher the fat content of a diet was, the higher the increase in plasma LPS levels(Reference Cani, Amar and Iglesias11). Healthy men presented postprandial increases in LPS levels after consumption of high-fat meals (33 and 50 g) when compared to those who fasted(Reference Laugerette, Vors and Geloen19, Reference Erridge, Attina and Spickett22). Because LPS contain an insoluble fraction (lipid A) in their molecular structure(Reference Raetz and Whitfield36), they can be incorporated into micelles and absorbed and aggregated into the chylomicrons in the postprandial period(Reference Ghoshal, Witta and Zhong20, Reference Vreugdenhil, Rousseau and Hartung37).

The transport of LPS by chylomicrons may confer a physiological advantage because it favours hepatic clearance of LPS, reducing LPS toxicity(Reference Manco, Putignani and Bottazzo38, Reference Harris, Grunfeld and Feingold39). However, excessive chylomicron formation induced by the consumption of high-fat diets can lead to prolonged chylomicronaemia, increasing the chances of extra-hepatic exposure to LPS(Reference Ghoshal, Witta and Zhong20). Chylomicrons are secreted into the intercellular space and they must reach the lamina propria and lymphatic vessels before entering the systemic circulation. In this process, an accumulation of chylomicrons in the intercellular space due to a high-fat diet may increase the local pressure and cause the loosening of junctional complexes between the enterocytes(Reference Salim and Soderholm40, Reference Shen, Su and Turner41) or even basal membrane rupture(Reference Tso and Balint42). It has been demonstrated that during fat absorption, the intestinal epithelium becomes temporarily injured and is repaired approximately 50 min later(Reference Kvietys, Specian and Grisham43). After injury, the gut barrier can become compromised, increasing intestinal permeability, especially through the paracellular space, to molecules of higher molecular weight, such as LPS.

Higher fat intake has also been shown to increase intestinal permeability in obese rodents(Reference Cani, Bibiloni and Knauf44). Dietary fat can indirectly affect intestinal permeability through the activation of mast cells in the intestinal mucosa(Reference Ji, Sakata and Tso45). Mast cells are directly related to the regulation of transcellular and paracellular intestinal permeability through the secretion of mediators, such as TNF-α, IL-1β, IL-4 and IL-13 as well as tryptase via protease activation receptor-2(Reference Keita and Derholm46), which in turn favour LPS translocation. TNF-α levels, for example, can increase as a result of myosin light-chain kinase phosphorylation, leading to cytoskeletal contraction and possibly tight junction rupture(Reference Turner47). Reduced expression of proteins in tight junctions, such as claudin-1, claudin-3, occludin and junctional adhesion molecule-1, has also been observed in the intestinal mucosa of animals fed high-fat diets(Reference de La Serre, Ellis and Lee48, Reference Suzuki and Hara49).

High-fat diets (49·5 % lipids) also induce changes in the composition of gut microbiota, including the reduction in Bifidobacterium spp. and Eubacterium rectaleClostridium coccoides (Gram-positive bacteria) as well as Bacteroides (Gram-negative bacteria). A negative correlation between Bifidobacterium spp. and plasma LPS levels has been observed, and an increase in bifidobacteria induced by prebiotic intake reduces endotoxaemia(Reference Cani, Neyrinck and Fava10). Bifidobacteria can reduce the levels of endotoxins by improving gut barrier function(Reference Cani, Possemiers and Van de Wiele50Reference Griffiths, Duffy and Schanbacher53). These bacteria do not degrade mucus glycoproteins, as some pathogenic bacteria do; they instead promote a stable environment, inhibiting the translocation of bacteria and toxins(Reference Cani, Possemiers and Van de Wiele50, Reference Ruseler-van Embden, van Lieshout and Gosselink54). In contrast, increasing the proportion of Gram-negative bacteria can decrease the integrity of the intestinal mucosa and lead to higher levels of plasma LPS(Reference Cani, Amar and Iglesias11). The administration of antibiotics to mice fed high-fat diets resulted in changes in gut microbiota composition accompanied by recovery of the integrity of the intestinal epithelia (higher zonulin expression), reduction in metabolic endotoxaemia and reduction in the caecal levels of LPS(Reference Cani, Bibiloni and Knauf44). These results suggest that changes in the composition of gut microbiota can modulate intestinal permeability and endotoxaemia, even when a high-fat diet is consumed.

High-fat diets can induce changes in gut microbiota without necessarily being associated with obesity. Caecal samples obtained from rats fed high- or low-fat diets for 8 weeks were analysed. Not all animals receiving the high-fat diet became obese after 8 weeks, but all the animals eating the high-fat diet showed reductions in the total number of bacteria and increases in the relative proportion of Bacteroidales and Clostridiales in comparison with the ones that consumed the low-fat diet(Reference de La Serre, Ellis and Lee48). These results suggest that excessive fat intake leads to changes in the composition of microbiota without necessarily causing obesity. The differences between obesity-prone and obesity-resistant animals were related to an intestinal enzyme, alkaline phosphatase, which will be discussed later.

Another consequence of the consumption of high-fat diets is the increased production of bile observed in both obese and lean animals(Reference Suzuki and Hara49). There is evidence to suggest a relationship between bile secretion, microbiota in the small intestine, increased intestinal permeability and endotoxin production. The majority of gut microbiota are mainly located in the caecum or large intestine. The microbiota in the small intestine is less abundant and is usually limited as a source of LPS due to the presence of bile. Bile represents a major challenge to the survival and colonisation of the gastrointestinal tract by micro-organisms. The presence of IgA and mucus, which are secreted into the bile to prevent bacterial growth, and the detergent property of bile acids confer potent antimicrobial properties on bile. However, it is evident that certain bacteria have evolved to resist these antibiotic elements, and pathogens can even use bile to regulate virulence factors(Reference Begley, Gahan and Hill55).

Small-intestinal bacterial overgrowth (SIBO) represents alteration in the local microbiota and is characterised by an increased number of bacteria in the proximal small bowel (10Reference Stoll and Bendszus5 colony-forming units/ml) or the presence of a lower count of bacteria (>103 colony-forming units/ml), but with a profile of species isolated in the jejunal aspirate that is typical of micro-organisms that normally colonise the large bowel(Reference Quigley and Quera56). SIBO has been detected in obese individuals(Reference Sabaté, Jouët and Harnois57), suggesting that the increased circulatory levels of LPS in response to high-fat diet-induced chylomicronaemia might reflect changes in the microbiota of the small intestine.

The chemical structure of bile acid and its concentration might affect the biological effects of bile. Bile acids in the conjugated form are necessary for the absorption of dietary fats and have been suggested to repress bacterial growth in the small intestine through direct antimicrobial effects and up-regulation of host mucosal defences(Reference Jones, Begley and Hill58). Bile also reduces the permeation of endotoxin by binding it to micelles in vitro (Reference Parlesak, Schaeckeler and Moser59). Decreased conjugated bile acid secretion or increased deconjugation reduces the bacteriostatic properties of bile, allowing bacterial growth, which in turn leads to more deconjugation and, ultimately, to bacterial translocation and endotoxaemia(Reference Lorenzo-Zúñiga, Bartolí and Planas60). Endotoxaemia can also reflect a direct effect of bile on intestinal permeability. The mechanisms underlying the multifaceted effects of bile acids on the modulation of tight junctions are under investigation(Reference Raimondi, Santoro and Barone61). Exposure of Caco-2 cells to bile juice increased permeability through different mechanisms: decreased protein expression in tight junctions(Reference Suzuki and Hara49), occludin dephosphorylation(Reference Raimondi, Santoro and Barone61) and reduction of transepithelial electrical resistance through the generation of reactive oxygen species (ROS)(Reference Araki, Katoh and Ogawa62). The influence of a high-fat diet on the quantity and composition of bile in human or animal models of obesity, and how it affects the composition of microbiota and intestinal permeability, should be further investigated.

Chronic high-fat diets can affect the composition of gut microbiota, increase the incorporation of LPS into chylomicrons and compromise gut mucosal integrity, which can result in the entry of pathogenic agents from the intestinal lumen into the blood stream(Reference Cani, Neyrinck and Fava10, Reference Delzenne and Cani32, Reference Ji, Sakata and Tso45). The role of dietary fat in metabolic endotoxaemia is of major concern, and it may partly explain the high prevalence of chronic diseases in Western countries(Reference Musso, Gambino and Cassader63, Reference Cordain, Eaton and Sebastian64).

Inflammation and insulin resistance as a result of the biological effects of lipopolysaccharide

Insulin signalling is a very complex process that involves multiple pathways and cascades of phosphorylation events. Interference with these signalling pathways can alter insulin action and lead to the development of insulin resistance(Reference Hotamisligil65). One of the metabolically relevant sites of insulin resistance is white adipose tissue. The hypertrophy of adipocytes and infiltration of macrophages into white adipose tissue can culminate in a higher production of pro-inflammatory cytokines, such as TNF-α and IL-6, through the activation of intracellular signalling pathways involving NF-κB and Jun NH2-terminal kinase (JNK) systems(Reference Bastard, Maachi and Lagathu66). Cytokines such as TNF-α can blunt the proper transmission of the insulin signal by altering the pattern of insulin-receptor substrate proteins phosphorylation(Reference Hotamisligil65), and LPS can also interfere with the insulin signalling pathways.

The LPS molecule is structurally divided into three parts: lipid A, the oligosaccharide core and the O-antigen(Reference Raetz and Whitfield36). Lipid A is the portion of the LPS molecule that is responsible for endotoxicity. The recognition of an LPS molecule by Toll-like receptor-4 (TLR4) is mediated by the LPS-binding protein, the CD14 co-receptor of TLR4 and the myeloid differentiation protein-2. CD14 is present in soluble form (sCD14), which is derived from both the secretion of CD14 and the enzymatic cleavage of the membrane form of CD14. TLR4 is present on the membrane surface of immune cells (monocytes, macrophages, Kupffer cells) and other cells (adipocytes, hepatocyte, endothelial cells). Upon recognition of LPS, TLR4 undergoes oligomerisation and recruits its downstream adaptor molecules, TIR domain-containing adapter-inducing interferon-β (TRIF) and myeloid differentiation primary response gene 88 (MyD88), into lipid rafts of the membrane, leading to the activation of downstream signalling pathways, such as NF-κB and mitogen-activated protein kinase (MAPK), which can lead to inflammation(Reference Manco, Putignani and Bottazzo38, Reference Cani and Delzenne67, Reference Grimaldi, Donnarumma and Perfetto68). The translocation of NF-κB to the nucleus promotes the activation of genes that codify proteins involved in the inflammatory response, such as TNF-α, IL-6, inducible NO synthase and monocyte chemotactic protein-1(Reference Song, Kim and Yoon69). The signalling pathways activated by MAPK include JNK, p38 MAPK and extracellular signal-regulated kinases that can induce insulin resistance via different mechanisms(Reference Manco, Putignani and Bottazzo38, Reference Moreira and Alfenas70Reference Pan72).

Chronic and systemic exposure to slightly increased LPS levels is relevant for the manifestation of many diseases because it induces an immune response and activates signalling pathways that culminate with a subclinical inflammatory status, inhibiting proper insulin signalling and leading to insulin resistance. Insulin resistance is an important component in the pathophysiology of diseases like obesity, type 2 diabetes mellitus and related co-morbidities, such as hypertension, non-alcoholic fatty liver, cancer, and cardiovascular and renal diseases(Reference Manco, Putignani and Bottazzo38, Reference Ding and Lund73Reference Shanik, Xu and Skrha76).

The chronic administration of very low doses of LPS to wild-type mice results in the development of subclinical inflammation, which is followed by increases in body and liver weight, increases in the subcutaneous and visceral adipose tissue and increases in fasting and postprandial blood glucose levels(Reference Cani, Amar and Iglesias11). In human subjects, acute administration of LPS disturbs insulin sensitivity(Reference Dandona, Ghanim and Bandyopadhyay77Reference Agwunobi, Reid and Maycock79).

There is a network of factors that, in addition to the action of LPS, contributes to the development of insulin resistance, such as elevated plasma levels of NEFA and mitochondrial dysfunction(Reference Chow, From and Seaquist80Reference Kovacs and Stumvoll82) and hormone levels (reduced adiponectin or leptin resistance)(Reference Bastard, Maachi and Lagathu66). The role of microbiota and molecular patterns associated with microbes may add more complexity to this network, not necessarily as a cause but as a key actor in the relationship between diet and host. The metabolism of phospholipid (phosphatidylcholine) by microbiota results in the production of a metabolite (trimethylamine N-oxide), which has been shown to increase the pro-atherogenic phenotype, while the suppression of microbiota by the use of antibiotics inhibits the progression of atherosclerosis and the production of this metabolite(Reference Wang, Klipfell and Bennett83). In another animal model of atherosclerosis, the interaction between genetic susceptibility, diet (high-fat diet) and infectious agents illustrates that microbial elements are not the cause of atherosclerotic lesions; instead, they accelerate the progression of the disease in a susceptible host but not necessarily in combination with a high-fat diet(Reference Li, Messas and Batista84). This might also be the case with insulin resistance; LPS may add stronger inflammatory stimuli to a diet and genetic background that are already unfavourable.

Intestinal alkaline phosphatase: a possible therapeutic target

LPS clearance is fundamental to the attenuation of its negative consequences. The liver is the main organ responsible for the removal of LPS from the circulation. The majority of systemic LPS are taken up by the Kupffer cells in the liver and most probably by the endothelial cells as well. The Kupffer cells modify the endocytosed LPS to neutralise its endotoxic activity, passing it to the hepatocytes, which subsequently excrete it into the bile. Some LPS is also removed directly by hepatocytes mediated by lipoproteins(Reference Manco, Putignani and Bottazzo38, Reference Tuin, Huizinga-Van der Vlag and van Loenen-Weemaes85).

Another important mechanism is the dephosphorylation of LPS by the enzyme alkaline phosphatase, which induces a 100-fold reduction in lipid A toxicity(Reference Bates, Akerlund and Mittge86, Reference Schromm, Brandenburg and Loppnow87). In the liver, there is an increase in the expression of this enzyme after LPS injection(Reference Tuin, Huizinga-Van der Vlag and van Loenen-Weemaes85). The activity of this enzyme is high in enterocyte membranes, where the enzyme also helps to protect against bacterial translocation and regulates duodenal pH and fat absorption(Reference Lallès88, Reference Goldberg, Austen and Zhang89). A decrease in intestinal alkaline phosphatase activity may decrease LPS degradation and increase circulating LPS levels(Reference Delzenne, Neyrinck and Cani90). Intestinal alkaline phosphatase may also exert a protective effect systemically in addition to that conferred in the intestinal lumen(Reference Tuin, Huizinga-Van der Vlag and van Loenen-Weemaes85, Reference Goldberg, Austen and Zhang89).

Many food components, including fat, proteins, carbohydrates and some micronutrients, can modulate the expression or activity of the intestinal alkaline phosphatase, depending on the type and quantity of nutrient consumed(Reference Lallès88). A reduction in the activity of this enzyme was observed in the duodenal mucosa of rats with a propensity for obesity receiving high-fat diets(Reference de La Serre, Ellis and Lee48). However, intestinal alkaline phosphatase knockout mice gained more weight when fed a high-fat diet than wild-type mice fed the same diet(Reference Narisawa, Huang and Iwasaki91).

Sprague–Dawley rats fed high-fat diets presented higher alkaline phosphatase activity in the duodenum and jejunum. They also showed hypertrophy of the jejunal mucosa when compared to the control group, which was fed a control diet (9·5 % of energy from fat). However, rats receiving high-fat diets were subsequently classified as sensitive or resistant to obesity according to weight gain. Mice resistant to obesity were observed to have higher intestinal alkaline phosphatase activity(Reference Sefcíková, Hajek and Lenhardt92). Some authors suggest that dietary fat content and specific fatty acids can modulate the enzyme activity in different ways(Reference Lallès88, Reference Kaur, Madan and Hamid93, Reference Vazquez, Zanetti and Santa-Maria94). Thus, more studies are needed to determine the relationship between fat absorption, intestinal alkaline phosphatase activity and LPS clearance.

Recently, the importance of phosphatase in preserving gut microbiota homeostasis and in the protection against pathogenic bacteria was demonstrated in intestinal alkaline phosphatase knockout mice(Reference Malo, Alam and Mostafa95). When high-fat diets affect intestinal alkaline phosphatase activity, it may interfere with the interaction between diet, microbiota and endotoxaemia, suggesting that this enzyme can be a possible therapeutic target in the future. The routes that may favour metabolic endotoxaemia and related diseases in response to the consumption of high-fat diets are represented in Fig. 1.

Fig. 1 The possible pathways linking high fat consumption to metabolic endotoxaemia and chronic diseases. CM, chylomicrons; IAP, intestinal alkaline phosphatase; LPS, lipopolysaccharide.

Future perspectives

The effects of the consumption of two isoenergetic meals (3807 kJ (910 kcal) of either a high-fat or a normal meal) were evaluated in healthy, lean individuals (BMI < 25 kg/m2). The high-fat meal induced increases in plasma LPS levels and the expression of TLR4, ROS and NF-κB activity(Reference Ghanim, Abuaysheh and Sia34). The results of this study emphasise the importance of reducing the amount of fat consumed to a level required to maintain good health.

The chronic and excessive intake of fat has been associated with the development and progression of many non-transmissible chronic diseases. Traditionally, this association is attributed to the biological effects of fats, such as direct activation of the innate immune system through NEFA or through the increase in oxidation of fatty acids(Reference DeFronzo96, Reference Geraldo and Alfenas97). Recognition of the relationship between high-fat diets and endotoxaemia is recent and can partly explain the manifestation and maintenance of a subclinical inflammatory status that favours the development of insulin resistance and associated diseases(Reference Laugerette, Vors and Peretti33).

Similar macronutrient distributions in two diets differing in fat and carbohydrate sources have shown that the components of the diet rather than the macronutrient composition determine the extent of protection from developing obesity when comparing germ-free and conventional mice, and those components also exert different effects on the composition of microbiota(Reference Fleissner, Huebel and Abd El-Bary98). It is important to understand how the fatty acid profile of different lipid sources can affect endotoxaemia. As incorporation into chylomicrons and alteration of intestinal permeability are the main routes contributing to endotoxaemia, how different types of fatty acids can influence postprandial lipaemia and intestinal barrier function should be further explored.

For example, creamy saturated butter has been extensively replaced with vegetable-based ‘unsaturated’ margarines on supermarket shelves. However, this choice may not be the healthiest. Postprandial lipaemia and chylomicron secretion can be modified by the fatty acid composition and physico-chemical properties of dietary fat, which in turn may have an impact on postprandial endotoxaemia(Reference Laugerette, Vors and Peretti33). It has been observed that the consumption of butter in a meal resulted in lower postprandial lipaemia and chylomicron accumulation in the circulation in young men than that in men who consumed olive and sunflower oils(Reference Mekki, Charbonnier and Borel99). Moreover, oil emulsification has been shown to result in different levels of postprandial lipaemia. Rodents receiving emulsified sunflower oil showed higher postprandial lipaemia than when they were given non-emulsified oil, most probably because emulsification increases the surface area of oil and facilitates fat hydrolysis and absorption. Postprandial endotoxaemia was also higher in the group fed emulsified sunflower oil, showing that the physico-chemical structure of fat can affect the levels of circulating LPS as well(Reference Laugerette, Vors and Geloen19).

The type of fatty acid can also influence gut barrier function. The influence of oleic, eicosapentaenoic and DHA on intestinal epithelial integrity through the modulation of tight junctions has been demonstrated in vitro (Reference Aspenstrom-Fagerlund, Ring and Aspenstrom100, Reference Usami, Muraki and Iwamoto101), suggesting that the fatty acid profile of different foods might lead to different effects on intestinal permeability and cause differential increases in LPS.

Recently, Laugerette et al. (Reference Laugerette, Furet and Debard102) investigated the effects of dietary oil composition on markers of endotoxin action. Milk fat, palm oil, rapeseed oil or sunflower oil (22·4 % lipids) was administered to mice for 8 weeks. The palm oil group presented the highest level of IL-6 in plasma; and the highest expression of IL-1β, TLR4 and CD14 was in white adipose tissue(Reference Laugerette, Furet and Debard102). LPS-binding protein is used as a marker of metabolic endotoxaemia because it is a major LPS transporter in plasma, while sCD14 seems to provide protective effects against the LPS response(Reference Laugerette, Furet and Debard102), buffering the inflammatory signals by the avoidance of LPS exposure to the cell-anchored membrane form of CD14(Reference Fernández-Real, Pérez del Pulgar and Luche103). The higher inflammatory response observed in the palm oil group was correlated with a greater ratio of LPS-binding protein/sCD14 in plasma. Rapeseed oil intake resulted in higher levels of sCD14 than the intake of palm oil and was associated with less inflammation in plasma and white adipose tissue despite the higher plasma endotoxaemia. This finding reveals that the fatty acid profile can contribute to modulation of the onset of low-grade inflammation by influencing the type of endotoxin receptors and transporters, and it shows that higher endotoxin levels will not necessarily cause a more intense activation of the inflammatory pathways. Thus, components of the diet, such as fatty acids, also trigger inflammation, and LPS, in some situations, might increase the inflammatory burden induced by the diet.

The stimulation of adipocytes with LPS or different types of fatty acids (myristic, palmitic, linoleic or α-linolenic acids) shows that palmitic and linolenic acids are able to trigger inflammation, either alone or synergistically with LPS, inducing a greater increase in IL-6 than that of LPS alone(Reference Laugerette, Furet and Debard102). The activation of immunological cells in the intestine can also be influenced by the type of fatty acids, which in turn can result in different inflammatory response patterns(Reference Ji, Sakata and Tso45, Reference Tsuzuki, Miyazaki and Matsuzaki104). In macrophages, for example, long-chain SFA bind to TLR4 and induce pro-inflammatory cytokine expression(Reference Shi, Kokoeva and Inouye105). By contrast, medium-chain TAG were shown to protect rats from LPS-induced injuries of the gut and liver in comparison to maize oil(Reference Kono, Fujii and Asakawa106).

The possibility that some specific fatty acid types can be incorporated into the cell membrane, changing the composition of the lipid raft domain, indicates that they can shift/displace signalling proteins from the lipid raft and alter the activation of TLR4. LPS and lauric acid (medium-chain SFA) induce dimerisation and activation of TLR4, while DHA, an n-3 PUFA, inhibits the recruitment of TLR4 and other signalling proteins (TRIF and MyD88) to the lipid raft. The recruitment of TLR4 to the lipid raft is dependent on NADPH-oxidase, which is mediated by ROS; and LPS and lauric acid increase the cellular levels of ROS, while DHA reduces them(Reference Wong, Kwon and Choi107). Thus, low-grade inflammation induced by fatty acids is not a common characteristic of all fatty acids(Reference Laugerette, Furet and Debard102). Therefore, although creamy butter may seem to favourably affect lipaemia, its fatty acid profile, which is rich in SFA, may trigger inflammation independently of LPS action. How the fatty acid profile affects bile acid secretion and absorption of the fatty acids and of LPS, as also the increase and duration of postprandial lipaemia and the expression of receptors that bind to LPS and fatty acids, should be examined.

The potential of food combinations to reduce the negative effects of fat intake should also be considered in future studies. Orange juice, for example, when consumed with a high-fat meal, did not induce oxidative stress or inflammation, nor did it increase TLR4 expression or endotoxaemia, compared to when the same type of meal was consumed with water or a glucose solution. The authors attributed this beneficial effect of orange juice to its high levels of bioactive compounds, such as flavonoids, naringenin and hesperidin, because they exert a significant ROS-suppressive effect(Reference Ghanim, Sia and Upadhyay21). In another study, orange juice consumption did not affect the analysed parameters (suppression of cytokines signalling-3, TNF-α, IL-1β, LPS, TLR4) compared to water, cream and a glucose solution(Reference Deopurkar, Ghanim and Friedman108), suggesting that other phytochemicals may also play an important role in the intestinal environment or systemically(Reference Laparra and Sanz31).

Endotoxaemia induced by dietary fat can also be prevented by the administration of prebiotics and probiotics. A prebiotic is a selectively fermented ingredient that allows specific changes in the composition or activity of the gastrointestinal microbiota that confers benefits upon host well-being and health(Reference Roberfroid, Gibson and Hoyles109). Nutrients with prebiotic properties change the gut microbiota, stimulate the secretion of intestinal hormones such as glucagon-like peptide 1 and 2(Reference Cani, Possemiers and Van de Wiele50) and modulate the activation of the endocannabinoid system in the intestine and in the adipose tissue(Reference Muccioli, Naslain and Bäckhed110). All these effects contribute to reduce gut permeability, thereby decreasing endotoxaemia, and systemic inflammation(Reference Delzenne, Neyrinck and Cani90). Probiotics are defined as viable microbial dietary supplements that exert beneficial effects on host health. Some bacterial strains reportedly inhibit TLR4 expression and/or activation in the intestinal epithelial cells(Reference Takemura, Okubo and Sonoyama111).

Conclusions

Diet can modify the composition of gut microbiota, increase intestinal permeability and decrease LPS clearance, favouring metabolic endotoxaemia. This endotoxaemia, in turn, can cause subclinical inflammation that has been associated with the manifestation of several metabolic diseases. More studies are necessary to deepen the understanding of how specific nutrients or foods may affect metabolic endotoxaemia to allow the identification of nutritional strategies capable of its modulation. It is essential to identify dietetic strategies capable of minimising the extension and kinetics of postprandial endotoxaemia. From this perspective, two principles of nutrition guidelines seem to be very important: the types of nutrients consumed and the combination of different food types in a meal. This perspective offers new challenges for future studies once current recommendations, especially for foods that are typical sources of fat, have been reviewed. The amount of fat consumed, the fat's fatty acids profile and its physico-chemical properties are important characteristics to consider. In the near future, food will certainly be classified as pro-endotoxaemic or anti-endotoxaemic, which will be useful for future interventional studies.

Acknowledgements

No grant supported the present study, and none of the authors had any personal or financial conflict of interest related to this study. The authors' contributions were as follows: A. P. B. M. and T. F. S. T. designed the concept of the study, and all authors were involved in the literature search and review. A. P. B. M. and T. F. S. T. wrote the manuscript. A. B. F., M. d. C. G. P. and R. d. C. G. A. were involved with editing the manuscript; and all authors read and approved the final manuscript.

References

1Cani, PD & Delzenne, NM (2009) Interplay between obesity and associated metabolic disorders: new insights into the gut microbiota. Curr Opin Pharmacol 9, 737743.CrossRefGoogle ScholarPubMed
2Larsen, N, Vogensen, FK, van den Berg, FWJ, et al. (2010) Gut microbiota in human adults with type 2 diabetes differs from non-diabetic adults. PLoS One 5, e9085.CrossRefGoogle ScholarPubMed
3Caesar, R, Fåk, F & Bäckhed, F (2010) Effects of gut microbiota on obesity and atherosclerosis via modulation of inflammation and lipid metabolism. J Intern Med 268, 320328.CrossRefGoogle Scholar
4Herder, C, Schneitler, S, Rathmann, W, et al. (2007) Low-grade inflammation, obesity, and insulin resistance in adolescents. J Clin Endocrinol Metab 92, 45694574.CrossRefGoogle ScholarPubMed
5Stoll, G & Bendszus, M (2006) Inflammation and atherosclerosis: novel insights into plaque formation and destabilization. Stroke 37, 19231932.CrossRefGoogle ScholarPubMed
6Dandona, P, Aljada, A & Bandyopadhyay, A (2004) Inflammation: the link between insulin resistance, obesity and diabetes. Trends Immunol 25, 47.CrossRefGoogle ScholarPubMed
7Pickup, JC (2004) Inflammation and activated innate immunity in the pathogenesis of type 2 diabetes. Diabetes Care 27, 813823.CrossRefGoogle ScholarPubMed
8Duncan, BB, Schmidt, MI, Pankow, JS, et al. (2003) Low-grade systemic inflammation and the development of type 2 diabetes. Diabetes 52, 17991805.CrossRefGoogle ScholarPubMed
9Libby, P, Ridker, PM & Maseri, A (2002) Inflammation and atherosclerosis. Circulation 105, 11351143.CrossRefGoogle ScholarPubMed
10Cani, PD, Neyrinck, AM, Fava, F, et al. (2007) Selective increases of bifidobacteria in gut microflora improve high-fat-diet-induced diabetes in mice through a mechanism associated with endotoxaemia. Diabetologia 50, 23742383.CrossRefGoogle ScholarPubMed
11Cani, PD, Amar, J, Iglesias, MA, et al. (2007) Metabolic endotoxemia initiates obesity and insulin resistance. Diabetes 56, 17611772.CrossRefGoogle ScholarPubMed
12Elson, G, Dunn-Siegrist, I, Daubeuf, B, et al. (2007) Contribution of Toll-like receptors to the innate immune response to Gram-negative and Gram-positive bacteria. Blood 109, 15741583.CrossRefGoogle Scholar
13Wiedermann, CJ, Kiechl, S, Dunzendorfer, S, et al. (1999) Association of endotoxemia with carotid atherosclerosis and cardiovascular disease: prospective results from the Bruneck Study. J Am Coll Cardiol 34, 19751981.CrossRefGoogle ScholarPubMed
14Elin, RJ & Wolff, SM (1976) Biology of endotoxin. Annu Rev Med 27, 127141.CrossRefGoogle ScholarPubMed
15Hattori, M & Taylor, TD (2009) The human intestinal microbiome: a new frontier of human biology. DNA Res 16, 112.CrossRefGoogle ScholarPubMed
16Brun, P, Castagliuolo, I, Leo, VD, et al. (2007) Increased intestinal permeability in obese mice: new evidence in the pathogenesis of nonalcoholic steatohepatitis. Am J Physiol Gastrointest Liver Physiol 292, G518G525.CrossRefGoogle ScholarPubMed
17Berg, RD (1996) The indigenous gastrointestinal microflora. Trends Microbiol 4, 430435.CrossRefGoogle ScholarPubMed
18Bayston, K & Cohen, J (1990) Bacterial endotoxin and current concepts in the diagnosis and treatment of endotoxaemia. J Med Microbiol 31, 7383.CrossRefGoogle ScholarPubMed
19Laugerette, FC, Vors, A, Geloen, A, et al. (2011) Emulsified lipids increase endotoxemia: possible role in early postprandial low-grade inflammation. J Nutr Biochem 22, 5359.CrossRefGoogle ScholarPubMed
20Ghoshal, S, Witta, J, Zhong, J, et al. (2009) Chylomicrons promote intestinal absorption of lipopolysaccharides. J Lipid Res 50, 9097.CrossRefGoogle ScholarPubMed
21Ghanim, H, Sia, CL, Upadhyay, M, et al. (2010) Orange juice neutralizes the proinflammatory effect of a high-fat, high-carbohydrate meal and prevents endotoxin increase and Toll-like receptor expression. J Clin Nutr 91, 940949.CrossRefGoogle ScholarPubMed
22Erridge, C, Attina, T, Spickett, CM, et al. (2007) A high-fat meal induces low-grade endotoxemia: evidence of a novel mechanism of postprandial inflammation. Am J Clin Nutr 86, 12861292.CrossRefGoogle ScholarPubMed
23Heine, H, Rietschel, ET & Ulmer, AJ (2001) The biology of endotoxin. Mol Biotechnol 19, 279296.CrossRefGoogle ScholarPubMed
24Rietschel, ET, Kirikae, T, Schade, FU, et al. (1994) Bacterial endotoxin: molecular relationships of structure to activity and function. FASEB J 8, 217225.CrossRefGoogle ScholarPubMed
25Pussinen, PJ, Havulinna, AS, Lehto, M, et al. (2011) Endotoxemia is associated with an increased risk of incident diabetes. Diabetes Care 34, 392397.CrossRefGoogle ScholarPubMed
26Devaraj, S, Dasu, MR, Park, SH, et al. (2009) Increased levels of ligands of Toll-like receptors 2 and 4 in type 1 diabetes. Diabetologia 52, 16651668.CrossRefGoogle ScholarPubMed
27Miller, MA, McTernan, PG, Harte, AL, et al. (2009) Ethnic and sex differences in circulating endotoxin levels: a novel marker of atherosclerotic and cardiovascular risk in a British multi-ethnic population. Atherosclerosis 203, 494502.CrossRefGoogle Scholar
28Thuy, S, Ladurner, R, Volynets, V, et al. (2008) Nonalcoholic fatty liver disease in humans is associated with increased plasma endotoxin and plasminogen activator inhibitor 1 concentrations and with fructose intake. J Nutr 138, 14521455.CrossRefGoogle ScholarPubMed
29Creely, SJ, McTernan, PG, Kusminski, CM, et al. (2007) Lipopolysaccharide activates an innate immune system response in human adipose tissue in obesity and type 2 diabetes. Am J Physiol Endocrinol Metab 292, E740E747.CrossRefGoogle ScholarPubMed
30De Bandt, JP, Waligora-Dupriet, AJ & Butel, MJ (2011) Intestinal microbiota in inflammation and insulin resistance: relevance to humans. Curr Opin Clin Nutr Metab Care 14, 334340.CrossRefGoogle ScholarPubMed
31Laparra, JM & Sanz, Y (2010) Interactions of gut microbiota with functional food components and nutraceuticals. Pharmacol Res 61, 219225.CrossRefGoogle ScholarPubMed
32Delzenne, NM & Cani, PD (2011) Gut microbiota and the pathogenesis of insulin resistance. Curr Diab Rep 11, 154159.CrossRefGoogle ScholarPubMed
33Laugerette, F, Vors, C, Peretti, N, et al. (2011) Complex links between dietary lipids, endogenous endotoxins and metabolic inflammation. Biochimie 93, 3945.CrossRefGoogle ScholarPubMed
34Ghanim, H, Abuaysheh, S, Sia, CL, et al. (2009) Increase in plasma endotoxin concentrations and the expression of Toll-like receptors and suppressor of cytokine signaling-3 in mononuclear cells after a high-fat, high-carbohydrate meal. Diabetes Care 32, 22812287.CrossRefGoogle ScholarPubMed
35Amar, J, Burcelin, R, Ruidavets, JB, et al. (2008) Energy intake is associated with endotoxemia in apparently healthy men. Am J Clin Nutr 87, 12191223.CrossRefGoogle ScholarPubMed
36Raetz, CRH & Whitfield, C (2002) Lipopolysaccharide endotoxins. Annu Rev Biochem 71, 635700.CrossRefGoogle ScholarPubMed
37Vreugdenhil, AC, Rousseau, CH, Hartung, T, et al. (2003) Lipopolysaccharide (LPS)-binding protein mediates LPS detoxification by chylomicrons. J Immunol 170, 13991405.CrossRefGoogle ScholarPubMed
38Manco, M, Putignani, L & Bottazzo, GF (2010) Gut microbiota, lipopolysaccharides, and innate immunity in the pathogenesis of obesity and cardiovascular risk. Endocr Rev 31, 817844.CrossRefGoogle ScholarPubMed
39Harris, HW, Grunfeld, C, Feingold, KR, et al. (1993) Chylomicrons alter the fate of endotoxin, decreasing tumor necrosis factor release and preventing death. J Clin Invest 91, 10281034.CrossRefGoogle ScholarPubMed
40Salim, SY & Soderholm, JD (2011) Importance of disrupted intestinal barrier in inflammatory bowel diseases. Inflamm Bowel Dis 17, 362381.CrossRefGoogle ScholarPubMed
41Shen, L, Su, L & Turner, JR (2009) Mechanisms and functional implications of intestinal barrier defects. Dig Dis 27, 443449.CrossRefGoogle ScholarPubMed
42Tso, P & Balint, JA (1986) Formation and transport of chylomicrons by enterocytes to the lymphatics. Am J Physiol 250, G715G726.Google Scholar
43Kvietys, PR, Specian, RD, Grisham, MB, et al. (1991) Jejunal mucosal injury and restitution: role of hydrolytic products of food digestion. Am J Physiol 261, G384G391.Google ScholarPubMed
44Cani, PD, Bibiloni, B, Knauf, C, et al. (2008) Changes in gut microbiota control metabolic endotoxemia-induced inflammation in high-fat diet-induced obesity and diabetes in mice. Diabetes 57, 14701481.CrossRefGoogle ScholarPubMed
45Ji, Y, Sakata, Y & Tso, P (2011) Nutrient-induced inflammation in the intestine. Curr Opin Clin Nutr Metab Care 14, 315321.CrossRefGoogle ScholarPubMed
46Keita, AV & Derholm, JD (2010) The intestinal barrier and its regulation by neuroimmune factors. Neurogastroenterol Motil 22, 718733.CrossRefGoogle ScholarPubMed
47Turner, JR (2006) Molecular basis of epithelial barrier regulation: from basic mechanisms to clinical application. Am J Pathol 169, 19011909.CrossRefGoogle ScholarPubMed
48de La Serre, CB, Ellis, CL, Lee, J, et al. (2010) Propensity to high-fat diet-induced obesity in rats is associated with changes in the gut microbiota and gut inflammation. Am J Physiol Gastrointest Liver Physiol 299, G440G448.CrossRefGoogle ScholarPubMed
49Suzuki, T & Hara, H (2010) Dietary fat and bile juice, but not obesity, are responsible for the increase in small intestinal permeability induced through the suppression of tight junction protein expression in LETO and OLETF rats. Nutr Metab 12, 719.Google Scholar
50Cani, PD, Possemiers, S, Van de Wiele, T, et al. (2009) Changes in gut microbiota control inflammation in obese mice through a mechanism involving GLP-2-driven improvement of gut permeability. Gut 58, 10911103.CrossRefGoogle ScholarPubMed
51Wang, Z, Xiao, G, Yao, Y, et al. (2006) The role of bifidobacteria in gut barrier function after thermal injury in rats. J Trauma 61, 650657.CrossRefGoogle ScholarPubMed
52Wang, ZT, Yao, YM, Xiao, GX, et al. (2004) Risk factors of development of gut-derived bacterial translocation in thermally injured rats. World J Gastroenterol 10, 16191624.CrossRefGoogle ScholarPubMed
53Griffiths, EA, Duffy, LC, Schanbacher, FL, et al. (2004) In vivo effects of bifidobacteria and lactoferrin on gut endotoxin concentration and mucosal immunity in Balb/c mice. Dig Dis Sci 49, 579589.CrossRefGoogle ScholarPubMed
54Ruseler-van Embden, JG, van Lieshout, LM, Gosselink, MJ, et al. (1995) Inability of Lactobacillus casei strain GG, L. acidophilus, and Bifidobacterium bifidum to degrade intestinal mucus glycoproteins. Scand J Gastroenterol 30, 675680.CrossRefGoogle Scholar
55Begley, M, Gahan, CG & Hill, C (2005) The interaction between bacteria and bile. FEMS Microbiol Rev 29, 625651.CrossRefGoogle ScholarPubMed
56Quigley, EM & Quera, R (2006) Small intestinal bacterial overgrowth: roles of antibiotics, prebiotics, and probiotics. Gastroenterology 130, S78S90.CrossRefGoogle ScholarPubMed
57Sabaté, JM, Jouët, P, Harnois, F, et al. (2008) High prevalence of small intestinal bacterial overgrowth in patients with morbid obesity: a contributor to severe hepatic steatosis. Obes Surg 18, 371377.CrossRefGoogle ScholarPubMed
58Jones, BV, Begley, M, Hill, C, et al. (2008) Functional and comparative metagenomic analysis of bile salt hydrolase activity in the human gut microbiome. Proc Natl Acad Sci 105, 1358013585.CrossRefGoogle ScholarPubMed
59Parlesak, A, Schaeckeler, S, Moser, L, et al. (2007) Conjugated primary bile salts reduce permeability of endotoxin through intestinal epithelial cells and synergize with phosphatidylcholine in suppression of inflammatory cytokine production. Crit Care Med 35, 23672374.CrossRefGoogle ScholarPubMed
60Lorenzo-Zúñiga, V, Bartolí, R, Planas, R, et al. (2003) Oral bile acids reduce bacterial overgrowth, bacterial translocation, and endotoxemia in cirrhotic rats. Hepatology 37, 551557.CrossRefGoogle ScholarPubMed
61Raimondi, F, Santoro, P, Barone, MV, et al. (2008) Bile acids modulate tight junction structure and barrier function of Caco-2 monolayers via EGFR activation. Am J Physiol Gastrointest Liver Physiol 294, G906G913.CrossRefGoogle ScholarPubMed
62Araki, Y, Katoh, T, Ogawa, A, et al. (2005) Bile acid modulates transepithelial permeability via the generation of reactive oxygen species in the Caco-2 cell line. Free Radic Biol Med 39, 769780.CrossRefGoogle ScholarPubMed
63Musso, G, Gambino, R & Cassader, M (2010) Obesity, diabetes, and gut microbiota. The hygiene hypothesis expanded? Diabetes Care 33, 22772284.CrossRefGoogle ScholarPubMed
64Cordain, L, Eaton, SB, Sebastian, A, et al. (2005) Origins and evolution of the Western diet: health implications for the 21st century. Am J Clin Nutr 81, 341354.CrossRefGoogle Scholar
65Hotamisligil, GS (2003) Inflammatory pathways and insulin action. Int J Obes Relat Metab Disord 27, S53S55.CrossRefGoogle ScholarPubMed
66Bastard, JP, Maachi, M, Lagathu, C, et al. (2006) Recent advances in the relationship between obesity, inflammation, and insulin resistance. Eur Cytokine Netw 17, 412.Google ScholarPubMed
67Cani, PD & Delzenne, NM (2011) The gut microbiome as therapeutic target. Pharmacol Ther 130, 202212.CrossRefGoogle ScholarPubMed
68Grimaldi, E, Donnarumma, G, Perfetto, B, et al. (2009) Proinflammatory signal transduction pathway induced by Shigella flexneri porins in Caco-2 cells. Braz J Microbiol 40, 701713.Google Scholar
69Song, MJ, Kim, KH, Yoon, JM, et al. (2006) Activation of Toll-like receptor 4 is associated with insulin resistance in adipocytes. Biochem Biophys Res Commun 346, 739745.CrossRefGoogle ScholarPubMed
70Moreira, APB & Alfenas, RCG (2012) The influence of endotoxemia on the molecular mechanisms of insulin resistance. Nutr Hosp 27, 382390.Google Scholar
71Bastos, DHM, Rogero, MM & Arêas, JAG (2009) Mecanismos de ação de compostos bioativos dos alimentos no contexto de processos inflamatórios relacionados à obesidade (Effects of dietary bioactive compounds on obesity-induced inflammation). Arq Bras Endocrinol Metab 53, 646656.CrossRefGoogle Scholar
72Pan, ZK (2004) Toll-like receptors and TLR-mediated signaling: more questions than answers. Am J Physiol Lung Cell Mol Physiol 286, L918L920.CrossRefGoogle ScholarPubMed
73Ding, S & Lund, PK (2011) Role of intestinal inflammation as an early event in obesity and insulin resistance. Curr Opin Clin Nutr Metab Care 14, 328333.CrossRefGoogle ScholarPubMed
74Hoehn, KL, Salmon, AB, Hohnen-Behrens, C, et al. (2009) Insulin resistance is a cellular antioxidant defense mechanism. Proc Natl Acad Sci U S A 106, 1778717792.CrossRefGoogle ScholarPubMed
75Laron, Z (2009) Insulin and the brain. Arch Physiol Biochem 115, 112116.CrossRefGoogle ScholarPubMed
76Shanik, MH, Xu, Y, Skrha, J, et al. (2008) Insulin resistance and hyperinsulinemia: is hyperinsulinemia the cart or the horse? Diabetes Care 31, S262S268.CrossRefGoogle ScholarPubMed
77Dandona, P, Ghanim, H, Bandyopadhyay, A, et al. (2010) Insulin suppresses endotoxin-induced oxidative, nitrosative, and inflammatory stress in humans. Diabetes Care 33, 24162423.CrossRefGoogle ScholarPubMed
78Mehta, NN, McGillicuddy, FC, Anderson, PD, et al. (2010) Experimental endotoxemia induces adipose inflammation and insulin resistance in humans. Diabetes 59, 172181.CrossRefGoogle ScholarPubMed
79Agwunobi, AO, Reid, C, Maycock, P, et al. (2000) Insulin resistance and substrate utilization in human endotoxemia. J Clin Endocrinol Metab 85, 37703778.CrossRefGoogle ScholarPubMed
80Chow, L, From, A & Seaquist, E (2010) Skeletal muscle insulin resistance: the interplay of local lipid excess and mitochondrial dysfunction. Metabolism 59, 7085.CrossRefGoogle ScholarPubMed
81Boden, G (2008) Obesity and free fatty acids (FFA). Endocrinol Metab Clin North Am 37, 635646(viii–ix).CrossRefGoogle Scholar
82Kovacs, P & Stumvoll, M (2005) Fatty acids and insulin resistance in muscle and liver. Best Pract Res Clin Endocrinol Metab 19, 625635.CrossRefGoogle ScholarPubMed
83Wang, Z, Klipfell, E, Bennett, BJ, et al. (2011) Gut flora metabolism of phosphatidylcholine promotes cardiovascular disease. Nature 472, 5763.CrossRefGoogle ScholarPubMed
84Li, L, Messas, E, Batista, EL Jr, et al. (2002) Porphyromonas gingivalis infection accelerates the progression of atherosclerosis in a heterozygous apolipoprotein E-deficient murine model. Circulation 105, 861867.CrossRefGoogle Scholar
85Tuin, A, Huizinga-Van der Vlag, A, van Loenen-Weemaes, AM, et al. (2006) On the role and fate of LPS-dephosphorylating activity in the rat liver. Am J Physiol Gastrointest Liver Physiol 290, G377G385.CrossRefGoogle ScholarPubMed
86Bates, JM, Akerlund, J, Mittge, E, et al. (2007) Intestinal alkaline phosphatase detoxifies lipopolysaccharide and prevents inflammation in response to the gut microbiota. Cell Host Microbe 2, 371382.CrossRefGoogle ScholarPubMed
87Schromm, AB, Brandenburg, K, Loppnow, H, et al. (1998) The charge of endotoxin molecules influences their conformation and IL-6-inducing capacity. J Immunol 161, 54645471.CrossRefGoogle ScholarPubMed
88Lallès, JP (2010) Intestinal alkaline phosphatase: multiple biological roles in maintenance of intestinal homeostasis and modulation by diet. Nutr Rev 68, 323332.CrossRefGoogle ScholarPubMed
89Goldberg, RF, Austen, WG Jr, Zhang, X, et al. (2008) Intestinal alkaline phosphatase is a gut mucosal defense factor maintained by enteral nutrition. Proc Natl Acad Sci U S A 105, 35513556.CrossRefGoogle ScholarPubMed
90Delzenne, NM, Neyrinck, AM & Cani, PD (2011) Modulation of the gut microbiota by nutrients with prebiotic properties: consequences for host health in the context of obesity and metabolic syndrome. Microb Cell Fact 10, S10.CrossRefGoogle ScholarPubMed
91Narisawa, S, Huang, L, Iwasaki, A, et al. (2003) Accelerated fat absorption in intestinal alkaline phosphatase knockout mice. Mol Cell Biol 23, 75257530.CrossRefGoogle ScholarPubMed
92Sefcíková, Z, Hajek, T, Lenhardt, L, et al. (2008) Different functional responsibility of the small intestine to high-fat/high-energy diet determined the expression of obesity-prone and obesity-resistant phenotypes in rats. Physiol Res 57, 467474.CrossRefGoogle ScholarPubMed
93Kaur, J, Madan, S, Hamid, A, et al. (2007) Intestinal alkaline phosphatase secretion in oil-fed rats. Dig Dis Sci 52, 665670.CrossRefGoogle ScholarPubMed
94Vazquez, CM, Zanetti, R, Santa-Maria, C, et al. (2000) Effects of two highly monounsaturated oils on lipid composition and enzyme activities in rat jejunum. Biosci Rep 20, 355368.CrossRefGoogle ScholarPubMed
95Malo, MS, Alam, SN, Mostafa, G, et al. (2010) Intestinal alkaline phosphatase preserves the normal homeostasis of gut microbiota. Gut 59, 14761484.CrossRefGoogle ScholarPubMed
96DeFronzo, RA (2010) Insulin resistance, lipotoxicity, type 2 diabetes and atherosclerosis: the missing links. The Claude Bernard Lecture 2009. Diabetologia 53, 12701287.CrossRefGoogle Scholar
97Geraldo, JM & Alfenas, RCG (2008) Papel da dieta na prevenção e no controle da inflamação crônica – evidências atuais (Role of diet on chronic inflammation prevention and control – current evidence). Arq Bras Endocrinol Metab 52, 951967.CrossRefGoogle Scholar
98Fleissner, CK, Huebel, N, Abd El-Bary, MM, et al. (2010) Absence of intestinal microbiota does not protect mice from diet-induced obesity. Br J Nutr 104, 919929.CrossRefGoogle Scholar
99Mekki, N, Charbonnier, M, Borel, P, et al. (2002) Butter differs from olive oil and sunflower oil in its effect on postprandial lipemia and triacylglycerol-rich lipoproteins after single mixed meals in healthy young men. J Nutr 132, 36423649.CrossRefGoogle ScholarPubMed
100Aspenstrom-Fagerlund, B, Ring, L, Aspenstrom, P, et al. (2007) Oleic acid and docosahexaenoic acid cause an increase in the paracellular absorption of hydrophilic compounds in an experimental model of human absorptive enterocytes. Toxicology 237, 1223.CrossRefGoogle Scholar
101Usami, M, Muraki, K, Iwamoto, M, et al. (2001) Effect of eicosapentaenoic acid (EPA) on tight junction permeability in intestinal monolayer cells. Clin Nutr 20, 351359.CrossRefGoogle ScholarPubMed
102Laugerette, F, Furet, JP, Debard, C, et al. (2012) Oil composition of high-fat diet affects metabolic inflammation differently in connection with endotoxin receptors in mice. Am J Physiol Endocrinol Metab 302, E374E386.CrossRefGoogle ScholarPubMed
103Fernández-Real, JM, Pérez del Pulgar, S, Luche, E, et al. (2011) CD14 modulates inflammation-driven insulin resistance. Diabetes 60, 21792186.CrossRefGoogle ScholarPubMed
104Tsuzuki, Y, Miyazaki, J, Matsuzaki, K, et al. (2006) Differential modulation in the functions of intestinal dendritic cells by long- and medium-chain fatty acids. J Gastroenterol 41, 209216.CrossRefGoogle ScholarPubMed
105Shi, H, Kokoeva, MV, Inouye, K, et al. (2006) TLR4 links innate immunity and fatty acid-induced insulin resistance. J Clin Invest 116, 30153025.CrossRefGoogle ScholarPubMed
106Kono, H, Fujii, H, Asakawa, M, et al. (2003) Protective effects of medium-chain triglycerides on the liver and gut in rats administered endotoxin. Ann Surg 237, 246255.CrossRefGoogle ScholarPubMed
107Wong, SW, Kwon, MJ, Choi, AM, et al. (2009) Fatty acids modulate Toll-like receptor 4 activation through regulation of receptor dimerization and recruitment into lipid rafts in a reactive oxygen species-dependent manner. J Biol Chem 284, 2738427392.CrossRefGoogle Scholar
108Deopurkar, R, Ghanim, H, Friedman, J, et al. (2010) Differential effects of cream, glucose and orange juice on inflammation, endotoxin, and the expression of Toll-like receptor-4 and suppressor of cytokine signaling-3. Diabetes Care 33, 991997.CrossRefGoogle ScholarPubMed
109Roberfroid, M, Gibson, GR & Hoyles, L (2010) Prebiotic effects: metabolic and health benefits. Br J Nutr 104, Suppl. 2, S1S63.CrossRefGoogle ScholarPubMed
110Muccioli, GG, Naslain, D, Bäckhed, F, et al. (2010) The endocannabinoid system links gut microbiota to adipogenesis. Mol Syst Biol 6, 392.CrossRefGoogle ScholarPubMed
111Takemura, N, Okubo, T & Sonoyama, K (2010) Lactobacillus plantarum strain no. 14 reduces adipocyte size in mice fed high-fat diet. Exp Biol Med 235, 849856.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 The possible pathways linking high fat consumption to metabolic endotoxaemia and chronic diseases. CM, chylomicrons; IAP, intestinal alkaline phosphatase; LPS, lipopolysaccharide.