Simvastatin-induced cardiac autonomic control improvement in fructose-fed female rats

OBJECTIVE: Because autonomic dysfunction has been found to lead to cardiometabolic disorders and because studies have reported that simvastatin treatment has neuroprotective effects, the objective of the present study was to investigate the effects of simvastatin treatment on cardiovascular and autonomic changes in fructose-fed female rats. METHODS: Female Wistar rats were divided into three groups: controls (n=8), fructose (n=8), and fructose+ simvastatin (n=8). Fructose overload was induced by supplementing the drinking water with fructose (100 mg/L, 18 wks). Simvastatin treatment (5 mg/kg/day for 2 wks) was performed by gavage. The arterial pressure was recorded using a data acquisition system. Autonomic control was evaluated by pharmacological blockade. RESULTS: Fructose overload induced an increase in the fasting blood glucose and triglyceride levels and insulin resistance. The constant rate of glucose disappearance during the insulin intolerance test was reduced in the fructose group (3.4+ 0.32%/min) relative to that in the control group (4.4+ 0.29%/min). Fructose+simvastatin rats exhibited increased insulin sensitivity (5.4+0.66%/min). The fructose and fructose+simvastatin groups demonstrated an increase in the mean arterial pressure compared with controls rats (fructose: 124+2 mmHg and fructose+simvastatin: 126 + 3 mmHg vs. controls: 112 + 2 mmHg). The sympathetic effect was enhanced in the fructose group (73 + 7 bpm) compared with that in the control (48 + 7 bpm) and fructose+simvastatin groups (31+8 bpm). The vagal effect was increased in fructose+simvastatin animals (84 + 7 bpm) compared with that in control (49 + 9 bpm) and fructose animals (46+5 bpm). CONCLUSION: Simvastatin treatment improved insulin sensitivity and cardiac autonomic control in an experimental model of metabolic syndrome in female rats. These effects were independent of the improvements in the classical plasma lipid profile and of reductions in arterial pressure. These results support the hypothesis that statins reduce the cardiometabolic risk in females with metabolic syndrome.

Obtaining and selection of hexokinases-less strains of Saccharomyces cerevisiae for production of ethanol and fructose from sucrose

Saccharomyces cerevisiae hexokinase-less strains were produced to study the production of ethanol and fructose from sucrose. These strains do not have the hexokinases A and B. Twenty-three double-mutant strains were produced, and then, three were selected for presenting a smaller growth in yeast extract-peptone-fructose. In fermentations with a medium containing sucrose (180.3 g L-1) and with cell recycles, simulating industrial conditions, the capacity of these mutant yeasts in inverting sucrose and fermenting only glucose was well characterized. Besides that, we could also see their great tolerance to the stresses of fermentative recycles, where fructose production (until 90 g L-1) and ethanol production (until 42.3 g L-1) occurred in cycles of 12 h, in which hexokinase-less yeasts performed high growth (51.2% of wet biomass) and viability rates (77% of viable cells) after nine consecutive cycles.

Glucose and Fructose Fermentation by Wine Yeasts in Media Containing Structurally Complex Nitrogen Sources

Glucose and fructose fermentations by industrial yeasts strains are strongly affected by both the structural complexity of the nitrogen Source and the availability of oxygen. In this Study two Saccharomyces cerevisiae industrial wine strains were grown, under shaken and static conditions, in a media containing either a) 20% (w/v) glucose, or b) 10% (w/v) fructose and 10% (w/v) glucose or c) 20% (w/v) fructose, all supplemented with nitrogen Sources varying from a single ammonium salt (ammonium Sulfate) to free amino acids (casamino acids) and peptides (peptone). Data Suggest that 1 complex Structured nitrogen source is not submitted to the same control mechanisms as those involved in the utilization of simpler structured nitrogen Sources, and mutual interaction between carbon and nitrogen Sources, including the mechanisms involved ill the regulation of aerobic/anaerobic metabolism, may play in important role in defining yeast fermentation performance and the differing response to the structural complexity of the nitrogen Source, with a strong impact oil fermentation performance.

Fructose-1,6-bisphosphate reduces inflammatory pain-like behaviour in mice: role of adenosine acting on A(1) receptors

Background and purpose: D-Fructose-1,6-bisphosphate (FBP) is an intermediate in the glycolytic pathway, exerting pharmacological actions on inflammation by inhibiting cytokine production or interfering with adenosine production. Here, the possible antinociceptive effect of FBP and its mechanism of action in the carrageenin paw inflammation model in mice were addressed, focusing on the two mechanisms described above. Experimental approach: Mechanical hyperalgesia (decrease in the nociceptive threshold) was evaluated by the electronic pressure-metre test; cytokine levels were measured by elisa and adenosine was determined by high performance liquid chromatography. Key results: Pretreatment of mice with FBP reduced hyperalgesia induced by intraplantar injection of carrageenin (up to 54%), tumour necrosis factor alpha (40%), interleukin-1 beta (46%), CXCL1 (33%), prostaglandin E(2) (41%) or dopamine (55%). However, FBP treatment did not alter carrageenin-induced cytokine (tumour necrosis factor alpha and interleukin-1 beta) or chemokine (CXCL1) production. On the other hand, the antinociceptive effect of FBP was prevented by systemic and intraplantar treatment with an adenosine A(1) receptor antagonist (8-cyclopentyl-1,3-dipropylxanthine), suggesting that the FBP effect is mediated by peripheral adenosine acting on A(1) receptors. Giving FBP to mice increased adenosine levels in plasma, and adenosine treatment of paw inflammation presented a similar antinociceptive mechanism to that of FBP. Conclusions and implications: In addition to anti-inflammatory action, FBP also presents an antinociceptive effect upon inflammatory hyperalgesia. Its mechanism of action seems dependent on adenosine production but not on modulation of hyperalgesic cytokine/chemokine production. In turn, adenosine acts peripherally on its A(1) receptor inhibiting hyperalgesia. FBP may have possible therapeutic applications in reducing inflammatory pain.

Physical aging of amorphous fructose

Physical aging of amorphous anhydrous fructose at temperature 5 degreesC and at 22 degreesC was studied using differential scanning calorimetry (DSC). The dynamic glass transitions temperature, T-g0 for unaged samples was 16 degreesC and 13.3 degreesC for heating rate of 10 degreesC/min and 1 degreesC/min, respectively. The fictive temperature, T-f0 for unaged samples calculated by Richardson and Savill method was 12 degreesC, which is close to the dynamic value obtained from the lower DSC heating rate. The fictive temperature T-f of the aged fructose glasses at temperatures both below and above the transition region was fitted well by a non-exponential decay function (Williams-Watts form). Aging above the transition region (22 degreesC) for 18 d increased both the dynamic glass transition temperature T and the fictive temperature T-f. However, aging below the transition region (5 degreesC) for I d increased the dynamic glass transition temperature T-g but decreased the fictive temperature T-f.

Co-crystallization of sucrose at high concentration in the presence of glucose and fructose

Co-crystallization of sucrose from a highly concentrated sucrose syrup (less than or equal to 7% moisture, w/w) at 131 degreesC with 0, 5, 10, 15, and 20% of fructose, glucose, or a mixture of fructose and glucose was investigated. The crystallization of sucrose was delayed in presence of these lower molecular weight sugars. The DSC melting endotherm of cocrystallized samples exhibited a decrease in crystalline sucrose in the sample as a function of increased level of glucose and fructose. The mechanical strength of co-crystallized granules was found to be related to the moisture content and the amount of glucose or fructose content in the sample. The samples containing 10, 15, and 20% glucose in co-crystallized product demonstrated crystallization of glucose in its monohydrate form during 1 mo of storage.

Characterization of the surface stickiness of fructose-maltodextrin solutions during drying

A probe tack test has been used for the in situ characterization of the surface stickiness of hemispherical drops with an initial radius of 3.5 mm while drying. Surface stickiness of drops of fructose and maltodextrin solutions dried at 63degreesC and 95degreesC was determined. The effect of addition of maltodextrin on fructose solution-was studied with fructose/maltodextrin solid mass ratios of 4: 1, 1: 1, and 1:4. Pure fructose solutions remained completely sticky and failed cohesively even when their moisture approached zero. Shortly after the start of drying, the surface of the maltodextrin drops formed a skin, which rapidly grew in thickness. Subsequently the drop surface became completely nonsticky probably due to transformation of outer layers into a glassy material. Addition of malto,dextrin significantly altered the surface stickiness of drops of fructose solutions, demonstrating its use as an effective drying aid.

Effects of infused fructose on endogenous glucose production, gluconeogenesis, and glycogen metabolism.

To determine the mechanisms that prevent an increase in gluconeogenesis from increasing hepatic glucose output, six healthy women were infused with [1-13C]fructose (22 mumol.kg-1.min-1), somatostatin, insulin, and glucagon. In control experiment, non-13C-enriched fructose was infused at the same rate without somatostatin, and [U-13C]glucose was infused to measure specifically plasma glucose oxidation. Endogenous glucose production (EGP, [6,6-2H]glucose), net carbohydrate oxidation (CHOox, indirect calorimetry), and fructose oxidation (13CO2) were measured. EGP rate did not increase after fructose infusion with (13.1 +/- 1.2 vs. 12.9 +/- 0.3 mumol.kg-1.min-1) and without (10.3 +/- 0.5 vs. 9.7 +/- 0.5 mumol.kg-1.min-1) somatostatin, despite the fact that gluconeogenesis increased. Nonoxidative fructose disposal, corresponding mainly to glycogen synthesis, was threefold net glycogen deposition, the latter calculated as fructose infusion minus CHOox (14.8 +/- 1.1 and 4.3 +/- 2.0 mumol.kg-1.min-1). It is concluded that 1) the mechanism by which EGP remains constant when gluconeogenesis from fructose increases is independent of changes in insulin and 2) simultaneous breakdown and synthesis of glycogen occurred during fructose infusion.

Moderate amounts of fructose consumption impair insulin sensitivity in healthy young men: a randomized controlled trial.

OBJECTIVE: Adverse effects of hypercaloric, high-fructose diets on insulin sensitivity and lipids in human subjects have been shown repeatedly. The implications of fructose in amounts close to usual daily consumption, however, have not been well studied. This study assessed the effect of moderate amounts of fructose and sucrose compared with glucose on glucose and lipid metabolism. RESEARCH DESIGN AND METHODS: Nine healthy, normal-weight male volunteers (aged 21-25 years) were studied in this double-blind, randomized, cross-over trial. All subjects consumed four different sweetened beverages (600 mL/day) for 3 weeks each: medium fructose (MF) at 40 g/day, and high fructose (HF), high glucose (HG), and high sucrose (HS) each at 80 g/day. Euglycemic-hyperinsulinemic clamps with [6,6]-(2)H(2) glucose labeling were used to measure endogenous glucose production. Lipid profile, glucose, and insulin were measured in fasting samples. RESULTS: Hepatic suppression of glucose production during the clamp was significantly lower after HF (59.4 ± 11.0%) than HG (70.3 ± 10.5%, P < 0.05), whereas fasting glucose, insulin, and C-peptide did not differ between the interventions. Compared with HG, LDL cholesterol and total cholesterol were significantly higher after MF, HF, and HS, and free fatty acids were significantly increased after MF, but not after the two other interventions (P < 0.05). Subjects' energy intake during the interventions did not differ significantly from baseline intake. CONCLUSIONS: This study clearly shows that moderate amounts of fructose and sucrose significantly alter hepatic insulin sensitivity and lipid metabolism compared with similar amounts of glucose.

Exercise prevents fructose-induced hypertriglyceridemia in healthy young subjects.

Excess fructose intake causes hypertriglyceridemia and hepatic insulin resistance in sedentary humans. Since exercise improves insulin sensitivity in insulin-resistant patients, we hypothesized that it would also prevent fructose-induced hypertriglyceridemia. This study was therefore designed to evaluate the effects of exercise on circulating lipids in healthy subjects fed a weight-maintenance, high-fructose diet. Eight healthy males were studied on three occasions after 4 days of 1) a diet low in fructose and no exercise (C), 2) a diet with 30% fructose and no exercise (HFr), or 3) a diet with 30% fructose and moderate aerobic exercise (HFrEx). On all three occasions, a 9-h oral [(13)C]-labeled fructose loading test was performed on the fifth day to measure [(13)C]palmitate in triglyceride-rich lipoprotein (TRL)-triglycerides (TG). Compared with C, HFr significantly increased fasting glucose, total TG, TRL-TG concentrations, and apolipoprotein (apo)B48 concentrations as well as postfructose glucose, total TG, TRL-TG, and [(13)C]palmitate in TRL-TG. HFrEx completely normalized fasting and postfructose TG, TRL-TG, and [(13)C]palmitate concentration in TRL-TG and apoB48 concentrations. In addition, it increased lipid oxidation and plasma nonesterified fatty acid concentrations compared with HFr. These data indicate that exercise prevents the dyslipidemia induced by high fructose intake independently of energy balance.

Effects of four-week high-fructose diet on gene expression in skeletal muscle of healthy men.

AIMS: A high-fructose diet (HFrD) may play a role in the obesity and metabolic disorders epidemic. In rodents, HFrD leads to insulin resistance and ectopic lipid deposition. In healthy humans, a four-week HFrD alters lipid homoeostasis, but does not affect insulin sensitivity or intramyocellular lipids (IMCL). The aim of this study was to investigate whether fructose may induce early molecular changes in skeletal muscle prior to the development of whole-body insulin resistance. METHODS: Muscle biopsies were taken from five healthy men who had participated in a previous four-week HFrD study, during which insulin sensitivity (hyperinsulinaemic euglycaemic clamp), and intrahepatocellular lipids and IMCL were assessed before and after HFrD. The mRNA concentrations of 16 genes involved in lipid and carbohydrate metabolism were quantified before and after HFrD by real-time quantitative PCR. RESULTS: HFrD significantly (P<0.05) increased stearoyl-CoA desaturase-1 (SCD-1) (+50%). Glucose transporter-4 (GLUT-4) decreased by 27% and acetyl-CoA carboxylase-2 decreased by 48%. A trend toward decreased peroxisomal proliferator-activated receptor-gamma coactivator-1alpha (PGC-1alpha) was observed (-26%, P=0.06). All other genes showed no significant changes. CONCLUSION: HFrD led to alterations of SCD-1, GLUT-4 and PGC-1alpha, which may be early markers of insulin resistance.

Modulation of fructose metabolism by dietary factors

High fructose consumption is associated with obesity and characteristics of metabolic syndrome. This includes insulin resistance, dyslipidemia, type II diabetes and hepatic steatosis, the hepatic component of metabolic syndrome. Short term high fructose consumption in healthy humans is considered as a study model to increase intrahepatocellular lipids (IHCL). Protein supplementation added to a short term high fructose diet exerts a protective role on hepatic fat accumulation. Fructose disposal after an acute fructose load is well established. However, fructose disposal is usually studied when a high intake of fructose is ingested. Interaction of fructose with other macronutrients on fructose disposal is not clearly established. We wanted to assess how fructose disposal is modulated with nutritional factors. For the first study, we addressed the question of how would essential amino acid (EAA) supplemented to a high fructose diet have an impact on hepatic fat accumulation? We tried to distinguish which metabolic pathways were responsible for the increase in IHCL induced by high fructose intake and how those pathways would be modulated by EAA. After 6 days of hypercaloric high fructose diet, we observed, as expected an increase in IHCL modulated by an increase in VLDL-triglycerides and an increase in VLDL-13C-palmitate production. When adding a supplementation in EAA, we observed a decrease in IHCL but we could not define which mechanism was responsible for this process. With the second study, we were interested to observe fructose disposal after a test meal that contained lipid, protein and a physiologic dose of fructose co-ingested or not with glucose. When ingested with other macronutrients, hepatic fructose disposal is similar as when ingested as pure fructose. It induced oxidation, gluconeogenesis followed by glycogen synthesis, conversion into lactate and to a minor extent by de novo lipogenesis. When co- ingested with glucose decreased fructose oxidation as well as gluconeogenesis and an increased glycogen synthesis without affecting de novo lipogenesis or lactate. We were also able to observe induction of intestinal de novo lipogenesis with both fructose and fructose co- ingested with glucose. In summary, essential amino acids supplementation blunted increase in hepatic fat content induced by a short term chronic fructose overfeeding. However, EAA failed to improve other cardiovascular risk factors. Under isocaloric condition and in the frame of an acute test meal, physiologic dose of fructose associated with other macronutrients led to the same fructose disposal as when fructose is ingested alone. When co-ingested with glucose, we observed a decrease in fructose oxidation and gluconeogenesis as well as an increased in glycogen storage without affecting other metabolic pathways. - Une consommation élevée en fructose est associée à l'obésité et aux caractéristiques du syndrome métabolique. Ces dernières incluent une résistance à l'insuline, une dyslipidémie, un diabète de type II et la stéatose hépatique, composant hépatique du syndrome métabolique. À court terme une forte consommation en fructose chez l'homme sain est considérée comme un modèle d'étude pour augmenter la teneur en graisse hépatique. Une supplémentation en protéines ajoutée à une alimentation riche en fructose de courte durée a un effet protecteur sur l'accumulation des graisses au niveau du foie. Le métabolisme du fructose après une charge de fructose aiguë est bien établi. Toutefois, ce dernier est généralement étudié quand une consommation élevée de fructose est donnée. L'interaction du fructose avec d'autres macronutriments sur le métabolisme du fructose n'est pas connue. Nous voulions évaluer la modulation du métabolisme du fructose par des facteurs nutritionnels. Pour la première étude, nous avons abordé la question de savoir quel impact aurait une supplémentation en acides aminés essentiels (AEE) associé à une alimentation riche en fructose sur l'accumulation des graisses hépatiques. Nous avons essayé de distinguer les voies métaboliques responsables de l'augmentation des graisses hépatiques induite par l'alimentation riche en fructose et comment ces voies étaient modulées par les AEE. Après 6 jours d'une alimentation hypercalorique riche en fructose, nous avons observé, comme attendu, une augmentation des graisses hépatiques modulée par une augmentation des triglycérides-VLDL et une augmentation de la production de VLDL-13C-palmitate. Lors de la supplémentation en AEE, nous avons observé une diminution des graisses hépatiques mais les mécanismes responsables de ce processus n'ont pas pu être mis en évidence. Avec la seconde étude, nous nous sommes intéressés à observer le métabolisme du fructose après un repas test contenant des lipides, des protéines et une dose physiologique de fructose co-ingéré ou non avec du glucose. Lorsque le fructose était ingéré avec les autres macronutriments, le devenir hépatique du fructose était similaire à celui induit par du fructose pur. Il a induit une oxydation, suivie d'une néoglucogenèses, une synthèse de glycogène, une conversion en lactate et dans une moindre mesure une lipogenèse de novo. Lors de la co-ngestion avec du glucose, nous avons observé une diminution de l'oxydation du fructose et de la néoglucogenèse et une augmentation de la synthèse du glycogène, sans effet sur la lipogenèse de novo ni sur le lactate. Nous avons également pu mettre en évidence que le fructose et le fructose ingéré de façon conjointe avec du glucose ont induit une lipogenèse de novo au niveau de l'intestin. En résumé, la supplémentation en acides aminés essentiels a contrecarré l'augmentation de la teneur en graisse hépatique induite par une suralimentation en fructose sur le court terme. Cependant, la supplémentation en AEE a échoué à améliorer d'autres facteurs de risque cardiovasculaires. Dans la condition isocalorique et dans le cadre d'un repas test aiguë, la dose physiologique de fructose associée à d'autres macronutriments a conduit aux mêmes aboutissants du métabolisme du fructose que lorsque le fructose est ingéré seul. Lors de la co-ngestion avec le glucose, une diminution de l'oxydation du fructose est de la néoglucogenèse est observée en parallèle à une augmentation de la synthèse de glycogène sans affecter les autres voies métaboliques.

Metabolic effects of fructose in humans

Abstract : Fructose is a simple sugar, whose consumption has increased over the past decades. In rodents, a high-fructose diet (HFrD) induces several features of the metabolic syndrome. The aim of the studies included in this thesis was to investigate the metabolic effects of a HFrD in humans, with a focus on insulin sensitivity and ectopic fat deposition. Moreover, we addressed the question whether these effects may differ between individuals according to gender and the genetic background. The first study was designed to evaluate the impact of a 4-week HFrD on insulin sensitivity and lipid metabolism in 7 healthy men. Insulin sensitivity, intrahepatocellular lipids (IHCL) and intramyocellular lipids (IMCL) contents were measured before and after 1 and 4 weeks of HFrD (1.5 g fructose/kg body weight/day). Insulin sensitivity was assessed by a 2-step hyperinsulinemic euglycemic clamp. IHCL and IMCL were measured by 1H-magnetic resonance spectroscopy (MRS). Fructose caused significant (P<0.05) increases in fasting plasma concentrations of triacylglycerol (TG) (+36%), VLDL-TG (+72%) and glucose (+6%) without any change in body weight, IHCL, IMCL, and insulin sensitivity. In the second study, muscle biopsies were taken from five of these healthy male subjects before and after 4 weeks of HFrD. mRNA concentrations of 18 genes involved in lipid and carbohydrate metabolism were quantified by real-time quantitative PCR. We found that a 4-week HFrD increased the expression of genes involved in lipid synthesis, while it decreased those involved in insulin sensitivity and lipid oxidation; these molecular changes maybe early markers of insulin resistance and altered lipid metabolism. The third study aimed at delineating whether male and females equally respond to a HFrD. For this purpose, higher doses of fructose (twice the dose of the previous study) were provided to 8 healthy young males and 8 healthy young females over 6 days. HFrD significantly increased fasting TG in males (+71 %), whereas this increase was markedly blunted in females (+16%). Males also developed hepatic insulin resistance, characterized by increased hepatic glucose output (+12%), and showed higher alanine aminotransferase concentration (+38%), but none of these effect was observed in females. This study suggests that short-term HFrD leads to hypertriglyceridemia and hepatic insulin resistance in men, but premenopausal women seem protected against these effects. Finally, the fourth study investigated whether healthy offspring of type 2 diabetic patients (OffT2D), a subgroup of individuals prone to metabolic disorders due to their genetic background, may have exacerbated response to HFrD. Eight healthy males (Ctrl) and 16 OffT2D received a HFrD and isocaloric diet in a randomized order. In both groups, HFrD significantly increased IHCL (Ctrl: +76%; OffT2D: +79%) and fasting plasma VLDL-TG (Ctrl: +51 %; OffT2D: +110%). In absolute values, these increments were significantly higher in OffT2D, suggesting that these individuals may be more prone to developing metabolic disorders when challenged by high fructose intake. In order to better delineate the specific effects of fructose vs the hypercaloric energy content, we repeated the complete metabolic investigations after an isocaloric high glucose diet in four of the eight Ctrl volunteers. After a high glucose diet, TG and IHCL concentrations remained similar to the control values, in contrast to the marked increases observed after the HFrD. In conclusion, the studies included in this thesis provided novel insights into the metabolic effects of fructose in humans. They showed that fructose may rapidly increase fasting VLDL-TG, IHCL and lead to hepatic insulin resistance; these effects seem specific to fructose, and potential mechanisms may involve both stimulation of hepatic de novo lipogenesis and decreased lipid oxidation. Moreover, the results suggest that women seem protected against such deleterious effects, while OffT2D displayed exacerbated response. Résumé : Le fructose est un sucre simple, dont la consommation a augmenté durant les dernières décennies. Dans les modèles animaux, un régime riche en fructose (RRFru) peut induire plusieurs composantes du syndrome métabolique. Le but de cette thèse était d'étudier les effets d'un régime riche en fructose sur la sensibilité à l'insuline et la déposition de lipides ectopiques chez l'humain, et si ces effets variaient selon le genre ou le background génétique. La première étude avait pour but d'évaluer l'effet d'un RRFru d'une durée de 4 semaines sur la sensibilité à l'insuline et le métabolisme des lipides chez des hommes sains. La sensibilité à l'insuline, les lipides intrahépatiques (IHCL) et intramusculaires (IMCL) ont été mesurés avant, et après 1 et 4 semaines du RRFru (1.5 g fructose/kg/jour). La sensibilité à l'insuline a été déterminée par un clamp hyperinsulinémique euglycémique, et les IHCL/IMCL par spectroscopie à résonnance magnétique. Le fructose a augmenté les concentrations plasmatiques à jeun des VLDL- triglycérides (TG) (+72%) et de glucose (+6%), sans induire de changement au niveau de la sensibilité à l'insuline, IHCL ou IMCL. Dans la deuxième étude, des biopsies de muscle squelettique ont été prélevées chez cinq de ces volontaires avant et après les 4 semaines de RRFru. Les concentrations de mRNA de 18 gènes impliqués dans le métabolisme des lipides et des hydrates de carbone ont été mesurées par RT-PCR quantitative. Le RRFru a augmenté l'expression de gènes impliqués dans la synthèse de lipides, et diminué celles de gènes impliqués dans la sensibilité à l'insuline et l'oxydation de lipides. Ces changements pourraient constituer des altérations précoces de la sensibilité à l'insuline et du métabolisme lipidique en réponse au fructose. La troisième étude avait pour but de définir si les réponses au RRFru étaient semblables entre les hommes et les femmes. Pour ceci, des doses plus élevées de fructose ont été administrées à 8 jeunes hommes et 8 jeunes femmes durant 6 jours. Le RRFru a augmenté les TG chez les hommes (+71 %), et de manière nettement plus modeste chez les femmes (+16%). Les hommes ont développé une résistance hépatique à l'insuline, ainsi qu'une augmentation des concentrations d'alanine aminotransférase (+38%), mais aucun de ces effets n'a été observé chez les femmes. Cette étude suggère qu'à court terme, un RRFru mène à une hypertriglycéridémie et résistance hépatique à l'insuline chez l'homme, tandis que les femmes semblent en être protégées. Finalement, la 4ème étude a investigué si des personnes apparentées à des patients diabétiques de type 2 (AppDT2), qui constituent un groupe d'individus à risque de développer des maladies métaboliques en raison de leur background génétique, avaient des réponses plus marquées au RRFru. Huit hommes sains (Ctrl) et 16 AppDT2 on reçu dans un ordre randomisé un RRFru et une diète isocalorique durant 6 jours. Dans les deux groupes, le RRFru a augmenté significativement les IHCL (Ctrl: +76%; AppDT2: +79%) et les VLDL-TG plasmatiques à jeun (Ctrl: +51%; AppDT2: +110%). En valeurs absolues, ces deux augmentations étaient plus importantes dans le groupe des AppDT2, suggérant que ces individus sont plus à risque de développer des problèmes métaboliques suite à un apport de fructose. Afin de définir les effets spécifiques du fructose, quatre des huit sujets Ctrl ont été soumis à un régime riche en glucose. Après le régime riche en glucose, les concentrations de TG et d'IHCL étaient semblables aux valeurs obtenues après une diète isocalorique, contrairement aux nombreux effets observés après le RRFru. En conclusion, ces différentes études ont démontré que chez l'humain, le fructose peut rapidement induire une augmentation des VLDL-TG à jeun, des IHCL et une résistance hépatique à l'insuline ; ces effets semblent être spécifiques au fructose. De plus, les différents résultats obtenus montrent que les femmes développent des effets moindres en réponse au fructose, contrairement aux AppDT2, chez qui les effets du fructose semblent plus marqués. Résumé grand public : Le fructose est un sucre simple, présent naturellement et en faibles quantités dans les fruits, mais également constituant du sucrose - appelé aussi sucre de table. Depuis les années 1970, la consommation de fructose a augmenté dans les pays industrialisés et émergents, principalement par le biais d'une hausse de consommation de boissons sucrées de type soda. Dans des modèles animaux tels que les rongeurs, un régime riche en fructose mène au développement de plusieurs facteurs de risques étroitement liés aux maladies cardiovasculaires, à l'obésité et au diabète de type 2; ceux-ci sont caractérisés par une augmentation des concentrations de glucose et de lipides sanguins, ainsi qu'une accumulation de lipides dits « ectopiques », à savoir dans le foie et les muscles. Le but de cette thèse était de définir les effets d'un régime riche en fructose chez l'être humain. De plus, nous nous sommes intéressés à savoir si ces effets étaient semblables entre différents groupes d'individus, à savoir des personnes de sexe masculin / féminin, ou des personnes dont au moins un des parents est diabétique de type 2. Pour ceci, différents groupes de volontaires (hommes, femmes, avec histoire familiale de diabète de type 2) âgés de 18-30 ans se sont soumis à une alimentation enrichie en fructose, d'une durée allant de 6 à 28 jours, suivant l'étude à laquelle ils participaient. La quantité de fructose consommée en plus de l'alimentation normale durant ces périodes équivalait au contenu en fructose de 2-4 litres de boissons sucrées par jour. Des prises de sang ont été effectuées au terme de chacun de ces différents régimes, ainsi que des mesures de sensibilité à l'insuline et de concentrations de lipides dans le foie et le muscle par résonnance magnétique nucléaire, en collaboration avec l'Hôpital de l'Ile de Berne. Les résultats montrent qu'après 6 jours de régime riche en fructose, les volontaires sains de sexe masculin ont presque doublé leurs concentrations de lipides sanguins et hépatiques. De plus, le foie de ces volontaires réagissait moins bien à l'insuline, ce qui pourrait mener à long terme à des maladies métaboliques comme le diabète de type 2. Un des mécanismes postulés est que le fructose pourrait stimuler la formation de lipides dans le foie, contribuant ainsi à un dysfonctionnement de cet organe. De manière surprenante, des femmes d'âge et d'IMC (Indice de Masse Corporelle) comparables aux hommes étudiés n'ont pas développé ces différents effets en réponse au régime riche en fructose. Il semblerait donc qu'elles possèdent certaines propriétés pouvant les «protéger », du moins à court terme, des problèmes métaboliques induits par le fructose. De tels mécanismes sont pour l'heure inconnus, mais il est possible que des différences hormonales, ou de répartition de la masse graisseuse dans le corps, puissent jouer un rôle. Enfin, nous avons également démontré que chez certaines personnes ayant au moins un parent (père ou mère) diabétique de type 2, les augmentations de lipides sanguins et hépatiques induits par le fructose étaient plus marquées que chez des volontaires sans parents diabétiques. Ceci est néanmoins à tempérer par le fait que nous avons observé une grande hétérogénéité des réponses parmi ces individus, découlant certainement d'interactions complexes entre différents facteurs tels que la génétique, le mode de vie, l'alimentation et l'activité physique. Ces différents résultats donnent lieu à une meilleure compréhension du rôle de facteurs alimentaires dans le développement de problèmes métaboliques tels que le diabète de type 2. Ils vont également permettre de tester différentes approches thérapeutiques. Bien qu'ayant été obtenus avec des doses de fructose importantes, ces études soulignent l'effet potentiellement dangereux pour la santé d'une alimentation riche en sucres.

Effects of dexamethasone on hepatic glucose production and fructose metabolism in healthy humans.

This study was designed to determine whether glucocorticoids alter autoregulation of glucose production and fructose metabolism. Two protocols with either dexamethasone (DEX) or placebo (Placebo) were performed in six healthy men during hourly ingestion of[13C]fructose (1.33 mmol.kg-1.h-1) for 3 h. In both protocols, endogenous glucose production (EGP) increased by 8 (Placebo) and 7% (DEX) after fructose, whereas gluconeogenesis from fructose represented 82 (Placebo) and 72% (DEX) of EGP. Fructose oxidation measured from breath 13CO2 was similar in both protocols [9.3 +/- 0.7 (Placebo) and 9.6 +/- 0.5 mumol.kg-1.min-1 (DEX)]. Nonoxidative carbohydrate disposal, calculated as fructose administration rate minus net carbohydrate oxidation rate after fructose ingestion measured by indirect calorimetry, was also similar in both protocols [5.8 +/- 0.8 (Placebo) and 5.9 +/- 2.0 mumol.kg-1.min-1 (DEX)]. We concluded that dexamethasone 1) does not alter the autoregulatory process that prevents a fructose-induced increase in gluconeogenesis from increasing total glucose production and 2) does not affect oxidative and nonoxidative pathways of fructose. This indicates that the insulin-regulated enzymes involved in these pathways are not affected in a major way by dexamethasone.