Effect of fatty Amazon fish consumption on lipid metabolism

Souza, Francisca das Chagas do Amaral; Garcia, Nadja Pinto; Sales, Rejane Souza de Aquino; Aguiar, Jaime Paiva Lopes; Duncan, Wallice Luiz Paxiúba; Carvalho, Rosany Piccolotto

doi:10.1590/1415-52732014000100009

Abstracts

OBJECTIVE:

The present study aimed to evaluate the effect of feeding diets enriched with fatty fish from the Amazon basin on lipid metabolism.

METHODS:

Male Wistar rats were divided into four groups: control group treated with commercial chow; Mapará group was fed diet enriched with Hypophthalmus edentatus; Matrinxã group was fed diet enriched with Brycon spp.; and, Tambaqui group was fed diet enriched with Colossoma macropomum. Rats with approximately 240g±0.60 of body weight were fed ad libitum for 30 days, and then were sacrificed for collection of whole blood and tissues.

RESULTS:

The groups treated with enriched diets showed a significant reduction in body mass and lipogenesis in the epididymal and retroperitoneal adipose tissues and carcass when compared with the control group. However, lipogenesis in the liver showed an increase in Matrinxã group compared with the others groups. The levels of serum triglycerides in the treated groups with Amazonian fish were significantly lower than those of the control group. Moreover, total cholesterol concentration only decreased in the group Matrinxã. High Density Lipoprotein cholesterol levels increased significantly in the Mapará and Tambaqui compared with control group and Matrinxã group. The insulin and leptin levels increased significantly in all treatment groups.

CONCLUSION:

This study demonstrated that diets enriched with fatty fish from the Amazon basin changed the lipid metabolism by reducing serum triglycerides and increasing high density lipoprotein-cholesterol in rats fed with diets enriched with Mapará, Matrinxã, and Tambaqui.

Amazon fishes; Diet; Lipid metabolism; Rats, wistar

OBJETIVO:

Este trabalho avaliou o efeito da alimentação com dietas enriquecidas com peixes gordurosos da região amazônica sobre o metabolismo lipídico.

MÉTODOS:

Ratos machos da linhagem Wistar foram separados em quatro grupos: grupo controle tratados com ração comercial; grupo Mapará, dieta enriquecida com Hypophthalmus edentatus; grupo Matrinxã dieta enriquecida com Brycon spp.; grupo Tambaqui, dieta enriquecida com Colossoma macropomum. Animais com aproxi-madamente 240g±0,60 de massa corporal foram alimentados ad libitum por 30 dias e eutanasiados para coleta do sangue total e tecidos.

RESULTADOS:

Os grupos tratados com dietas enriquecidas apresentaram uma redução significativa na massa corporal e da taxa de lipogênese nos tecidos adiposos epididimal, retroperitoneal e carcaça quando comparados ao grupo controle. No entanto, a taxa de lipogênese do fígado aumentou significativamente no grupo Mapará quando comparados aos demais grupos. A concentração sérica de trigilcerideos dos grupos tratados com os peixes amazônicos foi significativamente menor em relação ao grupo-controle. Por outro lado, o colesterol total redu-ziu significativamente apenas no grupo Mapará. Os níveis de lipoproteína de alta densidade aumentaram de forma significativa nas rações preparadas com Mapará e Tambaqui. Os niveis de insulina e leptina apresentaram aumento significativo em todos os tratamentos em relação ao grupo controle.

CONCLUSÃO:

Este estudo demonstrou que o enriquecimento das dietas com peixes amazônicos gordurosos alterou o metabolismo lipídico em ratos diminuindo a concentração plasmática de triglicerídeos e, concomitantemente, elevando os teores de lipoproteína de alta densidade nos grupos alimentados com dietas enriquecidas com as espécies Mapará, Matrinxã e Tambaqui.

Peixes amazônicos; Dietas; Metabolismo dos lipídeos; Ratos wistar

INTRODUCTION

Obesity is considered a global public health problem in developed and developing countries¹1. Lameu EB, de Oliveira GMM, Godoy PH, Cárcano CBM, Cárcano FM. Catabolismo muscular nos pa-cientes com infarto agudo do miocárdio. Rev SOCERJ. 2005; 18(2):137-40.. Obesity pathophysiology involves complex neuroendocrine and metabolic mechanisms²2. Geloneze B. Síndrome metabólica: mito ou reali-dade? Arq Bra Endocrinol Metab. 2006; 50(3):409-11.. The main processes involved in cardiac diseases are atheroma, thrombogenic, and dietary, and factors that affect lifestyle. High intake of saturated fats, cholesterol, and calories lead to obesity, and therefore, are factors that affect lipid metabolism³3. Assis MAA. Consulta de nutrição: controle e preven-ção do colesterol elevado. Florianópolis: Insular; 1997.. The quantity and nature of the fat ingested daily influence the concentration of plasma cholesterol. High cholesterol levels in the blood are related to the incidence of atherosclerotic vascular diseases, especially coronary diseases⁴4. Gonçalves RC, Faria KRM, Silva PI, Mattar Filho R, Malafaia G. Perfil lipídico e os fatores de risco para a doença aterosclerose em metalúrgicos de Quiri-nópolis-GO. Enciclopédia Biosfera. 2012; 8(14): 1618-2012.. On the other hand, high density lipid cholesterol plays an important role in maintaining the plasma cholesterol levels within a compatible range, since it removes free cholesterol from plasma⁵5. Ajayi OB, Ajayi DD. Effect of oilseed diets on plasma lipid profile in albino rats. Pakistan J Nutr. 2009; 8(2):116-8.. The main function of High Density Lipoprotein (HDL) is to build temporary reserves for total lipids, cholesterol, and apoproteins, protecting against atherosclerosis⁶6. Leichsenring M, Sütterlin N, Less S, Bäuman K, Anninos A, Becker K. Polyunsaturated fatty acids in erythrocyte and plasma lipids of children with severe protein-energy malnutrition. Acta Pediatr. 1995; 84(5):516-20.. Estadella et al. ⁷7. Estadella D, Oyama LM, Damaso AR, Ribeiro EB, Oller do Nascimento CM. Effect o palatable hyperlipidic diet in lipid metabolism os sedentary and exercised rats. Nutrition. 2004; 20(2):218-24., showed that a high-fat or mixed diet promotes a smaller rate of lipogenesis in retroperitoneal adipose and epididymal rat tissues. The accumulation of fat in the tissues and insulin resistance has been associated with dyslipidemia, higher plasma total cholesterol level, Low Density Lipoprotein-cholesterol (LDL-c), Very Low Density Lipoprotein-cholesterol (VLDL-c), triglycerides; and lower HDL-c.

The ability of some foods to reduce cholesterol levels has been investigated in the last decades. Fish lipids are among these components. Since the 1970s, studies have confirmed the role of omega-3 fatty acids, especially Eicosapentaenoic Acid (EPA), in controlling cholesterol and its fractions, and consequently, in preventing cardiovascular diseases⁸8. Costa RP, Menendez G, Bricarello LP, Elias MC, Ito M. Óleo de peixe, fitosteróis, soja e antioxidantes: impacto nos lípides e na aterosclerose. Rev Soc Cardiol. 2000; 10(6):819-27.. Researchers have found that the daily intake of omega-3 fatty acids can reduce the levels of triglycerides from 25% to 30%⁹9. Connor SL, Connor WE. Are fish oils beneficial in the prevention and treatment of coronary artery disease? Am J Clin Nutr. 1997; 66(Suppl):1020S-31S.. Xin et al. ¹⁰10. Xin W, Wei W, Li XY. Short-term effects of fish-oil supplementation on heart rate variability in humans: A meta-analysis of randomized controlled trials. Am J Clin Nutr. 2013; 97(5):926-35. state that short-term fish oil supplementation can have a favorable influence on the frequency domain of the heart rate variability.

The nature and amount of dietary lipids protect against and/or promote cardiovascular problems, and considering the high seafood intake in the Brazilian North region, this study aimed to examine whether diets containing fatty fish from the Amazon region, such as: mapará (Hypophthalmus edentatus), matrinxã (Brycon spp.), and tambaqui (Colossomoa macropomum) affect lipid metabolism in Wistar rats.

METHODS

Animals

Forty adult male Wistar (Rattus norvegicus) rats weighing approximately 240±0.60 grams, from the animal facility of the Universidade Federal do Amazonas (UFAM) were divided into four groups according to diet: Control Group (CG), Mapará Group (GMAP), Matrinxâ Group (GMAT), and Tambaqui Group (GTAB). All animals were kept in individual cages under a temperature of 24^oC to 28^oC and 12/12-hour light-dark cycle. The animals had free access to food and water. The experimental period lasted 30 days. The study was approved by the Animal Ethics Committee of the UFAM under Protocol 00014/12.

Preparation of the diets

The fish were transported to the Coorde-nação de Pesquisas em Tecnologia do Alimento/Instituto Nascional de Pesquisas da Amazônia (CPTA-INPA) where they were filleted and submitted to mechanical muscle separation in a German Baader model 694 separator. The resultant meat was distributed in rectangular metal trays and frozen to -30^oC. The frozen blocks weighting roughly 7kg and having a width of 5cm each were cut with an electric band saw in portions of roughly 500g and wrapped in polyethylene film. The frozen blocks were placed in isothermal boxes containing ice, transported to the Physiology Laboratory of UFAM and stored at -18±1°C. The Amazon fish-based diet consisted of Labina chow (72.5%), casein (12.5%), and mechanically separated meat of each species (15.0%). All components were ground and mixed. The final composition of each chow was approximately 22.0% proteins, 10.5% fats, 40.0% carbohydrates, and 16.0% fibers (Table 1). The caloric density determined by an adiabatic calorimeter (IKA-C400) was approximately 251.40kJ/g±0.30kJ/g (35.0% calories as fats) for each palatable high-fat diet, and 17.03kJ/g for the standard diet.

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Table 1
Percent macronutrients (%) and total fatty acids in the Control (C) diet, diet enriched with ground Mapará (MAP), ground Matrinxã (MAT), and ground Tambaqui (TAB). Manaus (AM), Brazil, 2012.

Experimental Procedure

Body weight and food intake

The rats' food intake and body mass were assessed daily for 30 days. Energy intake was determined by multiplying food intake by energy density. At the end of 30 days, the forty rats were sacrificed by decapitation and the total blood extracted. Next, this material was centrifuged at 7500rpm for 2 minutes in an Eppendorf Model 5415 centrifuge. After one hour, an intraperitoneal injection of 3mCi ³3. Assis MAA. Consulta de nutrição: controle e preven-ção do colesterol elevado. Florianópolis: Insular; 1997.H₂O in a volume of 0.3mL was given for determining the rate of lipogenesis in vivo. Total blood was collected. The carcass and the tissues liver, Retroperitoneal Adipose (RET), and Epididymal (EPI) were immediately weighed. In vivo lipogenesis was determined by the incorporation of ³3. Assis MAA. Consulta de nutrição: controle e preven-ção do colesterol elevado. Florianópolis: Insular; 1997.H₂O in saponified lipids according to the Robinson and Williamson method¹¹11. Robinson AM, Williamson DH. Control of glucose metabolism in isolated acini of the lactating mammary gland of rat: Effects of oleate on glucose utilization and lipogenesis. Biochem J. 1978; 170(3):609-13.. The tissue samples were digested in 3.0mL of 30% KOH and 3.0mL of ethanol during 2h at 70^oC. After cooling, 2.0mL of H₂SO₄ 12N was added and the lipids were extracted with 10.0mL of ether in petroleum¹²12. Stanbie D, Browsey RW, Crettaz M, Denton RM. Acute effects in vivo of anti-insulin serum on rates of fatty acid synthesis and activities of acetylcoenzyme a carboxylase and pyruvate dehydrogenase in liver and epididymal adipose tissue of fed rats. Biochem J. 1976; 160(2):413-26.. This extract was washed with 2.0mL of distilled water and evaporated until dry. The radioactivity of 20µL of the serum in the samples was used to determine specific activity. The rate of lipogenesis was calculated as micromoles ³3. Assis MAA. Consulta de nutrição: controle e preven-ção do colesterol elevado. Florianópolis: Insular; 1997.H₂O of lipids incorporated by gram by hour. The lipid content of the tissue was determined by the gravimetric method¹³13. Oller do Nascimento CM, Williamson DH. Evidence for conservation of dietary lipid in the rat during lactation and the immediate period after removal of the litter. Biochem J. 1986; 239(1):233-6.. The glycogen¹⁴14. Johann G, Lentini EA. Simultaneous determination of glycogen and lipids from heart muscle. Anal Biochem. 1979; 43(1):183-7. content of the liver was determined by the anthrone method - H₂SO₄. Plasma was obtained by centrifugation and aliquots were used for measuring glucose, triglycerides, total lipids, cholesterol, high-density lipoprotein, insulin, and leptin. For these measurements, Doles (Brazil) kits were used. The concentration of insulin (Coat-A- Count DPC MedLab, CA, USA) and leptin (Linco Research, INC, MO, USA) were determined by radioimmunoassay kits.

Statistical analysis

The statistical tests were one-way Analysis of Variance (Anova) followed by the Tukey test. The differences were considered significant when p<0.05.

RESULTS

Diet composition

The percent macronutrient composition and fatty acids of the total lipid content of the CG, GMAP, GMAT, and GTAB diets are shown in Table 1; we see that the total protein content did not differ significantly between the groups. The percentage of carbohydrates in the CG group was statistically smaller than that of the groups fed Amazon fish, except for the group GMAP. Regarding fibers present in the percent composition of the diets, the CG had the lowest percentage. The GMAP group had higher fiber percentage than the groups GMAT and GTAB. The GMAP group had a higher lipid percentage than groups CG, GMAT, and GTAB. The CG fatty acids have a higher percentage of linolenic and linoleic acids. The GMAP was the only group with Docosahexaenoic (DHA) and EPA.

Weight gain, energy value, metabolic efficiency, and fat content

Table 2 shows that the fat content of the carcass in the groups fed diets with 15% meat was smaller than that of the control. However, the fat content of the carcass of groups GMAT and GTAB did not differ from each other, but both were higher than GMAP. The measure of the masses of the adipose epididymal and retroperitoneal tissues and liver of the GMAT, GMAP, and GTAB groups were greater than those of the control group. The CG consumed less energy than the other groups. On the other hand, the GMAP group had greater total energy intake than the GTAB and GMAT. GTAB total energy intake was significantly higher than that of GMAT. The control group gained more weight than the groups GTAB and GMAP. The metabolic efficiency of the control group was lower than that of the other groups. On the other hand, the GTAB group had a metabolic efficiency greater than the GMAP and GMAT groups. The GMAT had a lower metabolic efficiency than the group GMAP.

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Table 2
Body weight gain (f), total energy intake (kJ), metabolic efficiency (kJ/g of body weight gain), fat content of the carcass (g/100g), Retroperitoneal (RET) adipose tissue mass, Epididymal (EPI) adipose tissue mass, and liver mass of rats fed control diet and diets enriched with Ground Mapará (GMAP); Ground Matrinxã (GMAT) or Ground Tambaqui (GTAB). Manaus (AM), Brazil, 2012.

Lipogenesis

In the CG's, GMAP's, and GTAB's livers, the rate of lipogenesis was similar (Table 3). However, the GMAT group had a higher rate of liver lipogenesis than the GMAP, GTAB, and CG groups. The lipogenesis rates of the GMAP, GMAT, and GTAB were lower than those of the CG group. The animals in the GMAP, GMAT, and GTAB groups had lower RET and EPI adipose tissue lipogenesis than the CG. However, the lipogenesis rate of the EPI adipose tissue of the GMAT group was higher than that of the groups GTAB and GMAP.

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Table 3
In vivo lipogenesis rate (µmol 3H2O incorporated in lipids/g of tissues.h) in the Epididymal (EPI) and Retroperitoneal (RET) adipose tissues, liver, and carcass of the rats fed a control diet and diets enriched with Ground Mapara (GMAP); Ground Matrinxa (GMAT) or Ground Tambaqui (GTAB). Manaus (AM), Brazil, 2012.

Plasma metabolites

Table 4 shows that the total cholesterol and total protein contents did not change in the groups treated with the enriched diets with respect to the Control group. The groups GMAP, GMAT, and GTAB presented a significant reduction in plasma Triglyceride (TG) levels compared with the Control group. The groups GMAP and GTAB presented a significant increase in HDL-c when compared with the control and GMAT groups. Additionally, the plasma glucose of group GTAB decreased significantly when compared with the groups GMAT, GMAP, and CG. The increase in the glucose levels of the group GMAP was greater than that of the other groups. However, plasma insulin did not change significantly in any of the groups. Leptin in the CG was significantly lower than in the treated groups (Table 4).

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Table 4
Serum levels of glucose, Triglycerides (TG), total lipids, total cholesterol, LDL-c, VLDL-c, HDL-c, total proteins expressed as (mg/ dL) and leptin (ng/mL) of rats fed a control diet and diets enriched with Ground Mapará (GMAP); Ground Matrinxã (GMAT) or Ground Tambaqui (GTAB). Manaus (AM), Brazil, 2012.

DISCUSSION

In the literature the effect of high-fat diet on body weight is very controversial¹⁵15. Abadie JM, Malcom GT, Porter JR, Svec F. Can associations between free fatty acid levels and metabolic parameters determine insulin resistance development in obese Zucker rats? Life Sci. 2001; 69(22):2675-83. ^, ¹⁶16. Gurnell M, Savage DB, Chatterjee VK, O'Rahilly S. The metabolic syndrome: Peroxisome proliferator-activated receptor gamma and its therapeutic modulation. J Clin Endocrinol Metab. 2003; 88(6): 2412-21., especially of rats fed diets high in saturated fats and omega-6 polyunsaturated fats¹⁷17. Gaíva MH, Couto RC, Oyama,LM, Couto GE, Silveira VL, Ribeiro EB, et al. Polyinsaturated fatty acid-rich diets: Effect on adipose tissue metabolism in rats. Br J Nutr. 2001; 86(3):371-7.. The degree of satiety promoted by high-fat diet depends on their physical and chemical properties (chain length, saturation, and conjugation), its carbohydrates, and its palatability¹⁸18. French S, Robinson T. Fats and food intake. Curr Opin Clin Nutr Metab Care. 2003; 6(6):629-34.. These factors may influence the release of inhibitory gastrointestinal peptides such as cholecystokinin, enterostatin, and apoprotein A-IV¹⁹19. Beglinger C, Degen L. Fat in the intestine as a regulator of appetite-tole of CCK. Physiol Behav. 2004; 83(4):617-21. ^, ²⁰20. Tso P, Liu M. Apolipoprotein A-IV, food intake, and obesity. Physiol Behav. 2004; 83(4):631-43. and also the digestion, absorption, and metabolic rates. Himaya et al. ²¹21. Himaya A, Fantino M, Antoine JM, Brondel L, Louis-Sylvestre J. Satiety power of dietary fat: A new apprasial. Am J Clin Nutr. 1997; 65(5):1410-8. reported that the time of satiety in high-fat diets is longer in diets high in carbohydrates because of the higher levels of plasma metabolite substrates such as glucose, TG, and fatty acids. These results may partly explain the fact that Wistar rats present lower intake of diets enriched with mapará (Hypophthalmus edentatus), the fish with the highest lipid content. On the other hand, the rats fed matrinxã (Brycon spp.) consumed as much food as the controls.

Other studies have reported that rats kept with diets enriched with polyunsaturated and saturated fish oil did not vary their food intake²²22. Keelan M, Clandinin MT, Thompson ABR. Refeeding varyning fatty acid and cholesterol diets alters phospholipids in rat intestinal brush border membrane. Lipids. 1997; 32(8):895-905.. Interestingly, in past decades, this dietary practice of feeding high-fat diet was used as strategy to control obesity, but with little success, since in general this type of diet has high energy content leading to body weight gain²¹21. Himaya A, Fantino M, Antoine JM, Brondel L, Louis-Sylvestre J. Satiety power of dietary fat: A new apprasial. Am J Clin Nutr. 1997; 65(5):1410-8.. This is in agreement with the group that was fed the diet enriched with matrinxã, which gained more weight than the other groups. The intake of each macronutrient seems to be under strict control to maintain oxidation and the balance status. In case of fats, the adjustment is much less precise and higher intake does not stimulate proportional oxidation. The oxidation rate of fatty acids may also be another factor that controls food intake²³23. Leonhardt M, Langhans W. Fatty acid oxidation and control of food intake. Physiol Behav. 2004; 83(4): 645-51.. The accumulation of fats in tissues and the presence of insulin resistance has been associated with dyslipidemias, increase in the plasma level of total cholesterol, LDL-c, VLDL-c, IDL-c, TG, and low HDL-c. Hence, many studies have reported that obesity, dyslipidemia, diabetes type II, high blood pressure, and cardiovascular diseases lead to interrelated metabolic changes known as plurimetabolic syndrome²⁴24. National Cholesterol Education Program. Detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III). Final report. Bethesed (MD): National Heart, Lung, and Blood Institute, 2002 Sept. Report nº 02-5215.. Nieves et al.²⁵25. Nieves DJ, Cnop M, Retzlaff B, Walden CE, Brunzell JD, Knopp RH, et al. The atherogenic lipoprotein profile associated with obesity and insulin resistance is largely attributable to intra-abdominal fat. Diabetes. 2003; 52(4):172-9. indicate that the lipoprotein profile present seem to result primarily from the increase in central fat probably due to the development of insulin resistance. The reduction of abdominal fat by medication or lifestyle changes or dietary changes or more physical activity could contribute to improve the lipid profile, and avoid the development of atherosclerosis. Suprijana et al.²⁶26. Suprijana O, Terpstra AHM, Van Lith HA, Van Tol A, Lemmens AG, Geelhoed-Mieras MM. Plasma lipids and apolipoproteins in rats fed diets with type of fat (fish oil versus corn oil) and fiber (pectin versus cellulose) as vaiables. Nutr Res. 1997; 17(7):1187-97. found a reduction in the levels of TG, total cholesterol, and lipoprotein fractions in rats fed diets enriched with fish oil, which was later observed also by Kim et al.²⁷27. Kim HK, Choi S, Choi H. Suppression of hepatic fatty acid synthase by feeding a-linolenic acid rich Perilla oil lowers plasma triacylglycerol level in rats. J Nutr Biochem. 2004; 15(8):485-92..

Similarly, the results observed in this study show that the intake of fatty Amazon fish reduced TG and cholesterol levels. The effects caused by high-fat diets on the metabolism of animals may be influenced by the type of lipids²⁸28. Brooks SP, Lampi BJ. Effects of dietary fat on whole body fatty aci syntesis in weanling rats. J Nutr. Biochem. 1999; 10(5):291-8., gender, and treatment period¹⁷17. Gaíva MH, Couto RC, Oyama,LM, Couto GE, Silveira VL, Ribeiro EB, et al. Polyinsaturated fatty acid-rich diets: Effect on adipose tissue metabolism in rats. Br J Nutr. 2001; 86(3):371-7. ^, ²³23. Leonhardt M, Langhans W. Fatty acid oxidation and control of food intake. Physiol Behav. 2004; 83(4): 645-51.. Patients treated with fish oil rich in omega-6 fatty acids have experienced lower total cholesterol, LDL-c, TG, and VLDL²⁹29. Charman A, Muriithi EW, Milne E, Wheatley DJ, Armstrong RA, Belcher PR. Fish oil before cardiac surgery: Neutrophil activation is unaffected but myocardial damage is moderated. Prostaglandins Leukot Essent Fatty Acids. 2005; 72(4):257-65., and higher HDL-c²⁹29. Charman A, Muriithi EW, Milne E, Wheatley DJ, Armstrong RA, Belcher PR. Fish oil before cardiac surgery: Neutrophil activation is unaffected but myocardial damage is moderated. Prostaglandins Leukot Essent Fatty Acids. 2005; 72(4):257-65. ^, ³⁰30. Singer P. Fluvastantin plus fish oil are more effective on cardiovascular risk factors than fluvastatin alone. Prostaglandins Leukot Essent Fatty Acids. 2005; 13(22):123-5.. Similarly, the total cholesterol and TG of the rats fed diets enriched with Amazon fish decreased and the HDL of rats fed diets enriched with mapará and tambaqui increased - these fish contain omega-6 and omega-3 fatty acids. The plasma glucose levels did not differ significantly from those of the control group, which was also observed by Simão et al. ³¹31. Simão ANC, Godeny P, Lozovoy MAB, Dichi JB, Dich I. Efeito dos ácidos graxos n-3 no perfil glicêmico e lipídico, no estresse oxidativo e na capacidade an-tioxidante total de pacientes com síndrome meta-bólica. Arq Bra Endocrinol Metab. 2010; 54(5): 463-69. and Wilkson et al. ³²32. Wilkinson P, Leach C, Ah-Sing EE, Hussain N, Miller GJ, Millward DJ, et al. Influence of alpha-linolenic acid and fish-oil on markers of cardiovascular risk in subjects with an atherogenic lipoprotein phenotype. Atherosclerosis. 2005; 181(1):115-24.while supplementing a human diet with fish oil. Mortiz et al. ³³33. Moritz B, Wazlawik E, Minatti J, Miranda RCD. Interferência dos ácidos graxos ômega-3 nos lipí-deos sangüíneos de ratos submetidos ao exercício de natação. Rev Nutr. 2008; 21(6):659-69. doi: 10.1590/S1415-52732008000600005
https://doi.org/10.1590/S1415-5273200800... stated that rats fed with chow enriched with fish oil tended to have lower blood glucose, total cholesterol, and LDL-c and higher TG than the control group. Many works have showed that lipid metabolism is regulated by leptin, a protein hormone produced mainly by adipose tissue³⁴34. Iritani N, Sugimoto T, Fukuda H. Gene expression of leptin, insulin receptors and lipogenic enzymes are coordinately regulated by insulin and dietary fat in rats. J Nutr. 2000; 130(5):1183-8.. According to Nogalska et al. ³⁵35. Nogalska A, Sucajtys-Szulc E, Swierczynski J. Leptin decreases lipogenic enzyme gene expression through modification of SREBP-1c gene expression in white adipose tissue of aging rats. Metabolism. 2005; 54(8):1041-7. higher expression of the leptin gene partially clarifies the low lysogenic activity of the white adipose tissue of old animals. This finding corroborates our studies which showed low lipogenesis in the adipose tissues and concomitant leptin increase in the rats fed enriched chow.

In conclusion, this study found that diets enriched with fatty Amazon fish changed the lipid metabolism of rats effectively lowering plasma lipids (cholesterol, TG, and LDL) and increasing HDL. These results suggest that regular consumption of fish with these characteristics is beneficial.

ACKNOWLEDGMENTS

The authors thank Fundação de Amparo a Pesquisa do Amazonas (Process 3008/10) and the Instituto Nacional de Pesquisa da Amazônia.

REFERENCES

¹
Lameu EB, de Oliveira GMM, Godoy PH, Cárcano CBM, Cárcano FM. Catabolismo muscular nos pa-cientes com infarto agudo do miocárdio. Rev SOCERJ. 2005; 18(2):137-40.
²
Geloneze B. Síndrome metabólica: mito ou reali-dade? Arq Bra Endocrinol Metab. 2006; 50(3):409-11.
³
Assis MAA. Consulta de nutrição: controle e preven-ção do colesterol elevado. Florianópolis: Insular; 1997.
⁴
Gonçalves RC, Faria KRM, Silva PI, Mattar Filho R, Malafaia G. Perfil lipídico e os fatores de risco para a doença aterosclerose em metalúrgicos de Quiri-nópolis-GO. Enciclopédia Biosfera. 2012; 8(14): 1618-2012.
⁵
Ajayi OB, Ajayi DD. Effect of oilseed diets on plasma lipid profile in albino rats. Pakistan J Nutr. 2009; 8(2):116-8.
⁶
Leichsenring M, Sütterlin N, Less S, Bäuman K, Anninos A, Becker K. Polyunsaturated fatty acids in erythrocyte and plasma lipids of children with severe protein-energy malnutrition. Acta Pediatr. 1995; 84(5):516-20.
⁷
Estadella D, Oyama LM, Damaso AR, Ribeiro EB, Oller do Nascimento CM. Effect o palatable hyperlipidic diet in lipid metabolism os sedentary and exercised rats. Nutrition. 2004; 20(2):218-24.
⁸
Costa RP, Menendez G, Bricarello LP, Elias MC, Ito M. Óleo de peixe, fitosteróis, soja e antioxidantes: impacto nos lípides e na aterosclerose. Rev Soc Cardiol. 2000; 10(6):819-27.
⁹
Connor SL, Connor WE. Are fish oils beneficial in the prevention and treatment of coronary artery disease? Am J Clin Nutr. 1997; 66(Suppl):1020S-31S.
¹⁰
Xin W, Wei W, Li XY. Short-term effects of fish-oil supplementation on heart rate variability in humans: A meta-analysis of randomized controlled trials. Am J Clin Nutr. 2013; 97(5):926-35.
¹¹
Robinson AM, Williamson DH. Control of glucose metabolism in isolated acini of the lactating mammary gland of rat: Effects of oleate on glucose utilization and lipogenesis. Biochem J. 1978; 170(3):609-13.
¹²
Stanbie D, Browsey RW, Crettaz M, Denton RM. Acute effects in vivo of anti-insulin serum on rates of fatty acid synthesis and activities of acetylcoenzyme a carboxylase and pyruvate dehydrogenase in liver and epididymal adipose tissue of fed rats. Biochem J. 1976; 160(2):413-26.
¹³
Oller do Nascimento CM, Williamson DH. Evidence for conservation of dietary lipid in the rat during lactation and the immediate period after removal of the litter. Biochem J. 1986; 239(1):233-6.
¹⁴
Johann G, Lentini EA. Simultaneous determination of glycogen and lipids from heart muscle. Anal Biochem. 1979; 43(1):183-7.
¹⁵
Abadie JM, Malcom GT, Porter JR, Svec F. Can associations between free fatty acid levels and metabolic parameters determine insulin resistance development in obese Zucker rats? Life Sci. 2001; 69(22):2675-83.
¹⁶
Gurnell M, Savage DB, Chatterjee VK, O'Rahilly S. The metabolic syndrome: Peroxisome proliferator-activated receptor gamma and its therapeutic modulation. J Clin Endocrinol Metab. 2003; 88(6): 2412-21.
¹⁷
Gaíva MH, Couto RC, Oyama,LM, Couto GE, Silveira VL, Ribeiro EB, et al. Polyinsaturated fatty acid-rich diets: Effect on adipose tissue metabolism in rats. Br J Nutr. 2001; 86(3):371-7.
¹⁸
French S, Robinson T. Fats and food intake. Curr Opin Clin Nutr Metab Care. 2003; 6(6):629-34.
¹⁹
Beglinger C, Degen L. Fat in the intestine as a regulator of appetite-tole of CCK. Physiol Behav. 2004; 83(4):617-21.
²⁰
Tso P, Liu M. Apolipoprotein A-IV, food intake, and obesity. Physiol Behav. 2004; 83(4):631-43.
²¹
Himaya A, Fantino M, Antoine JM, Brondel L, Louis-Sylvestre J. Satiety power of dietary fat: A new apprasial. Am J Clin Nutr. 1997; 65(5):1410-8.
²²
Keelan M, Clandinin MT, Thompson ABR. Refeeding varyning fatty acid and cholesterol diets alters phospholipids in rat intestinal brush border membrane. Lipids. 1997; 32(8):895-905.
²³
Leonhardt M, Langhans W. Fatty acid oxidation and control of food intake. Physiol Behav. 2004; 83(4): 645-51.
²⁴
National Cholesterol Education Program. Detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III). Final report. Bethesed (MD): National Heart, Lung, and Blood Institute, 2002 Sept. Report nº 02-5215.
²⁵
Nieves DJ, Cnop M, Retzlaff B, Walden CE, Brunzell JD, Knopp RH, et al. The atherogenic lipoprotein profile associated with obesity and insulin resistance is largely attributable to intra-abdominal fat. Diabetes. 2003; 52(4):172-9.
²⁶
Suprijana O, Terpstra AHM, Van Lith HA, Van Tol A, Lemmens AG, Geelhoed-Mieras MM. Plasma lipids and apolipoproteins in rats fed diets with type of fat (fish oil versus corn oil) and fiber (pectin versus cellulose) as vaiables. Nutr Res. 1997; 17(7):1187-97.
²⁷
Kim HK, Choi S, Choi H. Suppression of hepatic fatty acid synthase by feeding a-linolenic acid rich Perilla oil lowers plasma triacylglycerol level in rats. J Nutr Biochem. 2004; 15(8):485-92.
²⁸
Brooks SP, Lampi BJ. Effects of dietary fat on whole body fatty aci syntesis in weanling rats. J Nutr. Biochem. 1999; 10(5):291-8.
²⁹
Charman A, Muriithi EW, Milne E, Wheatley DJ, Armstrong RA, Belcher PR. Fish oil before cardiac surgery: Neutrophil activation is unaffected but myocardial damage is moderated. Prostaglandins Leukot Essent Fatty Acids. 2005; 72(4):257-65.
³⁰
Singer P. Fluvastantin plus fish oil are more effective on cardiovascular risk factors than fluvastatin alone. Prostaglandins Leukot Essent Fatty Acids. 2005; 13(22):123-5.
³¹
Simão ANC, Godeny P, Lozovoy MAB, Dichi JB, Dich I. Efeito dos ácidos graxos n-3 no perfil glicêmico e lipídico, no estresse oxidativo e na capacidade an-tioxidante total de pacientes com síndrome meta-bólica. Arq Bra Endocrinol Metab. 2010; 54(5): 463-69.
³²
Wilkinson P, Leach C, Ah-Sing EE, Hussain N, Miller GJ, Millward DJ, et al. Influence of alpha-linolenic acid and fish-oil on markers of cardiovascular risk in subjects with an atherogenic lipoprotein phenotype. Atherosclerosis. 2005; 181(1):115-24.
³³
Moritz B, Wazlawik E, Minatti J, Miranda RCD. Interferência dos ácidos graxos ômega-3 nos lipí-deos sangüíneos de ratos submetidos ao exercício de natação. Rev Nutr. 2008; 21(6):659-69. doi: 10.1590/S1415-52732008000600005
» https://doi.org/10.1590/S1415-52732008000600005
³⁴
Iritani N, Sugimoto T, Fukuda H. Gene expression of leptin, insulin receptors and lipogenic enzymes are coordinately regulated by insulin and dietary fat in rats. J Nutr. 2000; 130(5):1183-8.
³⁵
Nogalska A, Sucajtys-Szulc E, Swierczynski J. Leptin decreases lipogenic enzyme gene expression through modification of SREBP-1c gene expression in white adipose tissue of aging rats. Metabolism. 2005; 54(8):1041-7.

Publication Dates

Publication in this collection
Jan-Feb 2014

History

Received
21 May 2013
Reviewed
04 Nov 2013
Accepted
21 Dec 2013

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[17] ¹⁷
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[18] ¹⁸
French S, Robinson T. Fats and food intake. Curr Opin Clin Nutr Metab Care. 2003; 6(6):629-34.

[19] ¹⁹
Beglinger C, Degen L. Fat in the intestine as a regulator of appetite-tole of CCK. Physiol Behav. 2004; 83(4):617-21.

[20] ²⁰
Tso P, Liu M. Apolipoprotein A-IV, food intake, and obesity. Physiol Behav. 2004; 83(4):631-43.

[21] ²¹
Himaya A, Fantino M, Antoine JM, Brondel L, Louis-Sylvestre J. Satiety power of dietary fat: A new apprasial. Am J Clin Nutr. 1997; 65(5):1410-8.

[22] ²²
Keelan M, Clandinin MT, Thompson ABR. Refeeding varyning fatty acid and cholesterol diets alters phospholipids in rat intestinal brush border membrane. Lipids. 1997; 32(8):895-905.

[23] ²³
Leonhardt M, Langhans W. Fatty acid oxidation and control of food intake. Physiol Behav. 2004; 83(4): 645-51.

[24] ²⁴
National Cholesterol Education Program. Detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III). Final report. Bethesed (MD): National Heart, Lung, and Blood Institute, 2002 Sept. Report nº 02-5215.

[25] ²⁵
Nieves DJ, Cnop M, Retzlaff B, Walden CE, Brunzell JD, Knopp RH, et al. The atherogenic lipoprotein profile associated with obesity and insulin resistance is largely attributable to intra-abdominal fat. Diabetes. 2003; 52(4):172-9.

[26] ²⁶
Suprijana O, Terpstra AHM, Van Lith HA, Van Tol A, Lemmens AG, Geelhoed-Mieras MM. Plasma lipids and apolipoproteins in rats fed diets with type of fat (fish oil versus corn oil) and fiber (pectin versus cellulose) as vaiables. Nutr Res. 1997; 17(7):1187-97.

[27] ²⁷
Kim HK, Choi S, Choi H. Suppression of hepatic fatty acid synthase by feeding a-linolenic acid rich Perilla oil lowers plasma triacylglycerol level in rats. J Nutr Biochem. 2004; 15(8):485-92.

[28] ²⁸
Brooks SP, Lampi BJ. Effects of dietary fat on whole body fatty aci syntesis in weanling rats. J Nutr. Biochem. 1999; 10(5):291-8.

[29] ²⁹
Charman A, Muriithi EW, Milne E, Wheatley DJ, Armstrong RA, Belcher PR. Fish oil before cardiac surgery: Neutrophil activation is unaffected but myocardial damage is moderated. Prostaglandins Leukot Essent Fatty Acids. 2005; 72(4):257-65.

[30] ³⁰
Singer P. Fluvastantin plus fish oil are more effective on cardiovascular risk factors than fluvastatin alone. Prostaglandins Leukot Essent Fatty Acids. 2005; 13(22):123-5.

[31] ³¹
Simão ANC, Godeny P, Lozovoy MAB, Dichi JB, Dich I. Efeito dos ácidos graxos n-3 no perfil glicêmico e lipídico, no estresse oxidativo e na capacidade an-tioxidante total de pacientes com síndrome meta-bólica. Arq Bra Endocrinol Metab. 2010; 54(5): 463-69.

[32] ³²
Wilkinson P, Leach C, Ah-Sing EE, Hussain N, Miller GJ, Millward DJ, et al. Influence of alpha-linolenic acid and fish-oil on markers of cardiovascular risk in subjects with an atherogenic lipoprotein phenotype. Atherosclerosis. 2005; 181(1):115-24.

[33] ³³
Moritz B, Wazlawik E, Minatti J, Miranda RCD. Interferência dos ácidos graxos ômega-3 nos lipí-deos sangüíneos de ratos submetidos ao exercício de natação. Rev Nutr. 2008; 21(6):659-69. doi: 10.1590/S1415-52732008000600005
» https://doi.org/10.1590/S1415-52732008000600005

[34] ³⁴
Iritani N, Sugimoto T, Fukuda H. Gene expression of leptin, insulin receptors and lipogenic enzymes are coordinately regulated by insulin and dietary fat in rats. J Nutr. 2000; 130(5):1183-8.

[35] ³⁵
Nogalska A, Sucajtys-Szulc E, Swierczynski J. Leptin decreases lipogenic enzyme gene expression through modification of SREBP-1c gene expression in white adipose tissue of aging rats. Metabolism. 2005; 54(8):1041-7.

Macronutrients	GC	GMAP	GMAT	GMAP
Proteins	22.4^a	22.3^a	22.6^a	23.7^a
Carbohydrates	39.1^a	38.2^a	41.3 ^c	40.3 ^d
Fibers	11.4^a	16.7 ^b	15.0 ^c	16.0 ^d
Lipids	4.8^a	11.8 ^b	10.0^c	9.9 ^c
Palmitic (16:9)	20.4^a	23.93 ^b	24.58^C	24.8^c
Oleic (18:1n-9)	27.4^a	24.55 ^b	27.9 ^a	38.85^d
Stearic (18:0)	5.12^a	7.65 ^b	6.93 ^a	9.84^c
Palmitoleic (16:1n-7)	-	3.56 ^b	7.5^c	1.72 ^d
Linolenic (18:3n-3)	9.91^a	3.76 ^b	2.35^c	2.66^c
Linoleic (18:2n-6)	41.0^a	11.11 ^b	18.52^c	18.62^c
Myristic (14:0)	2.07 ^a	0.56 ^b	2.46 ^a	0.66 ^b
Docosahexaenoic (22:6n-3)	-	2.9	-	-
Eicosapentaenoic (20:5n-3)	-	2.4	-	-

Variables		CG	GMAP			GMAT			GTAB

	M	SD	M	SD		M	SD		M	SD
	M	SD	M	SD		M	SD		M	SD

Body weight gain	0080.30	006.78^a0	0066.98^b	003.34^b00	0070.08		0005.24^c00	0056.75		005.26 ^d0
Total energy intake	6840.40	153.9^a00	7910.6^a0	183.2^b000	7284.30		183.3^c000	7441.10		188.5 ^d00
Metabolic efficiency	0096.44	007.07^a0	0119.72^a	004.43 ^b00	0107.44		0006.47^c00	0144.17		14.52 ^d
Fat content of the carcass	0008.20	000.025^a	000 3.78^a	001.56^c00	0005.53		0005.00^b00	0004.01		000.89 ^b0
EPI mass	0000.86	000.025^a	000 1.04^a	000.0006^b	0001.04		0000.0006^b	0001.02		000.008^b
RET mass	0000.65	000.06^a0	00 01.05^b	000.007^b0	0001.05		0000.006^b0	0000.99		000.027^b
Liver mass	0009.08	000.300^a	00 11.59^a	000.007^b0	0011.66		0000.442^b0	0011.05		000.250 ^b

Tissues		CG			GMAP		GMAT				GTAB

	M	SD		M	SD		M	SD		M	SD
	M	SD		M	SD		M	SD		M	SD

EPI	34.46	39.88^a	3.42		0.79^b	04.6		2.04^c	3.28		0.82^b
RET	12.92	09.9^a0	3.73		1.47^b	03.64		0.84^b	3.76		1.41^b
Liver	08.24	02.22^a	7.63		2.64^a	15.52		8.82^b	9.40		2.08^a
Carcass	07.71	04.83^a	1.30		0.43^b	01.42		0.55^b	1.67		0.32^b

Tissues		CG		GMAP			GMAT			GTAB

	M	SD		M	SD		M	SD		M	SD
	M	SD		M	SD		M	SD		M	SD

Glucose	139.87	8.87^a	154.28		7.60^bb	134.24		4.20^ac	117.34		4.18^d
TG	060.43	4.08^a	040.55		3.62^bb	044.62		4.98^bb	038.96		4.49^b
Total cholesterol	076.28	4.44^a	067.33		5.84^ab	059.39		3.80^ab	065.68		4.33^a
HDL-c	008.79	0.81^a	013.67		1.11^bb	007.08		0.96^ab	011.44		1.38^b
Total proteins	004.68	0.42^a	004.81		0.43^ab	004.29		0.14^ab	004.23		0.17^a
Leptin	001.63	0.26^a	004.38		0.65^ab	003.90		0.42^ac	006.34		1.70^c
Insulin	011.75	1.32^a	014.14		2.56^ab	014.12		2.01^ab	011.30		1.07^a

Brasil

Brasil

Effect of fatty Amazon fish consumption on lipid metabolism

Efeito do consumo de peixes amazônicos gordurosos sobre o metabolismo lipídico

Abstracts

OBJECTIVE:

METHODS:

RESULTS:

CONCLUSION:

OBJETIVO:

MÉTODOS:

RESULTADOS:

CONCLUSÃO:

INTRODUCTION

METHODS

Animals

Preparation of the diets

Experimental Procedure

Statistical analysis

RESULTS

Diet composition

Weight gain, energy value, metabolic efficiency, and fat content

Lipogenesis

Plasma metabolites

DISCUSSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History