High-protein diets are effective in achieving weight loss which is mainly explained by increased satiety and thermogenic effects. Recent studies suggest that the effects of protein-rich diets on satiety could be mediated by amino acids like leucine or arginine. Although high-protein diets require increased intestinal amino acid absorption, amino acid and peptide absorption has not yet been considered to contribute to satiety effects. We here demonstrate a novel finding that links intestinal peptide transport processes to food intake, but only when a protein-rich diet is provided. When mice lacking the intestinal peptide transporter PEPT1 were fed diets containing 8 or 21 energy% of protein, no differences in food intake and weight gain were observed. However, upon feeding a high-protein (45 energy%) diet, Pept1?/? mice reduced food intake much more pronounced than control animals. Although there was a regain in food consumption after a few days, no weight gain was observed which was associated with a reduced intestinal energy assimilation and increased fecal energy losses. Pept1?/? mice on high-protein diet displayed markedly reduced plasma leptin levels during the period of very low food intake, suggesting a failure of leptin signaling to increase energy intake. This together with an almost two-fold elevated plasma arginine level in Pept1?/? but not wildtype mice, suggests that a cross-talk of arginine with leptin signaling in brain, as described previously, could cause these striking effects on food intake.
References
[1]
Bensaid A, Tome D, Gietzen D, Even P, Morens C, et al. (2002) Protein is more potent than carbohydrate for reducing appetite in rats. Physiol Behav 75: 577–582.
[2]
Latner JD, Schwartz M (1999) The effects of a high-carbohydrate, high-protein or balanced lunch upon later food intake and hunger ratings. Appetite 33: 119–128.
[3]
Phillips RJ, Powley TL (1996) Gastric volume rather than nutrient content inhibits food intake. Am J Physiol 271: R766–769.
[4]
Eastwood C, Maubach K, Kirkup AJ, Grundy D (1998) The role of endogenous cholecystokinin in the sensory transduction of luminal nutrient signals in the rat jejunum. Neurosci Lett 254: 145–148.
[5]
Schwartz GJ (2000) The role of gastrointestinal vagal afferents in the control of food intake: current prospects. Nutrition 16: 866–873.
[6]
Wren AM, Bloom SR (2007) Gut hormones and appetite control. Gastroenterology 132: 2116–2130.
[7]
Smeets AJ, Soenen S, Luscombe-Marsh ND, Ueland O, Westerterp-Plantenga MS (2008) Energy expenditure, satiety, and plasma ghrelin, glucagon-like peptide 1, and peptide tyrosine-tyrosine concentrations following a single high-protein lunch. J Nutr 138: 698–702.
[8]
Nakazato M, Murakami N, Date Y, Kojima M, Matsuo H, et al. (2001) A role for ghrelin in the central regulation of feeding. Nature 409: 194–198.
[9]
Jean C, Fromentin G, Tome D, Larue-Achagiotis C (2002) Wistar rats allowed to self-select macronutrients from weaning to maturity choose a high-protein, high-lipid diet. Physiol Behav 76: 65–73.
[10]
Moran TH (2000) Cholecystokinin and satiety: current perspectives. Nutrition 16: 858–865.
[11]
Halatchev IG, Cone RD (2005) Peripheral administration of PYY(3-36) produces conditioned taste aversion in mice. Cell Metab 1: 159–168.
[12]
Tome D, Schwarz J, Darcel N, Fromentin G (2009) Protein, amino acids, vagus nerve signaling, and the brain. Am J Clin Nutr 90: 838S–843S.
[13]
Cota D, Proulx K, Smith KA, Kozma SC, Thomas G, et al. (2006) Hypothalamic mTOR signaling regulates food intake. Science 312: 927–930.
[14]
Lynch CJ, Gern B, Lloyd C, Hutson SM, Eicher R, et al. (2006) Leucine in food mediates some of the postprandial rise in plasma leptin concentrations. Am J Physiol Endocrinol Metab 291: E621–630.
[15]
Balage M, Dardevet D (2010) Long-term effects of leucine supplementation on body composition. Curr Opin Clin Nutr Metab Care 13: 265–270.
[16]
Nairizi A, She P, Vary TC, Lynch CJ (2009) Leucine supplementation of drinking water does not alter susceptibility to diet-induced obesity in mice. J Nutr 139: 715–719.
[17]
Peters JC, Harper AE (1985) Adaptation of rats to diets containing different levels of protein: effects on food intake, plasma and brain amino acid concentrations and brain neurotransmitter metabolism. J Nutr 115: 382–398.
[18]
Palacin M, Estevez R, Bertran J, Zorzano A (1998) Molecular biology of mammalian plasma membrane amino acid transporters. Physiol Rev 78: 969–1054.
[19]
Adibi SA (1997) The oligopeptide transporter (Pept-1) in human intestine: biology and function. Gastroenterology 113: 332–340.
[20]
Daniel H (2004) Molecular and integrative physiology of intestinal peptide transport. Annu Rev Physiol 66: 361–384.
[21]
Daniel H, Kottra G (2004) The proton oligopeptide cotransporter family SLC15 in physiology and pharmacology. Pflugers Arch 447: 610–618.
[22]
Terada T, Inui K (2007) Gene expression and regulation of drug transporters in the intestine and kidney. Biochem Pharmacol 73: 440–449.
[23]
Erickson RH, Gum JR Jr, Lindstrom MM, McKean D, Kim YS (1995) Regional expression and dietary regulation of rat small intestinal peptide and amino acid transporter mRNAs. Biochem Biophys Res Commun 216: 249–257.
[24]
Meissner B, Boll M, Daniel H, Baumeister R (2004) Deletion of the intestinal peptide transporter affects insulin and TOR signaling in Caenorhabditis elegans. J Biol Chem 279: 36739–36745.
[25]
Hu Y, Smith DE, Ma K, Jappar D, Thomas W, et al. (2008) Targeted disruption of peptide transporter Pept1 gene in mice significantly reduces dipeptide absorption in intestine. Mol Pharm 5: 1122–1130.
[26]
N?ssl A, Rubio-Aliaga I, Fenselau H, Marth M, Kottra G, et al. (2011) Amino acid absorption and homeostasis in mice lacking the intestinal peptide transporter PEPT1. Am J Physiol Gastrointest Liver Physiol [Epub ahead of print].
[27]
Chen M, Singh AK, Xiao F, Dringenberg U, Wang J, et al. (2010) Gene ablation for PEPT1 in mice abolishes the effects of dipeptides on small intestinal fluid absorption, short circuit current and intracellular pH. Am J Physiol Gastrointest Liver Physiol.
[28]
Bensaid A, Tome D, L'Heureux-Bourdon D, Even P, Gietzen D, et al. (2003) A high-protein diet enhances satiety without conditioned taste aversion in the rat. Physiol Behav 78: 311–320.
[29]
Krauss RM, Mayer J (1965) Influence of protein and amino acids on food intake in the rat. Am J Physiol 209: 479–483.
[30]
Potier M, Darcel N, Tome D (2009) Protein, amino acids and the control of food intake. Curr Opin Clin Nutr Metab Care 12: 54–58.
[31]
Weigle DS, Breen PA, Matthys CC, Callahan HS, Meeuws KE, et al. (2005) A high-protein diet induces sustained reductions in appetite, ad libitum caloric intake, and body weight despite compensatory changes in diurnal plasma leptin and ghrelin concentrations. Am J Clin Nutr 82: 41–48.
[32]
Tome D (2004) Protein, amino acids and the control of food intake. Br J Nutr 92: Suppl 1S27–30.
[33]
Schwartz MW, Woods SC, Porte D Jr, Seeley RJ, Baskin DG (2000) Central nervous system control of food intake. Nature 404: 661–671.
[34]
Hindlet P, Bado A, Farinotti R, Buyse M (2007) Long-term effect of leptin on H+-coupled peptide cotransporter 1 activity and expression in vivo: evidence in leptin-deficient mice. J Pharmacol Exp Ther 323: 192–201.
[35]
Buyse M, Berlioz F, Guilmeau S, Tsocas A, Voisin T, et al. (2001) PepT1-mediated epithelial transport of dipeptides and cephalexin is enhanced by luminal leptin in the small intestine. J Clin Invest 108: 1483–1494.
[36]
Hindlet P, Bado A, Kamenicky P, Delomenie C, Bourasset F, et al. (2009) Reduced intestinal absorption of dipeptides via PepT1 in mice with diet-induced obesity is associated with leptin receptor down-regulation. J Biol Chem 284: 6801–6808.
[37]
Faipoux R, Tome D, Gougis S, Darcel N, Fromentin G (2008) Proteins activate satiety-related neuronal pathways in the brainstem and hypothalamus of rats. J Nutr 138: 1172–1178.
[38]
Mithieux G, Misery P, Magnan C, Pillot B, Gautier-Stein A, et al. (2005) Portal sensing of intestinal gluconeogenesis is a mechanistic link in the diminution of food intake induced by diet protein. Cell Metab 2: 321–329.
[39]
Mithieux G (2009) A novel function of intestinal gluconeogenesis: central signaling in glucose and energy homeostasis. Nutrition 25: 881–884.
[40]
Mithieux G, Andreelli F, Magnan C (2009) Intestinal gluconeogenesis: key signal of central control of energy and glucose homeostasis. Curr Opin Clin Nutr Metab Care 12: 419–423.
[41]
Martin G, Ferrier B, Conjard A, Martin M, Nazaret R, et al. (2007) Glutamine gluconeogenesis in the small intestine of 72 h-fasted adult rats is undetectable. Biochem J 401: 465–473.
[42]
Remesey C, Demigne C, Aufrere J (1978) Inter-organ relationships between glucose, lactate and amino acids in rats fed on high-carbohydrate or high-protein diets. Biochem J 170: 321–329.
[43]
Broer S (2008) Amino acid transport across mammalian intestinal and renal epithelia. Physiol Rev 88: 249–286.
[44]
Le Bricon T (1996) Effects of administration of oral branched-chain amino acids on anorexia and caloric intake in cancer patients. Clin Nutr 15: 337.
[45]
Hiroshige K, Sonta T, Suda T, Kanegae K, Ohtani A (2001) Oral supplementation of branched-chain amino acid improves nutritional status in elderly patients on chronic haemodialysis. Nephrol Dial Transplant 16: 1856–1862.
[46]
Noatsch A, Petzke KJ, Millrose MK, Klaus S (2011) Body weight and energy homeostasis was not affected in C57BL/6 mice fed high whey protein or leucine-supplemented low-fat diets. Eur J Nutr 50: 479–488.
[47]
Zhang Y, Guo K, LeBlanc RE, Loh D, Schwartz GJ, et al. (2007) Increasing dietary leucine intake reduces diet-induced obesity and improves glucose and cholesterol metabolism in mice via multimechanisms. Diabetes 56: 1647–1654.
[48]
Kuhla B, Kucia M, Gors S, Albrecht D, Langhammer M, et al. (2010) Effect of a high-protein diet on food intake and liver metabolism during pregnancy, lactation and after weaning in mice. Proteomics 10: 2573–2588.
[49]
Morley JE, Flood JF (1991) Evidence that nitric oxide modulates food intake in mice. Life Sci 49: 707–711.
[50]
Buchmann I, Milakofsky L, Harris N, Hofford JM, Vogel WH (1996) Effect of arginine administration on plasma and brain levels of arginine and various related amino compounds in the rat. Pharmacology 53: 133–142.
[51]
Calapai G, Corica F, Corsonello A, Sautebin L, Di Rosa M, et al. (1999) Leptin increases serotonin turnover by inhibition of brain nitric oxide synthesis. J Clin Invest 104: 975–982.
[52]
van't Hof RJ, Macphee J, Libouban H, Helfrich MH, Ralston SH (2004) Regulation of bone mass and bone turnover by neuronal nitric oxide synthase. Endocrinology 145: 5068–5074.
[53]
Squadrito F, Calapai G, Altavilla D, Cucinotta D, Zingarelli B, et al. (1994) Food deprivation increases brain nitric oxide synthase and depresses brain serotonin levels in rats. Neuropharmacology 33: 83–86.
[54]
Yang SJ, Denbow DM (2007) Interaction of leptin and nitric oxide on food intake in broilers and Leghorns. Physiol Behav 92: 651–657.
[55]
Denbow DM, Meade S, Robertson A, McMurtry JP, Richards M, et al. (2000) Leptin-induced decrease in food intake in chickens. Physiol Behav 69: 359–362.
[56]
Squadrito F, Calapai G, Altavilla D, Cucinotta D, Zingarelli B, et al. (1994) Central serotoninergic system involvement in the anorexia induced by NG-nitro-L-arginine, an inhibitor of nitric oxide synthase. Eur J Pharmacol 255: 51–55.
[57]
Squadrito F, Calapai G, Cucinotta D, Altavilla D, Zingarelli B, et al. (1993) Anorectic activity of NG-nitro-L-arginine, an inhibitor of brain nitric oxide synthase, in obese Zucker rats. Eur J Pharmacol 230: 125–128.
[58]
Team RDC (2009) R: A language and environment for statistical computing. Vienna.Austria: R Foundation for Statistical Computing.
