Discussion

GLP-1 and PYY have important metabolic functions; both have been shown to reduce food intake in humans⁽Reference Cummings and Overduin¹⁷⁾. GLP-1 also directly stimulates pancreatic β-cells; the so-called incretin effect accounts for approximately 50–70 % of the total insulin secretion after a meal⁽Reference Vilsbøll, Krarup and Madsbad¹⁸⁾. In addition, obese subjects have attenuated plasma concentrations of both peptides, suggesting major changes in regulatory functions⁽Reference le Roux, Batterham and Aylwin^19, Reference Verdich, Toubro and Buemann²⁰⁾. For GLP-1, long-acting analogues are already clinically available (exenatide and liraglutide) for the treatment of type 2 diabetes and, interestingly, subcutaneous injections of exenatide to patients with type 2 diabetes are associated with a gradual and linear weight loss with no signs of impaired efficacy with time. In view of this great therapeutic success, the focus is now shifted towards intestinal endocrine cells that naturally produce GLP-1 and PYY. The question is whether it is possible to increase the secretion of these peptides from endogenous stores using specific stimuli. However, mechanisms by which carbohydrates, fats and proteins in the gut lumen stimulate the release of GI peptides from enteroendocrine cells are only insufficiently understood. Regarding the detection of carbohydrates in the gut, sweet taste receptors (T1R2+T1R3), α-gustducin, and several other proteins comprising a full signalling machinery similar to that found in the mouth have been identified in enteroendocrine cells of the rodent⁽Reference Höfer, Püschel and Drenckhahn²¹⁾ and human small intestine and colon⁽Reference Jang, Kokrashvili and Theodorakis^2, Reference Rozengurt, Wu and Chen²²⁾. Several studies have shown co-localisation of taste receptors with GLP-1, GIP, PYY and cholecystokinin⁽Reference Jang, Kokrashvili and Theodorakis^2, Reference Rozengurt and Sternini^3, Reference Rozengurt, Wu and Chen²²⁾. In addition, studies in mice using knockout models for α-gustducin (α-gust − / − ) or T1R3 (T1R3 − / − ) have revealed impaired glucose-stimulated incretin secretion⁽Reference Jang, Kokrashvili and Theodorakis²⁾. In vitro, both carbohydrate sugars and the AS sucralose were capable of stimulating GLP-1 and GIP release from enteroendocrine cell lines (GLUTag, NCI-H716); more importantly, lactisole, a sweet receptor antagonist, blocked the secretion of GLP-1⁽Reference Jang, Kokrashvili and Theodorakis^2, Reference Margolskee, Dyer and Kokrashvili⁴⁾. Based on these studies, it has been suggested that the gut directly senses glucose or other sweet compounds by taste-signalling elements expressed in L cells and that this leads to GLP-1 release from these same cells⁽Reference Kokrashvili, Mosinger and Margolskee¹¹⁾.

Here, we have investigated in healthy human subjects whether sweetness-matched carbohydrate sugars and AS have equivalent effects on the release of GI satiety peptides, glucose homeostasis and appetite feelings. The data reveal that mainly glucose, and to a small extent fructose, stimulated GLP-1 and PYY release and reduced ghrelin secretion; both also affected appetite with (albeit not significantly) increased satiety and fullness compared with water. The equisweet AS loads did not affect GI peptide secretion with minimal effects on appetite compared with water. These findings correspond to human studies also reporting a lack of effect of AS on incretin release, plasma glucose, C-peptide and gastric emptying⁽Reference Gregersen, Jeppesen and Holst^23–Reference Mezitis, Maggio and Koch²⁵⁾; however, the data are in contrast to the above-mentioned in vitro studies. This may be due to the simple fact that cell culture-based in vitro experiments do only model human physiology, whereas in vivo, the regulatory interface of the GI tract is much more complex and modulated by multiple homeostatic and non-homeostatic factors. In addition, studies in mice and rats have indicated that the majority of incretin-expressing cells in the duodenum and jejunum do not co-localise with α-gustducin⁽Reference Sutherland, Young and Cooper^26, Reference Fujita, Wideman and Speck²⁷⁾, suggesting that the taste receptor pathway is not the only one involved in signal transduction and subsequent GI peptide secretion. Other, non-taste receptor-mediated mechanisms might be involved in the induction of GI peptide release. Several studies have suggested that the secretion of incretins is also dependent on actively absorbed carbohydrate sugars: in rats, glucose-stimulated GIP secretion was markedly suppressed not only by gymnemic acid (a potent blocker of sweet taste) but also by phlorizin, which inhibits the active transport of glucose by the Na-dependent glucose co-transporter 1⁽Reference Fushiki, Kojima and Imoto²⁸⁾. In addition, in vitro studies using the enteroendocrine GLUTag cell line have shown that GLP-1 release was impaired when glucose absorption was blocked with phlorizin⁽Reference Gribble, Williams and Simpson²⁹⁾. Further studies by Ritzel et al. ⁽Reference Ritzel, Fromme and Ottleben³⁰⁾ have shown that when the non-sweet, non-metabolisable sugar-analogues, 3-O-methylglucose (absorbed via passive and active glucose transport systems) and 2DG (absorbed only via passive glucose transport systems) were perfused into the rat ileum, 3-O-methylglucose induced the secretion of GLP-1, whereas 2DG did not, suggesting that the release of GLP-1 is independent of intracellular metabolism but dependent on active cellular uptake.

In this regard, we performed an experiment to test whether an intragastric load of 2DG affects GLP-1, PYY or ghrelin secretion. The data show that 2DG does not affect peptide secretion, confirming previous animal and in vitro data for humans and extending the findings to PYY and ghrelin secretion. 2DG is known to reduce intracellular glucose utilisation by competitively inhibiting hexokinase activity and glucose membrane carrier systems. The resulting intracellular glucoprivation induces counter-regulatory mechanisms leading to hyperglycaemia⁽Reference Rezek and Kroeger^31, Reference Welle, Thompson and Campbell³²⁾. The almost linear rise in blood glucose concentrations in the present study reflects these metabolic effects; although blood glucose concentrations are high, cellular utilisation of glucose at cerebral and peripheral glucosensitive sites did not occur. The observed side effects (heat flushes and sweating) further suggest sympathetic activation. In parallel, we observed a marked increase in hunger feelings. 2DG has been demonstrated to augment food intake and thirst in mammalian species including rats, pigs, monkeys and humans due to the functional hypoglycaemic state⁽Reference Welle, Thompson and Campbell³²⁾. Our data, therefore, support the basic concept of decreasing blood glucose as a metabolic correlate of hunger, namely ‘the glucostatic theory’⁽Reference Mayer³³⁾. As mentioned above, the increase in hunger was, however, not reflected by increased plasma ghrelin concentrations or alterations in plasma GLP-1 or PYY.

Fructose infusions (25 g) did not affect GLP-1, PYY and ghrelin plasma concentrations to the same extent as the equisweet loads of glucose (50 g); however, fructose induced plasma levels much closer to those observed after glucose infusions than the AS. It is arguable that the different molar load may have affected peptide secretion differentially; however, previous human data document that GLP-1 secretion in response to equal doses (75 g) of either fructose or glucose is less for fructose⁽Reference Kong, Chapman and Goble³⁴⁾. The relationship between the molecular structure of carbohydrate sugars and their ability to stimulate the release of GLP-1 or GIP has been investigated in detail⁽Reference Shima, Suda and Nishimoto^35, Reference Sirinek, Levine and O'Dorisio³⁶⁾. Sirinek et al. ⁽Reference Sirinek, Levine and O'Dorisio³⁶⁾ demonstrated that only glucose and, to a lesser extent, galactose (C-4 epimer), but not fructose (C-2 keto sugar), mannose (C-2 epimer) or sorbitol (reduced alcohol of glucose), can stimulate the release of GIP. Based on these observations, it has been proposed that a special sugar sensor with specific steric requirements is necessary to directly stimulate incretin release⁽Reference Sirinek, Levine and O'Dorisio³⁶⁾.

The finding that AS have less effect on satiety, fullness and hunger ratings compared with carbohydrate sugars confirms the lack of post-ingestive mechanisms and supports recent findings in rats, suggesting that the consumption of AS might lead to increased body weight and obesity⁽Reference Swithers and Davidson³⁷⁾. However, correlations between appetite ratings and amount of food consumed are quite small, and we did not directly measure food intake. The observed satiating effects of fructose in comparison with the effects of glucose, together with the rather small effects of fructose on peptide levels, suggest that additional mechanisms must operate to terminate a meal and/or to determine inter-meal satiety. Initial studies by Blundell et al. ⁽Reference Foltin, Fischman and Moran^38–Reference Rogers and Blundell⁴⁰⁾ and a few other studies have reported energy compensation in humans when energy-containing sugars were replaced by AS. A large number of subsequent studies could, however, not show an effect of AS on appetite and food intake⁽Reference Canty and Chan^41–Reference Drewnowski, Massien and Louis-Sylvestre⁴³⁾.