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Control of food intake by metabolism of fuels: a comparison across species

Published online by Cambridge University Press:  18 June 2012

Michael S. Allen  and
Barry J. Bradford
Michael S. Allen*
Affiliation:
Department of Animal Science, Michigan State University, East Lansing, MI, USA
Barry J. Bradford
Affiliation:
Department of Animal Sciences and Industry, Kansas State University, Manhattan, KS, USA
*
*Corresponding author: Professor M. S. Allen, fax +1 11 517 432 0147, email allenm@msu.edu
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Abstract

Research with laboratory species suggests that meals can be terminated by peripheral signals carried to brain feeding centres via hepatic vagal afferents, and that these signals are affected by oxidation of fuels. Pre-gastric fermentation in ruminants greatly alters fuels, allowing mechanisms conserved across species to be studied with different types and temporal absorption of fuels. These fuels include SCFA, glucose, lactate, amino acids and long-chain fatty acid (FA) isomers, all of which are absorbed and metabolised by different tissues at different rates. Propionate is produced by rumen microbes, absorbed within the timeframe of meals, and quickly cleared by the liver. Its hypophagic effects are variable, likely due to its fate; propionate is utilised for gluconeogenesis or oxidised and also stimulates oxidation of acetyl-CoA by anapleurosis. In contrast, acetate has little effect on food intake, likely because its uptake by the ruminant liver is negligible. Glucose is hypophagic in non-ruminants but not ruminants and unlike non-ruminant species, uptake of glucose by ruminant liver is negligible, consistent with the differences in hypophagic effects between them. Inhibition of FA oxidation increases food intake, whereas promotion of FA oxidation suppresses food intake. Hypophagic effects of fuel oxidation also vary with changes in metabolic state. The objective of this paper is to compare the type and utilisation of fuels and their effects on feeding across species. We believe that the hepatic oxidation theory allows insight into mechanisms controlling feeding behaviour that can be used to formulate diets to optimise energy balance in multiple species.

Keywords

Comparative metabolismFood intakeHepatic oxidation
Type
Symposium on ‘Metabolic flexibility in animal and human nutrition’
Information
Proceedings of the Nutrition Society , Volume 71 , Issue 3 , August 2012 , pp. 401 - 409
Copyright
Copyright © The Authors 2012

Abbreviations:
2,5-AM

2,5-anhydromannitol

2-DG

2-deoxyglucose

FA

fatty acid

LCFA

long-chain fatty acid

MA

mercaptoacetate

MP

methyl palmoxirate

Comparative metabolism can provide a valuable tool to improve understanding of physiological control mechanisms by investigating the similarities and differences across species. This paper addresses comparative aspects of the control of feeding behaviour by peripheral signals generated by oxidation of fuels. Research with rodents and other laboratory species indicates that inhibition of fuel oxidation stimulates feeding, whereas stimulation of oxidation inhibits feeding, and that the signal to brain feeding centres is via hepatic vagal afferents( Reference Langhans 1 ). Feeding behaviour of rats has been related to energy charge in the liver and synergistic effects of metabolic inhibitors suggest an integrated mechanism with a common signal related to hepatic energy status from oxidation of various fuels( Reference Friedman 2 ). However, the liver is only sparsely innervated with afferent fibres and the common hepatic vagus also innervates other tissues, including the duodenum( Reference Berthoud 3 ). The enterocyte was recently proposed as the primary sensor for fuel oxidation, casting doubt on a signal from the liver( Reference Langhans 4 ). Evaluation of the ruminant model and comparison with non-ruminant models provides important insight into this issue because pre-gastric fermentation in ruminants greatly alters the type and temporal pattern of absorption of fuels. Rumen microbes ferment organic matter to SCFA that are utilised by different tissues at different rates. Dairy cows have been studied extensively for decades because of their economic importance and are an ideal model for investigating control of feeding behaviour because of their extraordinary energy requirement and sensitivity to treatments within the physiological range( Reference Allen, Bradford and Harvatine 5 ). Excessive energy intake and weight gain in late lactation dairy cows subsequently increases the risk of suppressed appetite in the peri-parturient period, resulting in excessive mobilisation of body energy reserves and a greater incidence of ketosis and hepatic lipidosis. Conversely, energy intake is often a primary constraint to milk yield in peak lactation, and increasing voluntary feed intake can increase productivity of dairy cattle. A better understanding of control of feeding behaviour by hepatic oxidation of fuels will allow diets to be formulated to control energy balance in both domestic animals and human subjects. The objective of this paper is to discuss differences in fuel type and temporal oxidation between ruminant and non-ruminant species and how they relate to the control of feeding behaviour.

Oxidation of fuels and feeding in non-ruminants

Fuel oxidation and feeding

The effect of oxidation of fuels on food intake in laboratory species has been addressed by previous reviews in more detail( Reference Langhans 1 , Reference Friedman 2 ) and will be briefly described here. Various metabolic inhibitors have been reported to stimulate feeding by inhibiting glucose or fatty acid (FA) oxidation. Glycolysis is inhibited by 2-deoxy-d-glucose (2-DG), which increased food intake by rabbits when injected into the hepatic portal circulation( Reference Novin, VanderWeele and Rezek 6 ) and inhibition of glucose oxidation by α-cyano-4-hydroxycinnamic acid, which decreases pyruvate transport across the mitochondrial membrane, stimulated feeding in rats( Reference Del Prete, Lutz and Scharrer 7 ). Long-chain FA (LCFA) require carnitine palmitoyltransferase for transport across the mitochondrial membrane and subsequent β-oxidation, and inhibition of carnitine palmitoyltransferase-1 by methyl palmoxirate (MP)( Reference Friedman and Tordoff 8 ) and etomoxir( Reference Horn, Ji and Friedman 9 ) stimulated feeding in rats fed diets rich in long-chain TAG. However, MP failed to stimulate feeding when rats were fed a diet rich in medium-chain TAG( Reference Friedman, Ramirez and Bowden 10 ), likely because medium-chain FA do not require carnitine palmitoyltransferase-1 for transport into the mitochondria( Reference McGarry and Foster 11 ). Mercaptoacetate (MA) depresses β-oxidation by inhibiting long-chain acyl-CoA dehydrogenase activity and stimulated feeding in rats fed a high-fat diet( Reference Langhans and Scharrer 12 , Reference Scharrer and Langhans 13 ). However, feeding response to MA has been inconsistent( Reference Langhans 4 ), likely because of anorectic effects of MA through a β-adrenergic mechanism( Reference Allen and Bradford 14 ). Stimulation of fuel oxidation by PPARα agonists decreased food intake in rats( Reference Fu, Gaetani and Oveisi 15 Reference Bergeron 17 ) and knockdown of 11β-hydroxysteroid dehydrogenase type 1 increased hepatic oxidation and decreased food intake in mice( Reference Li, Hernandez-Ono and Crooke 18 ). In summary, there is a large body of evidence consistent with involvement of fuel oxidation in the control of food intake.

Signal via hepatic vagal afferents

Hepatic vagal afferents are involved in the transmission of signals from fuel oxidation to brain feeding centres. The discharge rate of hepatic vagal afferents was increased by portal infusion of the metabolic inhibitors 2,5-anhydromannitol (2,5-AM)( Reference Lutz, Niijima and Scharrer 19 ) and MA( Reference Lutz, Diener and Scharrer 20 ) and hepatic vagotomy blocked the stimulation of feeding by 2-DG in rabbits( Reference Novin, VanderWeele and Rezek 6 ), as well as 2,5-AM( Reference Tordoff, Rawson and Friedman 21 ) and MA( Reference Langhans and Scharrer 12 ) in rats. Hepatic vagotomy also blocked the stimulation of satiety by a variety of fuels in rats( Reference Langhans, Egli and Scharrer 22 , Reference Langhans, Damaske and Scharrer 23 ), glucose in chickens( Reference Rusby, Anil and Chatterjee 24 ), and propionate in sheep( Reference Anil and Forbes 25 ). This research indicates that fuel oxidation in peripheral tissues is involved in the control of feeding and that the transmission of signals to brain feeding centres is via hepatic vagal afferents.

Feeding related to hepatic energy status

A series of experiments conducted by Friedman and colleagues showed that feeding behaviour was related to hepatic energy status. An inverse temporal relationship was reported between hepatic ATP concentration and feeding in rats( Reference Koch, Ji and Osbakken 26 , Reference Ji and Friedman 27 ) and preventing ATP production by 2,5-AM stimulated feeding in rats( Reference Tordoff, Rafka and DiNovi 28 , Reference Rawson, Blum and Osbakken 29 ). This fructose analogue is rapidly phosphorylated in the liver but not metabolised beyond the 1,6-bisphosphate stage, thereby sequestering inorganic phosphate and preventing ATP production( Reference Rawson, Blum and Osbakken 29 ). Phosphate loading restored ATP concentrations and eliminated the stimulatory effects of 2,5-AM on feeding( Reference Rawson and Friedman 30 ). The effect was likely in the liver because the latency for the eating response was less for portal compared with jugular infusion, hepatic vagotomy blocked the response, and radiolabelled 2,5-AM concentrations increased in liver but not the brain( Reference Tordoff, Rawson and Friedman 21 ). Inhibition of FA oxidation by MP( Reference Friedman, Harris and Ji 31 ) and etomoxir( Reference Horn, Ji and Friedman 32 ) also reduced hepatic ATP concentration and stimulated feeding. Hepatic energy status might be a common link by which oxidation of various fuels affect feeding.

Integrated mechanism

Synergistic effects of metabolic inhibitors on feeding by rats have been demonstrated. Inhibition of glycolysis by 2-DG and FA oxidation by MP( Reference Friedman and Tordoff 8 ) and inhibition of glycolysis by 2-DG and lipolysis by nicotinic acid( Reference Friedman, Tordoff and Ramirez 33 ) synergistically increased feeding in rats. In addition, feeding response to specific fuels is dependent on diet. Lactate and pyruvate caused hypophagia when rats were fed chow but not a high-fat diet( Reference Langhans, Egli and Scharrer 34 ), which the authors attributed to decreased activity of pyruvate dehydrogenase (required for oxidation of pyruvate via conversion to acetyl-CoA) by the high-fat diet( Reference Begum, Tepperman and Tepperman 35 ). Diet also affected feeding response to metabolic inhibitors. When rats were fed a low-fat, high-carbohydrate diet, 2,5-AM stimulated feeding but MP did not; conversely, when they were fed a high-fat, low-carbohydrate diet, MP stimulated feeding but 2,5-AM did not( Reference Horn and Friedman 36 ). These experiments, along with the relationship between hepatic energy status and feeding, suggest that a common integrated mechanism involving the hepatic oxidation of a variety of fuels is involved in the control of food intake as suggested by Friedman and Tordoff( Reference Friedman and Tordoff 8 ).

Control of food intake by hepatic oxidation: the case for ruminants

Pre-gastric fermentation: different fuels

Diets consumed by dairy cows and most other ruminants contain a higher concentration of fibre (>25% insoluble fibre) and lower concentration of FA (<5%) than diets consumed by human subjects and laboratory species. Pre-gastric fermentation greatly alters both type and temporal supply of fuels. SCFA are produced by fermentation of organic matter by rumen microbes and include acetic, propionic and butyric acids. Acetic acid (mostly acetate at rumen pH) is produced primarily from fermentation of fibre and is the most abundant SCFA. Propionate is produced primarily from fermentation of starch and its rate of production and absorption is much greater than acetate because starch ferments faster than fibre and propionate is absorbed more quickly than acetate. Starch escaping fermentation in the rumen can be digested and absorbed in the small intestine providing glucose and lactic acid (from intestinal metabolism of glucose) as absorbed fuels. The starch concentration of ruminant diets ranges widely from a trace for ruminants grazing mature pastures to more than 50% for feedlot cattle, and site of digestion is easily manipulated by type, concentration and processing of cereal grains in the diet. Unsaturated FA are altered by biohydrogenation in the rumen increasing degree of saturation of FA absorbed compared with FA consumed and producing various FA isomers with physiological effects on energy partitioning( Reference Harvatine, Perfield and Bauman 37 ). The different fuels produced from pre-gastric fermentation and the ability to manipulate site of digestion combined with differences between species in hepatic metabolism of fuels (below) makes ruminants an important model to investigate mechanisms controlling feeding.

Hepatic metabolism of fuels

Fuels metabolised in bovine liver include NEFA, glycerol, amino acids, lactate and certain SCFA (primarily propionate). Plasma NEFA are important fuels oxidised in the liver of both ruminant and non-ruminant species. They are extracted from the blood in proportion to their concentration( Reference Emery, Liesman and Herdt 38 ). The bovine liver has limited capacity to export TAG as VLDL( Reference Pullen, Liesman and Emery 39 ) so most NEFA taken up by the liver are oxidised either immediately or stored as TAG to be oxidised later. Glycerol (from lipolysis of TAG), lactate (from intestinal metabolism of glucose and the Cori cycle) and amino acids are common fuels metabolised by both ruminant and non-ruminant species. The primary difference for hepatic metabolism between ruminants and non-ruminants is metabolism of glucose and propionate. Unlike most laboratory species, hepatic uptake of glucose from the blood is negligible in mature ruminants( Reference Reynolds, Aikman and Lupoli 40 ) because glucokinase activity, necessary for activation and subsequent metabolism, is very low( Reference Ballard 41 ). It is notable that plasma glucose concentration is similar for pre-ruminant calves and many non-ruminants species and decreased utilisation of plasma glucose by the liver coincides with rumen development, when absorbed glucose supply is diminished by pre-gastric fermentation. Propionate is rapidly produced by rumen microbes (primarily by fermentation of starch), readily cleared by ruminant liver from the portal vein, and readily metabolised( Reference Seal and Reynolds 42 ), in part because activity of propionyl-CoA synthetase is very high( Reference Ricks and Cook 43 ). Propionate as an oxidative fuel in the liver is much less important for non-ruminants; its supply to the liver is low because most starch is digested and absorbed before becoming available for fermentation in the large intestine. Other SCFA are less important than propionate as oxidative fuels in ruminant liver. Uptake and utilisation of plasma acetate by ruminant liver is negligible( Reference Seal and Reynolds 42 ), because acetyl-CoA synthetase activity is very low( Reference Ricks and Cook 43 ). Butyrate is cleared and metabolised by ruminant liver, but its supply is much lower than propionate because of a lower rate of production( Reference Sutton, Dhanoa and Morant 44 ) and extensive metabolism by ruminal epithelia( Reference Kristensen 45 ). Similar to propionate, butyrate can be oxidised via conversion to acetyl-CoA, but unlike propionate, butyrate cannot stimulate oxidation in the TCA cycle by anaplerosis.

Hypophagic effects of fuels in ruminants

Hypophagic effects of fuels have been investigated by infusion studies with ruminants and these results are consistent with effects of diet on feeding behaviour. The most hypophagic fuels include propionate, medium-chain FA and unsaturated LCFA and the least hypophagic include glucose and acetate. Propionate decreased feed intake compared with acetate when isosmotic solutions were infused into the rumen in many studies reported in the literature( Reference Allen 46 ). While a reduction of feed intake by propionate could occur simply because propionate has greater energy concentration than acetate, propionate also linearly decreased total energy intake when the energy of infusates was considered( Reference Oba and Allen 47 ). Glucose has been shown to be hypophagic in a variety of non-ruminant species( Reference Baile and Forbes 48 ) but did not reduce feed intake when infused abomasally( Reference Clark, Spires and Derrig 49 , Reference Frobish and Davis 50 ) or intravenously( Reference Dowden and Jacobsen 51 ) in cows. Unsaturated C18 FA were more hypophagic than 18 : 0 when infused abomasally in lactating cows( Reference Bremmer, Ruppert and Clark 52 ) and coconut oil (primarily medium-chain TAG) was more hypophagic than LCFA when fed to lactating dairy cows( Reference Dohme, Machmüller and Sutter 53 ). Variation in the hypophagic effects of fuels in ruminants allows insight into mechanisms controlling feeding across species.

Hypophagia from hepatic oxidation?

It is notable that the most hypophagic fuels for ruminants are those most readily oxidised in the liver. Glucose and acetate have little effect on feeding relative to other fuels and do not stimulate oxidation in the liver, while propionate is hypophagic and can be oxidised as well as stimulate oxidation. Unsaturated C18 FA are more hypophagic than stearate and more readily oxidised in ruminant liver( Reference Mashek, Bertics and Grummer 54 ). Medium-chain TAG are more hypophagic than LCFA and are quickly and completely hydrolysed, delivered quickly to the liver via the portal vein compared to the lymphatic system for LCFA, and unlike LCFA, can bypass carnitine palmitoyltransferase for transport into the mitochondria( Reference Langhans 1 ). Hypophagic effects of specific fuels in ruminants are consistent with their effects on hepatic oxidation.

The temporal supply to the liver varies greatly among fuels even when cows are fed ad libitum. Propionate is most variable and is most likely to be the primary fuel to stimulate satiety in ruminants fed diets containing starch( Reference Allen, Bradford and Oba 55 ). Propionate is the primary end-product of rumen starch digestion and rumen production rates vary greatly among diets because of variation in starch concentration and fermentability( Reference Allen 46 ). It is rapidly absorbed within the timeframe of meals( Reference Benson, Reynolds and Aikman 56 ) and rapidly extracted by the liver( Reference Kristensen 45 ). Much of the glucose from intestinal starch digestion is oxidised to lactate or CO2 by enterocytes, and that which is absorbed is not oxidised in the liver. Lactate is metabolised by ruminant liver, but it is unlikely to be the primary fuel oxidised causing satiety; relatively little reaches the liver during meals because of latency for transit of starch to the small intestine, and extraction of lactate by the liver is lower than propionate( Reference Reynolds, Aikman and Lupoli 40 ). Similarly, the time required for passage from the rumen to the small intestine decreases the likelihood that amino acids or LCFA in feed consumed is oxidised in the liver within the timeframe of meals. However, these fuels can contribute to satiety and delay hunger by supplying acetyl-CoA for oxidation, and lactate, glycerol, and some amino acids can also stimulate oxidation in the TCA cycle by anapleurosis, thereby extending oxidation between meals. In addition, absorbed glucose, as well as glucose spared by metabolism of acetate, β-hydroxybutyrate, and LCFA by extra-hepatic tissues, can elevate plasma insulin concentration and affect hepatic oxidation indirectly by decreasing gluconeogenesis.

Effects of altering site of starch digestion on feed intake and feeding behaviour of dairy cows is consistent with the temporal supply of oxidative fuels to the liver( Reference Allen, Bradford and Harvatine 5 ). Shifting the site of starch digestion post-ruminally by substituting less fermentable starch sources increased feed intake in several experiments reported in the literature( Reference Allen 46 ). Increased feed intake by cows offered a less fermentable starch source is consistent with a slower rate of propionate production and metabolism within the timeframe of meals, resulting in increased meal size. To investigate mechanisms underlying these feed intake responses, feeding behaviour was measured in an experiment comparing a more fermentable to a less fermentable starch source fed to lactating cows( Reference Oba and Allen 57 ). The more rapidly fermentable starch source reduced feed intake 8% by reducing meal size 17%, despite a numerical decrease in the time between meals. The more fermentable treatment increased organic matter fermented in the rumen and likely increased the contribution of propionate, and decreased glucose and lactate as fuels. The effect of treatment on meal size and feed intake is consistent with the temporal supply of oxidative fuels to the liver.

Alternative mechanisms

Differences between ruminants and non-ruminants for hypophagic effects of glucose infusion allow insight into the existence of sensory neurons for glucose( Reference Allen, Bradford and Oba 55 ). It seems improbable that glucose utilisation in sensory neurons is involved in the hypophagic effects of glucose in non-ruminants because ruminal neural tissue metabolises glucose( Reference Lindsay and Setchell 58 ), yet glucose per se does not cause hypophagia in ruminants( Reference Allen 46 ). It is more likely that differences in hypophagic effects of glucose between ruminants and non-ruminants are because of differences in hepatic oxidation of glucose.

Specific receptors have been identified for SCFA( Reference Brown, Goldsworthy and Barnes 59 ); G-protein-coupled receptors (41 and 43) are widely expressed in bovine tissue including small intestine and liver and are activated similarly by acetate and propionate( Reference Wang, Gu and Heid 60 ). Greater rumen production and flux through the portal drained viscera for acetate compared with propionate as well as very high extraction of propionate by the liver results in much lower peripheral concentrations of propionate than acetate. This decreases the likelihood that these receptors are involved in the mechanism for hypophagia from propionate relative to acetate.

Propionate is an insulin secretagogue( Reference Leuvenink, Bleumer and Bongers 61 ) and insulin is a putative satiety hormone( Reference Anika, Houpt and Houpt 62 , Reference Porte and Woods 63 ). However, propionate has depressed dry matter intake without altering plasma insulin( Reference Frobish and Davis 50 , Reference Farningham and Whyte 64 ) and insulin's putative effects on feeding are through receptors in the central nervous system( Reference Foster, Ames and Emery 65 ), yet hepatic vagotomy eliminated hypophagic effects of propionate( Reference Anil and Forbes 25 ). Therefore, it is unlikely that the hypophagic effects of propionate are through direct effects of insulin. Rather, insulin is more likely involved indirectly through its effects on gluconeogenesis and removal of fuels from the blood that are potentially oxidised in the liver( Reference Allen, Bradford and Oba 55 ). While insulin is known to down-regulate transcription of gluconeogenic genes( Reference Barthel and Schmoll 66 ), short-term increases in plasma insulin concentration caused by propionate during meals likely have little effect on gluconeogenesis( Reference Bradford and Allen 67 ). Rapid response to insulin for nutrient uptake by peripheral tissues and decreased lipolysis results in decreased supply of NEFA and other fuels to the liver( Reference Allen, Bradford and Harvatine 5 ). Depression in feed intake by a highly fermentable starch source was related to plasma insulin concentration and insulin response to a glucose challenge in an experiment with lactating dairy cows( Reference Bradford and Allen 67 ). The more fermentable starch source depressed feed intake but response varied greatly among cows. Response in feed intake to the more fermentable starch source was negatively related to plasma insulin concentration (r 2 0·28, P<0·01) consistent with enhanced propionate oxidation due to down-regulation of gluconeogenesis. In addition, intake response was related positively (quadratically) to insulin response to a glucose challenge (r 2 0·40, P<0·01), consistent with decreased availability of fuels for hepatic oxidation. Therefore, insulin is likely involved indirectly in hypophagia from propionate by affecting oxidation of fuels in the liver.

Weaknesses in the model

Much of the support for a signal from the liver to brain feeding centres relies on experiments in which treatment effects on feed intake were eliminated by hepatic vagotomy. However, the common hepatic branch of the vagus innervates other tissues besides the liver including the proximal duodenum, distal stomach, pylorus, portal vein and pancreas; others have suggested that results of experiments with hepatic vagotomy must be interpreted with caution( Reference Berthoud 3 , Reference Horn and Friedman 68 ). Langhans( Reference Langhans 4 ) suggested that the signal linking FA oxidation to feeding centres in the brain via the hepatic vagus originates in enterocytes rather than the liver. This was based on the following observations: (1) vagotomy of the common hepatic vagus nerve typical of rat experiments is not specific to the liver only, (2) liver parenchyma is sparsely innervated in rats, (3) infusion of MA into the pancreatico-duodenal artery (targeting the proximal duodenum) increased the discharge rate of hepatic vagal afferents and the response was blocked by infusion of lidocaine into the intestinal lumen and (4) inhibition of β-oxidation by MA failed to stimulate feeding when FA oxidation was elevated by fasting or adrenoreceptor agonists.

One key and valid criticism of the hepatic oxidation theory is the fact that afferent innervation of the liver parenchyma is relatively sparse, at least in the rat( Reference Berthoud and Neuhuber 69 ). If we assume that these findings indicate that most hepatocytes do not directly interface with afferent nerve endings, does this mean that hepatic sensing of energy status could not be communicated to the brain? Although little work has been done to investigate potential modes of communication, several possibilities are feasible. Hepatocytes contain gap junctions that allow intercellular movement of ions, including Ca2+( Reference Gaspers and Thomas 70 ), which can cause membrane depolarisation. Rawson et al.( Reference Rawson, Ji and Friedman 71 ) reported that 2,5-AM caused a phospholipase C-mediated release of intracellular Ca2+ stores in hepatocytes in a timeframe that coincided with decreases in cellular ATP concentration. However, gap junctions between hepatocytes and afferent receptor nerves have not been found( Reference Berthoud 3 ), making it unlikely that direct transport of ions between hepatocytes and neurons occurs. It may be more important that increased intracellular Ca2+ can stimulate exocytosis of signalling molecules. Hepatocytes are known to utilise ATP as an autocrine–paracrine signalling molecule( Reference Wang, Roman and Lidofsky 72 , Reference Feranchak, Lewis and Kresge 73 ) and some afferent nerves are activated by ATP( Reference Kirkup, Booth and Chessell 74 ). Depolarisation of a hepatocyte could trigger release of intracellular Ca2+ stores( Reference Weiss and Burgoyne 75 ), leading to exocytosis of ATP, which could then move through the extracellular space to nearby parasympathetic nerves, binding purinergic receptors and leading to the generation of action potentials. Although some findings have been consistent with such a proposed mechanism( Reference Boutellier, Lutz and Volkert 76 ), others have not( Reference Scharrer, Rossi and Sutter 77 ).

Another potential signalling mechanism is glutamate release by hepatocytes. This process is thought to be mediated by the recently characterised organic anion transporter 2( Reference Fork, Bauer and Golz 78 ), and effects of liver failure on systemic glutamate concentrations suggest that the release is quantitatively significant. Although it is presently unclear how (or if) hepatic glutamate release is regulated, there is strong evidence for the presence of glutamate sensors in the hepatic–portal region that signal via the hepatic vagus nerve; hepatic portal vein administration of monosodium glutamate increased vagal afferent tone, and this response was eliminated by vagotomy( Reference Niijima 79 ). Therefore, it is at least possible that alterations in hepatocyte energy status influence glutamate efflux and, in turn, vagal signals to the central nervous system. The relatively large efflux of glutamate from the liver( Reference Fork, Bauer and Golz 78 ) could support adequate concentrations to induce sensory responses even in the absence of synapse-like interfaces between hepatocytes and sensory neurons.

An inability to clearly define mediators for liver communication with the central nervous system certainly should not be interpreted as evidence of a lack of such communication. In a series of studies unrelated to peripheral regulation of feeding behaviour, Imai et al. ( Reference Imai, Katagiri and Yamada 80 ) clearly demonstrated that nerve signals originating from the liver reach the brain and subsequently impact other peripheral organs. In this work, adenoviral-mediated overexpression of extracellular-regulated kinase in liver parenchyma resulted in increased insulin secretion. Imai et al.( Reference Imai, Katagiri and Yamada 80 ) first discovered that this response was driven by pancreatic β-cell proliferation, despite the lack of transgene expression in that organ. They further showed that the pancreatic effects could be eliminated by ablation of afferent splanchnic nerve signalling, pancreatic vagotomy or bilateral midbrain transection, clearly demonstrating the involvement of a liver–brain–pancreas axis mediated by the nervous system. Although the splanchnic nerve does not exclusively innervate the liver, the transgene was not detected in any portion of the gastrointestinal tract in this experiment( Reference Imai, Katagiri and Yamada 80 ). This demonstrated signalling pathway highlights the possibility that nutrient sensors expressed in hepatocytes, including AMP-dependent protein kinase( Reference Viollet, Guigas and Leclerc 81 , Reference Dzamko, van Denderen and Hevener 82 ) and mammalian target of rapamycin( Reference Howell and Manning 83 ), can respond to cellular energy status and communicate this status to the central nervous system. These signals are not necessarily coupled to hepatocyte depolarisation.

Another key criticism of the hepatic oxidation theory is based on recent studies in which MA failed to promote food intake even when it apparently suppressed hepatic FA oxidation( Reference Langhans, Leitner and Arnold 84 ). The logic underlying these experiments was that if oxidation of FA is blocked, then the resulting decreased energy status should promote greater food intake, according to the hepatic oxidation theory. Indeed, much of the evidence for this theory has been built on the use of metabolic inhibitors, so such findings must be taken seriously. However, in our opinion drug treatments (as opposed to palatable dietary interventions) provide little insight when they suppress intake or have no effect, simply because of the possibility that they had off-target effects and/or generated an aversive response( Reference Choi, Palmquist and Allen 85 ). In fact, several such problems have been reported with the use of MA( Reference Brandt, Arnold and Geary 86 , Reference Singer, York and Berthoud 87 ). This problem is not exclusive to results obtained for MA; we likewise put little emphasis on suppression of food intake by activators of PPARα or other drugs that result in increased hepatic oxidation. In fact, it is only an increase in food intake in response to a metabolic modifier that is unusual and, as such, these findings are far more valuable for discerning the biology of the sensory systems than negative results are.

One frustrating aspect of research on mechanisms regulating feeding behaviour is the vast degree of redundancy and overlap in the system, which can make even cleverly designed experiments difficult to interpret. Investigating the effects of a compound such as MA in the small intestine is an example. Langhans et al.( Reference Langhans, Leitner and Arnold 84 ) reported that intestinal infusion of MA altered vagal discharge rate, and that intestinal lidocaine administration eliminated this response. However, these responses and intake modulation by MA could be mediated by alterations in gut peptide signalling rather than through signals derived from oxidation in enterocytes. MA is known to act as a β-adrenergic agonist( Reference Brandt, Arnold and Geary 86 ), and the β-adrenergic agonist isoproterenol was shown to increase cholecystokinin secretion( Reference Scott, Prpic and Capel 88 ). As cholecystokinin release was decreased by anaesthetics( Reference Feinle, Grundy and Fried 89 ), effects of MA on vagal discharge rate could have been exclusively through gut peptides. Although intrajejunal infusion of MA stimulated feeding, the site of administration might have minimised response from vagal afferents and cholecystokinin release in the duodenum and the feeding response might have been through effects of absorbed MA on hepatic oxidation. This might explain the quandary for a signal from enterocytes discussed by Langhans( Reference Langhans, Leitner and Arnold 84 ) that MA and cholecystokinin have similar effects on vagal discharge rate of afferents from the duodenum but opposite effects on feeding. Langhans et al.( Reference Langhans, Leitner and Arnold 84 ) did report that the increase in food intake stimulated by intestinal MA infusion was eliminated by sub-diaphragmatic deafferentation; however, no evidence was presented that disconnecting afferents in this region of the vagus leaves the hepatic branch proper of the vagus nerve intact. Therefore, responses to intestinal MA infusions may well be explained by a combination of effects on gut peptide release and signalling from the liver.

Signal from liver, enterocytes, or both?

Although the link between oxidation of fuels and the firing of hepatic vagal afferents is not known, evidence for a common mechanism by oxidation of various fuels is compelling. While a signal from oxidation of fuels in enterocytes via the hepatic vagus is plausible and demands further investigation, there are some inconsistencies for both ruminant and non-ruminants models and it is unlikely that enterocytes are the primary signal by which peripheral oxidation of fuels affect feeding. Evidence across species provides strong support for a signal from the liver linked to oxidation of a variety of fuels. We base this on the following observations:

  1. (1) Although it is nearly impossible to selectively transect only those vagal fibres of the hepatic branch proper in rats( Reference Berthoud 3 ), it appears to be feasible in ruminants. Vagotomy of the hepatic branch of the vagus in sheep decreased hypophagic effects of propionate( Reference Anil and Forbes 25 ).

  2. (2) Inhibition of a satiety signal from oxidation of glucose by 2-DG in rabbits was more likely from the liver than enterocytes because eating was increased to a greater extent and with shorter latency when 2-DG was injected into the hepatic–portal system compared with both the jugular vein in normal rabbits and the hepatic–portal system of vagotomised rabbits( Reference Novin, VanderWeele and Rezek 6 ).

  3. (3) Glucose is oxidised by enterocytes and is partially oxidised in the portal drained viscera in ruminants when infused abomasally( Reference Huntington, Harmon and Richards 90 ). However, abomasal infusion of glucose did not decrease feed intake in cows( Reference Clark, Spires and Derrig 49 , Reference Frobish and Davis 50 ). It is likely that the difference in hypophagic effects of infused glucose between ruminants and non-ruminants is because of differences in hepatic oxidation as previously discussed.

  4. (4) Decreasing rumen digestibility of starch often increases feed intake in dairy cows( Reference Allen 46 ). However, this increases starch flow to the duodenum and glucose supply to enterocytes, increasing oxidation( Reference Huntington, Harmon and Richards 90 ). The effect on feed intake is the opposite of that expected if oxidation of glucose in enterocytes causes a satiety signal.

  5. (5) Intraruminal infusions of mixtures of acetate and propionate increase concentrations of these SCFA reaching the duodenum and unlike hepatocytes, enterocytes oxidise both acetate and propionate( Reference Marsman and McBurney 91 Reference Seal and Parker 93 ). Therefore, oxidation of SCFA by enterocytes is an unlikely mechanism explaining differences in their hypophagic effects in ruminants.

  6. (6) Abomasal infusion of propionate depressed feed intake in cows while glucose infused at twice the rate did not( Reference Frobish and Davis 50 ). Although both absorbed fuels are oxidised by enterocytes only propionate is oxidised by ruminant liver( Reference Allen, Bradford and Oba 55 ) consistent with a signal from hepatic oxidation.

  7. (7) Infusion of propionate into the jugular vein of sheep had no effect while infusion into the portal vein at the same rate decreased feed intake by more than 80%( Reference Anil and Forbes 94 ). While propionate can be metabolised by enterocytes, it is more likely that the signal was from the liver; propionate supply to enterocytes is much greater when infused in the jugular vein than the portal vein because of the very high extraction (>90%) of propionate by the liver from portal supply( Reference Kristensen 45 ).

  8. (8) Hypophagia during the transition from pregnancy to lactation is associated with elevated plasma NEFA and β-hydroxybutyrate concentrations in dairy cows( Reference Allen, Bradford and Oba 55 ). Although oxidation of plasma NEFA by enterocytes is possible( Reference Gangl and Ockner 95 ), hypophagia is more likely from hepatic oxidation of NEFA. This is because hypophagic effects of propionate are enhanced for cows immediately postpartum compared with cows later in lactation that are not in a lipolytic state, likely by stimulating hepatic oxidation of acetyl-CoA by TCA anapleurosis( Reference Oba and Allen 96 ). This is consistent with our recent observation that hypophagic effects of propionate increased linearly with hepatic acetyl-CoA concentrations( Reference Stocks and Allen 97 ).

  9. (9) While MA stimulates feeding in rats fed a high-fat diet, failure to stimulate feeding in cattle( Reference Choi, Palmquist and Allen 85 ) is likely because MA must be activated to MA CoA; activity of acetyl-CoA synthetase in liver is low in ruminants( Reference Ricks and Cook 43 ) but high in non-ruminants( Reference Hanson and Ballard 98 ). The hypophagic effect of FA oxidation is more likely from a signal from the liver because acetate is metabolised by enterocytes( Reference Oba, Baldwin and Bequette 92 ) indicating availability of acetyl-CoA synthetase. The dramatic (>70%) depression of feed intake in dairy cattle over several hours following injection of MA( Reference Choi, Palmquist and Allen 85 ) might have been due to a β-adrenergic mechanism as previously discussed( Reference Allen and Bradford 14 ).

  10. (10) From a purely teleological viewpoint, hepatic sensing of energy status has several advantages over enterocyte sensing. While it is true that enterocytes could offer a more rapid signal of nutrient availability after meals for animals such as rats, this is not the case for animals that rely on either foregut or hindgut fermentation for the majority of their energy supply. Additionally, as a key anabolic organ, the liver could offer the unique advantage of sensing not just energy availability, but energy balance relative to nutrient demands. For example, since the bovine liver uses much of its oxidisable substrate to support gluconeogenesis, a high rate of hepatic nutrient metabolism does not necessarily lead to elevated ATP concentrations or suppression of feed intake( Reference Oba and Allen 47 ). Although insulin has central effects on feeding, its ability to integrate long-term energy status and feeding behaviour by hepatic oxidation through regulation of hepatic gluconeogenesis provides a simple control mechanism that is not available by the insulin-independent glucose transporter in enterocytes.

Concluding remarks

If peripheral mechanisms are involved in intake regulation, as many studies suggest, hepatic oxidation is the only proposed mechanism that can accommodate both differences in fuels absorbed and sites of absorption across species while remaining consistent with food intake responses to diets. Although the complexity of feeding behaviour control mechanisms makes it likely that multiple mechanisms are involved, no other proposed peripheral feedback system offers the ‘broad explanatory power’( Reference Friedman 99 ) of the hepatic oxidation theory. Understanding the mechanisms by which feeding is affected by metabolism of fuels will allow dietary and pharmaceutical approaches to be developed to control energy intake across species.

Acknowledgements

This work was supported by National Research Initiative Competitive Grants No. 2004-35206-14167 from the USDA Cooperative State Research, Education, and Extension Service (to M.S.A.) and no. 2008-35206-18854 from the USDA National Institute of Food and Agriculture (to M.S.A.), and a National Science Foundation Graduate Research Fellowship (to B.J.B.). M.S.A. directed, researched and drafted the manuscript. B.J.B. researched and prepared sections of the manuscript. No conflicts of interest, financial or otherwise, are declared by the authors.

References

1. Langhans, W (1996) Role of the liver in the metabolic control of eating: what we know – and what we do not know. Neurosci Biobehav Rev 20, 145153.CrossRefGoogle Scholar
2. Friedman, MI (1998) Fuel partitioning and food intake. Am J Clin Nutr 67, 513S518S.CrossRefGoogle ScholarPubMed
3. Berthoud, H-R (2004) Anatomy and function of sensory hepatic nerves. Anat Rec 280A, 827835.CrossRefGoogle Scholar
4. Langhans, W (2008) Fatty acid oxidation in the energostatic control of eating – a new idea. Appetite 51, 446451.CrossRefGoogle ScholarPubMed
5. Allen, MS, Bradford, BJ & Harvatine, KJ (2005) The cow as a model to study food intake regulation. Annu Rev Nutr 25, 523547.CrossRefGoogle Scholar
6. Novin, D, VanderWeele, DA & Rezek, M (1973) Infusion of 2-deoxy-d-glucose into the hepatic–portal system causes eating: evidence for peripheral glucoreceptors. Science 181, 858860.CrossRefGoogle ScholarPubMed
7. Del Prete, E, Lutz, TA & Scharrer, E (2004) Inhibition of glucose oxidation by alpha-cyano-4-hydroxycinnamic acid stimulates feeding in rats. Physiol Behav 80, 489498.CrossRefGoogle ScholarPubMed
8. Friedman, MI & Tordoff, MG (1986) Fatty acid oxidation and glucose utilization interact to control food intake in rats. Am J Physiol 251, R840–R845.Google ScholarPubMed
9. Horn, C, Ji, H & Friedman, M (2004) Etomoxir, a fatty acid oxidation inhibitor, increases food intake and reduces hepatic energy status in rats. Physiol Behav 81, 157162.CrossRefGoogle ScholarPubMed
10. Friedman, MI, Ramirez, I, Bowden, CR et al. . (1990) Fuel partitioning and food intake: role for mitochondrial fatty acid transport. Am J Physiol 258, R216R221.Google ScholarPubMed
11. McGarry, JD & Foster, DW (1980) Regulation of hepatic fatty acid oxidation and ketone body production. Annu Rev Biochem 49, 395420.CrossRefGoogle ScholarPubMed
12. Langhans, W & Scharrer, E (1987) Evidence for a vagally mediated satiety signal derived from hepatic fatty acid oxidation. J Auton Nerv Syst 18, 1318.CrossRefGoogle ScholarPubMed
13. Scharrer, E & Langhans, W (1986) Control of food intake by fatty acid oxidation. Am J Physiol 250, R1003R1006.Google ScholarPubMed
14. Allen, MS & Bradford, BJ (2009) Control of eating by hepatic oxidation of fatty acids. A note of caution. Appetite 53, 272273.CrossRefGoogle ScholarPubMed
15. Fu, J, Gaetani, S, Oveisi, F et al. . (2003) Oleylethanolamide regulates feeding and body weight through activation of the nuclear receptor PPAR-alpha. Nature 425, 9093.CrossRefGoogle ScholarPubMed
16. Fu, J, Oveisi, F, Gaetani, S et al. . (2005) Oleoylethanolamide, an endogenous PPAR-α agonist, lowers body weight and hyperlipidemia in obese rats. Neuropharmacology 48, 11471153.CrossRefGoogle ScholarPubMed
17. Bergeron, R (2006) Peroxisome proliferator-activated receptor (PPAR)-agonism prevents the onset of type 2 diabetes in Zucker diabetic fatty rats: a comparison with PPAR agonism. Endocrinology 147, 42524262.CrossRefGoogle Scholar
18. Li, G, Hernandez-Ono, A, Crooke, RM et al. . (2011) Effects of antisense-mediated inhibition of 11β-hydroxysteroid dehydrogenase type 1 on hepatic lipid metabolism. J Lipid Res 52, 971981.CrossRefGoogle ScholarPubMed
19. Lutz, TA, Niijima, A & Scharrer, E (1996) Intraportal infusion of 2,5-anhydro-d-mannitol increases afferent activity in the common hepatic vagus branch. J Auton Nerv Syst 61, 204208.CrossRefGoogle Scholar
20. Lutz, TA, Diener, M & Scharrer, E (1997) Intraportal mercaptoacetate infusion increases afferent activity in the common hepatic vagus branch of the rat. Am J Physiol 273, R442R445.Google ScholarPubMed
21. Tordoff, MG, Rawson, N & Friedman, MI (1991) 2,5-anhydro-d-mannitol acts in liver to initiate feeding. Am J Physiol 261, R283R288.Google Scholar
22. Langhans, W, Egli, G & Scharrer, E (1985) Regulation of food intake by hepatic oxidative metabolism. Brain Res Bull 15, 425428.CrossRefGoogle ScholarPubMed
23. Langhans, W, Damaske, U & Scharrer, E (1985) Different metabolites might reduce food intake by the mitochondrial generation of reducing equivalents. Appetite 6, 143152.CrossRefGoogle ScholarPubMed
24. Rusby, AA, Anil, MH, Chatterjee, P et al. . (1987) Effects of intraportal infusion of glucose and lysine on food intake in intact and hepatic-vagotomized chickens. Appetite 9, 6572.CrossRefGoogle ScholarPubMed
25. Anil, MH & Forbes, JM (1988) The roles of hepatic nerves in the reduction of food intake as a consequence of intraportal sodium propionate administration in sheep. Q J Exp Physiol (Cambridge, England) 73, 539546.CrossRefGoogle ScholarPubMed
26. Koch, JE, Ji, H, Osbakken, MD et al. . (1998) Temporal relationships between eating behavior and liver adenine nucleotides in rats treated with 2,5-AM. Am J Physiol 274, R610R617.Google ScholarPubMed
27. Ji, H & Friedman, MI (1999) Compensatory hyperphagia after fasting tracks recovery of liver energy status. Physiol Behav 68, 181186.CrossRefGoogle ScholarPubMed
28. Tordoff, MG, Rafka, R, DiNovi, MJ et al. . (1988) 2,5-anhydro-d-mannitol: a fructose analogue that increases food intake in rats. Am J Physiol 254, R150R153.Google Scholar
29. Rawson, NE, Blum, H, Osbakken, MD et al. . (1994) Hepatic phosphate trapping, decreased ATP, and increased feeding after 2,5-anhydro-d-mannitol. Am J Physiol 266, R112R117.Google ScholarPubMed
30. Rawson, NE & Friedman, MI (1994) Phosphate loading prevents the decrease in ATP and increase in food intake produced by 2,5-anhydro-D-mannitol. Am J Physiol 266, R1792R1796.Google ScholarPubMed
31. Friedman, MI, Harris, RB, Ji, H et al. . (1999) Fatty acid oxidation affects food intake by altering hepatic energy status. Am J Physiol 276, R1046R1053.Google ScholarPubMed
32. Horn, C, Ji, H & Friedman, M (2004) Etomoxir, a fatty acid oxidation inhibitor, increases food intake and reduces hepatic energy status in rats. Physiol Behav 81, 157162.CrossRefGoogle ScholarPubMed
33. Friedman, MI, Tordoff, MG & Ramirez, I (1986) Integrated metabolic control of food intake. Brain Res Bull 17, 855859.CrossRefGoogle ScholarPubMed
34. Langhans, W, Egli, G & Scharrer, E (1985) Regulation of food intake by hepatic oxidative metabolism. Brain Res Bull 15, 425428.CrossRefGoogle ScholarPubMed
35. Begum, N, Tepperman, HM & Tepperman, J (1983) Effects of high fat and high carbohydrate diets on liver pyruvate dehydrogenase and its activation by a chemical mediator released from insulin-treated liver particulate fraction: effect of neuraminidase treatment on the chemical mediator activity. Endocrinology 112, 5059.CrossRefGoogle ScholarPubMed
36. Horn, CC & Friedman, MI (1998) Metabolic inhibition increases feeding and brain Fos-like immunoreactivity as a function of diet. Am J Physiol 275, R448R459.Google ScholarPubMed
37. Harvatine, KJ, Perfield, JW & Bauman, DE (2009) Expression of enzymes and key regulators of lipid synthesis is upregulated in adipose tissue during CLA-induced milk fat depression in dairy cows. J Nutr 139, 849854.CrossRefGoogle ScholarPubMed
38. Emery, RS, Liesman, JS & Herdt, TH (1992) Metabolism of long chain fatty acids by ruminant liver. J Nutr 122, 832837.CrossRefGoogle ScholarPubMed
39. Pullen, DL, Liesman, JS & Emery, RS (1990) A species comparison of liver slice synthesis and secretion of triacylglycerol from nonesterified fatty acids in media. J Anim Sci 68, 13951399.CrossRefGoogle ScholarPubMed
40. Reynolds, CK, Aikman, PC, Lupoli, B et al. . (2003) Splanchnic metabolism of dairy cows during the transition from late gestation through early lactation. J Dairy Sci 86, 12011217.CrossRefGoogle ScholarPubMed
41. Ballard, FJ (1965) Glucose utilization in mammalian liver. Comp Biochem Physiol 14, 437443.CrossRefGoogle ScholarPubMed
42. Seal, CJ & Reynolds, CK (1993) Nutritional implications of gastrointestinal and liver metabolism in ruminants. Nutr Res Rev 6, 185208.CrossRefGoogle ScholarPubMed
43. Ricks, CA & Cook, RM (1981) Regulation of volatile fatty acid uptake by mitochondrial acyl CoA synthetases of bovine liver. J Dairy Sci 64, 23242335.CrossRefGoogle ScholarPubMed
44. Sutton, JD, Dhanoa, MS, Morant, SV et al. . (2003) Rates of production of acetate, propionate, and butyrate in the rumen of lactating dairy cows given normal and low-roughage diets. J Dairy Sci 86, 36203633.CrossRefGoogle ScholarPubMed
45. Kristensen, N (2005) Splanchnic metabolism of volatile fatty acids in the dairy cow. Anim Sci 80, 3–10.CrossRefGoogle Scholar
46. Allen, MS (2000) Effects of diet on short-term regulation of feed intake by lactating dairy cattle. J Dairy Sci 83, 15981624.CrossRefGoogle ScholarPubMed
47. Oba, M & Allen, MS (2003) Intraruminal infusion of propionate alters feeding behavior and decreases energy intake of lactating dairy cows. J Nutr 133, 10941099.CrossRefGoogle ScholarPubMed
48. Baile, CA & Forbes, JM (1974) Control of feed intake and regulation of energy balance in ruminants. Physiol Rev 54, 160214.CrossRefGoogle ScholarPubMed
49. Clark, JH, Spires, HR, Derrig, RG et al. . (1977) Milk production, nitrogen utilization and glucose synthesis in lactating cows infused postruminally with sodium caseinate and glucose. J Nutr 107, 631644.CrossRefGoogle ScholarPubMed
50. Frobish, RA & Davis, CL (1977) Effects of abomasal infusions of glucose and propionate on milk yield and composition. J Dairy Sci 60, 204209.CrossRefGoogle Scholar
51. Dowden, DR & Jacobsen, DR (1960) Inhibition of appetite in dairy cattle by certain intermediate metabolites. Nature 188, 148149.CrossRefGoogle Scholar
52. Bremmer, DR, Ruppert, LD, Clark, JH et al. . (1998) Effects of chain length and unsaturation of fatty acid mixtures infused into the abomasum of lactating dairy cows. J Dairy Sci 81, 176188.CrossRefGoogle ScholarPubMed
53. Dohme, F, Machmüller, A, Sutter, F et al. . (2004) Digestive and metabolic utilization of lauric, myristic and stearic acid in cows, and associated effects on milk fat quality. Arch Anim Nutr 58, 99–116.CrossRefGoogle ScholarPubMed
54. Mashek, DG, Bertics, SJ & Grummer, RR (2002) Metabolic fate of long-chain unsaturated fatty acids and their effects on palmitic acid metabolism and gluconeogenesis in bovine hepatocytes. J Dairy Sci 85, 22832289.CrossRefGoogle ScholarPubMed
55. Allen, MS, Bradford, BJ & Oba, M (2009) Board Invited Review: the hepatic oxidation theory of the control of feed intake and its application to ruminants. J Anim Sci 87, 33173334.CrossRefGoogle ScholarPubMed
56. Benson, JA, Reynolds, CK, Aikman, PC et al. . (2002) Effects of abomasal vegetable oil infusion on splanchnic nutrient metabolism in lactating dairy cows. J Dairy Sci 85, 18041814.CrossRefGoogle ScholarPubMed
57. Oba, M & Allen, MS (2003) Effects of corn grain conservation method on feeding behavior and productivity of lactating dairy cows at two dietary starch concentrations. J Dairy Sci 86, 174183.CrossRefGoogle ScholarPubMed
58. Lindsay, DB & Setchell, BP (1976) The oxidation of glucose, ketone bodies and acetate by the brain of normal and ketonaemic sheep. J Physiol (Lond) 259, 801823.CrossRefGoogle ScholarPubMed
59. Brown, AJ, Goldsworthy, SM, Barnes, AA et al. . (2003) The Orphan G protein-coupled receptors GPR41 and GPR43 are activated by propionate and other short chain carboxylic acids. J Biol Chem 278, 1131211319.CrossRefGoogle ScholarPubMed
60. Wang, A, Gu, Z, Heid, B et al. . (2009) Identification and characterization of the bovine G protein-coupled receptor GPR41 and GPR43 genes1. J Dairy Sci 92, 26962705.CrossRefGoogle Scholar
61. Leuvenink, HG, Bleumer, EJ, Bongers, LJ et al. . (1997) Effect of short-term propionate infusion on feed intake and blood parameters in sheep. Am J Physiol 272, E997–E1001.Google ScholarPubMed
62. Anika, SM, Houpt, TR & Houpt, KA (1980) Insulin as a satiety hormone. Physiol Behav 25, 2123.CrossRefGoogle ScholarPubMed
63. Porte, D & Woods, SC (1981) Regulation of food intake and body weight in insulin. Diabetologia 20, Suppl., 274280.CrossRefGoogle ScholarPubMed
64. Farningham, DA & Whyte, CC (1993) The role of propionate and acetate in the control of food intake in sheep. Br J Nutr 70, 3746.CrossRefGoogle ScholarPubMed
65. Foster, LA, Ames, NK & Emery, RS (1991) Food intake and serum insulin responses to intraventricular infusions of insulin and IGF-I. Physiol Behav 50, 745749.CrossRefGoogle ScholarPubMed
66. Barthel, A & Schmoll, D (2003) Novel concepts in insulin regulation of hepatic gluconeogenesis. Am J Physiol Endocrinol Metab 285, E685E692.CrossRefGoogle ScholarPubMed
67. Bradford, BJ & Allen, MS (2007) Depression in feed intake by a highly fermentable diet is related to plasma insulin concentration and insulin response to glucose infusion. J Dairy Sci 90, 38383845.CrossRefGoogle ScholarPubMed
68. Horn, CC & Friedman, MI (2004) Separation of hepatic and gastrointestinal signals from the common ‘hepatic’ branch of the vagus. Am J Physiol Regul Integr Comp Physiol 287, R120R126.CrossRefGoogle ScholarPubMed
69. Berthoud, HR & Neuhuber, WL (2000) Functional and chemical anatomy of the afferent vagal system. Auton Neurosci: Basic Clin 85, 117.CrossRefGoogle ScholarPubMed
70. Gaspers, LD & Thomas, AP (2005) Calcium signaling in liver. Cell Calcium 38, 329342.CrossRefGoogle ScholarPubMed
71. Rawson, NE, Ji, H & Friedman, MI (2003) 2,5-Anhydro-d-mannitol increases hepatocyte calcium: implications for a hepatic hunger stimulus. Biochim Biophys Acta 1642, 5966.CrossRefGoogle Scholar
72. Wang, Y, Roman, R, Lidofsky, SD et al. . (1996) Autocrine signaling through ATP release represents a novel mechanism for cell volume regulation. Proc Natl Acad Sci USA 93, 1202012025.CrossRefGoogle ScholarPubMed
73. Feranchak, AP, Lewis, MA, Kresge, C et al. . (2010) Initiation of purinergic signaling by exocytosis of ATP-containing vesicles in liver epithelium. J Biol Chem 285, 81388147.CrossRefGoogle ScholarPubMed
74. Kirkup, AJ, Booth, CE, Chessell, IP et al. . (1999) Excitatory effect of P2X receptor activation on mesenteric afferent nerves in the anaesthetised rat. J Physiol (Lond) 520, 551563.CrossRefGoogle ScholarPubMed
75. Weiss, JL & Burgoyne, RD (2002) Sense and sensibility in the regulation of voltage-gated Ca2+ channels. Trends Neurosci 25, 489491.CrossRefGoogle Scholar
76. Boutellier, S, Lutz, TA, Volkert, M et al. . (1999) 2-Mercaptoacetate, an inhibitor of fatty acid oxidation, decreases the membrane potential in rat liver in vivo . Am J Physiol 277, R301R305.Google ScholarPubMed
77. Scharrer, E, Rossi, R, Sutter, DA et al. . (1997) Hyperpolarization of hepatocytes by 2,5-AM: implications for hepatic control of food intake. Am J Physiol 272, R874R878.Google ScholarPubMed
78. Fork, C, Bauer, T, Golz, S et al. . (2011) OAT2 catalyses efflux of glutamate and uptake of orotic acid. Biochem J 436, 305312.CrossRefGoogle ScholarPubMed
79. Niijima, A (2000) Reflex effects of oral, gastrointestinal and hepatoportal glutamate sensors on vagal nerve activity. J Nutr 130, 971S973S.CrossRefGoogle ScholarPubMed
80. Imai, J, Katagiri, H, Yamada, T et al. . (2008) Regulation of pancreatic beta cell mass by neuronal signals from the liver. Science 322, 12501254.CrossRefGoogle ScholarPubMed
81. Viollet, B, Guigas, B, Leclerc, J et al. . (2009) AMP-activated protein kinase in the regulation of hepatic energy metabolism: from physiology to therapeutic perspectives. Acta Physiol 196, 8198.CrossRefGoogle ScholarPubMed
82. Dzamko, N, van Denderen, BJW, Hevener, AL et al. . (2010) AMPK beta1 deletion reduces appetite, preventing obesity and hepatic insulin resistance. J Biol Chem 285, 115122.CrossRefGoogle ScholarPubMed
83. Howell, JJ & Manning, BD (2011) mTOR couples cellular nutrient sensing to organismal metabolic homeostasis. Trends Endocrinol Metab 22, 94–102.CrossRefGoogle ScholarPubMed
84. Langhans, W, Leitner, C & Arnold, M (2011) Dietary fat sensing via fatty acid oxidation in enterocytes: possible role in the control of eating. Am J Physiol Regul Integr Comp Physiol 300, R554R565.CrossRefGoogle ScholarPubMed
85. Choi, BR, Palmquist, DL & Allen, MS (1997) Sodium mercaptoacetate is not a useful probe to study the role of fat in regulation of feed intake in dairy cattle. J Nutr 127, 171176.CrossRefGoogle ScholarPubMed
86. Brandt, K, Arnold, M, Geary, N et al. . (2006) Beta-adrenergic-mediated inhibition of feeding by mercaptoacetate in food-deprived rats. Pharmacol Biochem Behav 85, 722727.CrossRefGoogle ScholarPubMed
87. Singer, L, York, D, Berthoud, HR et al. . (1999) Conditioned taste aversion produced by inhibitors of fatty acid oxidation in rats. Physiol Behav 68, 175179.CrossRefGoogle ScholarPubMed
88. Scott, L, Prpic, V, Capel, WD et al. . (1996) Beta-adrenergic regulation of cholecystokinin secretion in STC-1 cells. Am J Physiol 270, G291G297.Google ScholarPubMed
89. Feinle, C, Grundy, D & Fried, M (2001) Modulation of gastric distension-induced sensations by small intestinal receptors. Am J Physiol Gastrointest Liver Physiol 280, G51G57.CrossRefGoogle ScholarPubMed
90. Huntington, GB, Harmon, DL & Richards, CJ (2006) Sites, rates, and limits of starch digestion and glucose metabolism in growing cattle. J Anim Sci 84, Suppl., E14E24.CrossRefGoogle ScholarPubMed
91. Marsman, KE & McBurney, MI (1995) Dietary fiber increases oxidative metabolism in colonocytes but not in distal small intestinal enterocytes isolated from rats. J Nutr 125, 273282.Google Scholar
92. Oba, M, Baldwin, RL & Bequette, BJ (2004) Oxidation of glucose, glutamate, and glutamine by isolated ovine enterocytes in vitro is decreased by the presence of other metabolic fuels. J Anim Sci 82, 479486.CrossRefGoogle ScholarPubMed
93. Seal, CJ & Parker, DS (1994) Effect of intraruminal propionic acid infusion on metabolism of mesenteric- and portal-drained viscera in growing steers fed a forage diet: I. Volatile fatty acids, glucose, and lactate. J Anim Sci 72, 13251334.CrossRefGoogle ScholarPubMed
94. Anil, MH & Forbes, JM (1980) Effects of insulin and gastro-intestinal hormones on feeding and plasma insulin levels in sheep. Horm Metab Res 12, 234236.CrossRefGoogle ScholarPubMed
95. Gangl, A & Ockner, RK (1975) Intestinal metabolism of plasma free fatty acids. Intracellular compartmentation and mechanisms of control. J Clin Invest 55, 803813.CrossRefGoogle ScholarPubMed
96. Oba, M & Allen, MS (2003) Dose-response effects of intrauminal infusion of propionate on feeding behavior of lactating cows in early or midlactation. J Dairy Sci 86, 29222931.CrossRefGoogle ScholarPubMed
97. Stocks, SE & Allen, MS (2012) Hypophagic effects of propionate increase with elevated hepatic acetyl CoA concentration for cows in the early postpartum period. J Dairy Sci 95, 32593268.CrossRefGoogle ScholarPubMed
98. Hanson, RW & Ballard, FJ (1967) The relative significance of acetate and glucose as precursors for lipid synthesis in liver and adipose tissue from ruminants. Biochem J 105, 529536.CrossRefGoogle ScholarPubMed
99. Friedman, MI (1995) Control of energy intake by energy metabolism. Am J Clin Nutr 62, 1096S1100S.CrossRefGoogle ScholarPubMed