Leptin

Leptin (from the Greek leptos, meaning thin) is a 16 kDa polypeptide product of the ob (obese) gene⁽Reference Zhang, Proenca and Maffei⁹⁸⁾. The gene for leptin has been sequenced for cattle and sheep, and differs by only two conservative amino acids⁽Reference Blache, Tellam and Chagas¹⁰⁵⁾.

Leptin is produced by adipose tissue primarily, but also by the placenta, the skeletal muscle, the mammary tissue, and within the brain. In all ruminant animals, plasma concentrations are correlated with the amount of fat mass in animals that are not under any energetic or thermal stress, or stress of any other nature⁽Reference Blache, Tellam and Chagas^105–Reference Roche, Kolver and Kay¹⁰⁸⁾.

Leptin plays a key role in regulating energy intake and energy expenditure, including the orexigenic–anorexigenic complex and metabolism. Its role in the control of energy balance was first reported in the ob/ob mouse, a phenotype that presents hyperphagia, impaired thermogenesis, obesity and abnormal neuroendocrine profiles⁽Reference Campfield, Smith and Guisez¹⁰⁹⁾. In this model of obesity, peripheral (intraperitoneal or intravenous) or intracerebroventricular (icv) administration of leptin reduced VFI and activated BMR⁽Reference Campfield and Smith¹¹⁰⁾. Furthermore, administration of endogenous leptin prevented the normal endocrine response to fasting, such as the reduction in the activity of neuroendocrine systems such as the thyroid, reproductive and growth axes, and the activation of the hypothalamic–pituitary axis (for a review, see Ahima et al. ⁽Reference Ahima, Saper and Flier¹¹¹⁾).

Leptin interacts with six types of receptor (LepRa–LepRf), although LepRb is the only receptor isoform that contains active intracellular signalling domains. This receptor is present in a number of hypothalamic nuclei. Leptin is transported across the BBB by a short form of the leptin receptor⁽Reference Thomas, Preston and Wilson¹¹²⁾. Once in the brain, leptin binds to a long form of its receptor – a membrane receptor – present in high concentrations in specific neurons located in the ARC⁽Reference Adam, Archer and Findlay^113–Reference Williams, Adam and Mercer¹¹⁷⁾. The mRNA encoding for the ob receptor are mainly expressed in a population of orexinergic neurons co-expressing NPY and AgRP mRNA and in separate populations of anorexinergic neurons co-expressing cocaine- and amphetamine-regulated transcript and POMC⁽Reference Adam, Archer and Findlay^113–Reference Ahima¹¹⁸⁾. Leptin reduces VFI by stimulating the activity of the anorexinergic neurons and by decreasing the activity of the orexinergic neurons (for a review, see Ahima⁽Reference Ahima¹¹⁸⁾). In addition, leptin inhibits other orexinergic peptides, such as melanin-concentrating hormone and orexins, which are expressed in the lateral hypothalamic area of rodents and sheep⁽Reference Ahima^118–Reference Iqbal, Pomolo and Murakami¹²⁰⁾. Outside of the diencephalon, leptin also act on neurons of the NST, dorsal motor nucleus of the vagus nerve, lateral parabrachial nucleus, and central grey of the brainstem⁽Reference Hosoi, Kawagishi and Okuma¹²¹⁾. In the obese rodent, the action of leptin in the brainstem seems to be part of the mechanisms involved in short-term adjustments of energy intake such as regulation of meal size by cholecystokinin (CCK)⁽Reference Morton, Blevins and Williams¹²²⁾.

In ruminant species, the literature on leptin has been dominated by studies on the role of leptin (and fat reserves) in the control of reproduction. However, some of these studies have also demonstrated an effect of leptin in regulating VFI; the effects, however, are ambiguous. Physiologically large amounts of leptin (more than 0·04 μg/h infused intracerebrally) have been reported to decrease VFI (by up to 70 % within 5 d⁽Reference Blache, Celi and Blackberry¹²³⁾), but this anorexic effect is not universal. There are indications of seasonal dependency, with intacerebral injections of 1·5 mg leptin inducing a 30 % decrease in DM intake in sheep in autumn, but not in spring⁽Reference Miller, Findlay and Morrison¹²⁴⁾, reflecting a possible interaction of leptin with photoperiod⁽Reference Adam, Archer and Miller¹²⁵⁾. Consistent with these data, recent evidence also suggests that the hypothalamic orexigenic–anorexigenic regulatory mechanisms are less sensitive to leptin in sheep during spring than autumn, possibly due to a shift in leptin receptor sensitivity. Changes in photoperiod may inhibit leptin brain entry at the BBB in spring to prevent its anorectic actions when appetite and energy balance are at a seasonal low⁽Reference Adam, Findlay and Miller⁵⁹⁾.

In contrast, the seasonal effect of leptin on VFI was reversed in castrated sheep, with no effect in autumn but a decrease in spring⁽Reference Clarke, Henry and Iqbal¹²⁶⁾. In the same experiment Clarke et al. ⁽Reference Clarke, Henry and Iqbal¹²⁶⁾ also demonstrated that VFI is less sensitive to leptin in male than female sheep (25 v. 75 % reduction of DM intake in response to intracerebral infusion of leptin); these results indicate a possible interaction between photoperiod, the sex steroids and leptin in the regulation of VFI. Other hormonal mechanisms known to be influenced by photoperiod and also to have a direct effect on VFI, such as melatonin or prolactin⁽Reference Dahl, Buchanan and Tucker²²⁾, could also interact with leptin in the control of VFI⁽Reference Rhind, Archer and Adam¹²⁷⁾.

In addition to its chronic regulatory effect, leptin also appears to have an effect in the short-term regulation of VFI. Plasma concentrations of leptin decrease within hours of fasting and increase within hours following an increase in intake (for reviews, see Zieba et al. ⁽Reference Zieba, Amstalden and Williams¹⁰⁴⁾ and Adam et al. ⁽Reference Adam, Archer and Miller¹²⁵⁾). Similarly, plasma leptin concentrations decrease after an abrupt reduction in intake or following an energy challenge, such as the start of lactation⁽Reference Roche, Kolver and Kay^108, Reference Kadokawa, Blache and Yamada¹²⁸⁾. The evident changes in plasma leptin concentrations over a time frame too short to affect level of body fatness raise a few questions about factors controlling its production. It has been demonstrated that level of intake can affect the expression of mRNA encoding for the long form of the leptin receptor in sheep and cattle⁽Reference Adam, Archer and Findlay¹¹³⁾, suggesting that this variation in sensitivity to leptin could be part of the mechanism of action of leptin on VFI⁽Reference Adam, Archer and Miller¹²⁵⁾. Regulation of leptin secretion by acute changes in energy balance⁽Reference Mann, Mann and Blache^129, Reference Blache, Chagas, Martin, Juengel, Murray and Smith¹³⁰⁾ reflects an adipocyte response to circulating hormones or metabolites that are affected by energy intake and known to regulate leptin secretion, such as insulin⁽Reference Ahima and Flier¹³¹⁾, and not changes in adipose stores per se. This rapid response in circulating leptin concentrations to changes in VFI or energy expenditure supports a role for leptin in maintaining adiposity, and could possibly explain some of the daily fluctuation in VFI observed in animals fed ad libitum on an average-quality ration⁽Reference Tolkamp, Emmans and Kyriazakis⁹³⁾.

Other signals from adipose tissue

Adiponectin, a 30 kDa polypeptide secreted primarily by the white and brown adipose tissue⁽Reference Kershaw and Flier^132, Reference Viengchareun, Zennaro and Pascual-le Tallec¹³³⁾, has no apparent direct effect on VFI in laboratory animals; however, plasma concentrations are inversely correlated with fat mass in humans and rodents⁽Reference Kershaw and Flier¹³²⁾. There are two adiponectin receptors; AdipoR1 is mainly expressed in skeletal muscle, and AdipoR2 in the liver. However, an adiponectin receptor has, as yet, not been identified centrally⁽Reference Kadowaki and Yamauchi¹³⁴⁾, making it unlikely that adiponectin has a direct effect on central pathways regulating VFI. Furthermore, peripheral administration of adiponectin in rodents stimulates energy expenditure and reduces body-weight gain, without any apparent change in VFI (for a review, see Kadowaki & Yamauchi⁽Reference Kadowaki and Yamauchi¹³⁴⁾).

Adiponectin may instead play an indirect role in VFI regulation. Plasma concentrations of adiponectin are inversely correlated with the degree of insulin resistance⁽Reference Kadowaki and Yamauchi¹³⁴⁾, and adiponectin administration improves glucose uptake by peripheral tissues in rodents⁽Reference Yamauchi, Kamon and Waki¹³⁵⁾. This adiponectin-mediated effect on insulin resistance and glucose metabolism indicates a possible role for this hormone in the regulation of VFI, through changes in circulating glucose and insulin⁽Reference Matsuzawa¹³⁶⁾.

Resistin is a 12 kDa polypeptide produced primarily in white adipose tissue, although brown adipose tissue is also a source⁽Reference Viengchareun, Zennaro and Pascual-le Tallec^133, Reference Steppan, Bailey and Bhat¹³⁷⁾. Resistin mRNA has been isolated in the ARC and ventromedial nuclei of the hypothalamus, indicating a possible role in the regulation of VFI⁽Reference Tovar, Nogueiras and Tung¹³⁸⁾. Expression of resistin mRNA in adipose tissue is positively associated with feeding⁽Reference Steppan, Bailey and Bhat^137, Reference Savage, Sewter and Klenk¹³⁹⁾, increasing following a meal, while circulating concentrations of resistin decrease with declining body weight⁽Reference Valsamakis, McTernan and Chetty¹⁴⁰⁾. These data indicate a likely satiation role for resistin. Consistent with this, central administration of resistin in the ARC of rats induces a rapid, transient, 50 % decrease in VFI in fasted animals, and a 15 % decrease in satiated animals within 2 h of administration. There was no effect of resistin on body weight, or plasma concentrations of leptin or adiponectin with this negative effect on VFI⁽Reference Tovar, Nogueiras and Tung¹³⁸⁾, consistent with a direct central effect on VFI.

Resistin has additional physiological roles that may also associate it with VFI regulation. Mice infused with resistin exhibit impaired glucose homeostasis and insulin action⁽Reference Steppan, Bailey and Bhat^137, Reference Steppan and Lazar¹⁴¹⁾. Further evidence of resistin's involvement in energy homeostasis is in the positive and negative effects of hyperglycaemia and hyperinsulinaemia, respectively, on resistin mRNA expression⁽Reference Rajala, Lin and Ranalletta¹⁴²⁾. It is likely that resistin plays a similar role in ruminant animals because the expression of the resistin gene in adipose tissue is greater in lactating cows, when insulin concentrations are low and insulin resistance is high, than non-lactating cows⁽Reference Komatsu, Itoh and Mikawa¹⁴³⁾. Further research is required to determine whether resistin is a factor contributing to insulin resistance, or whether the insulin resistance in early lactation to facilitate use of tissue stores for milk production results in reduced resistin mRNA expression.

There are two cytokines secreted by adipose tissue that have been implicated in VFI regulation, IL-6 and TNF-α. Despite their size, these cytokines gain access to the hypothalamus via active transport systems⁽Reference Buchanan and Johnson¹⁴⁴⁾. IL-6 circulates in multiple forms with a size between 22 and 27 kDa, and the receptor for IL-6 is also expressed in adipose tissue. There are IL-6 receptors in the neurons of the ventral and dorsal nucleus of the hypothalamus of rats⁽Reference Schobitz, De Kloet and Hosboer¹⁴⁵⁾.

In humans, concentrations of IL-6 in the CSF are negatively correlated with fat mass and leptin concentration in the CSF⁽Reference Stenlof, Wernstedt and Fjallman¹⁴⁶⁾, and an injection of IL-6 can reverse the obesity observed in IL-6 knock-out mice⁽Reference Wallenius, Wallenius and Ahrén¹⁴⁷⁾. Moreover, central injection of IL-6 decreased VFI and increased energy expenditure⁽Reference Wallenius, Wallenius and Sunter¹⁴⁸⁾ in rats, indicating an anorexigenic and lipolytic function in energy metabolism. However, there are no data available on the effect of IL-6 on VFI in ruminant animals.

TNF-α is expressed in ovine and bovine adipose tissue⁽Reference Daniel, Elasser and Morrison^149, Reference Komatsu, Itoh and Hodate¹⁵⁰⁾, and plasma concentrations increase with level of fatness⁽Reference Daniel, Elasser and Morrison¹⁴⁹⁾. Peripheral administration has been shown to reduce VFI in rodents⁽Reference Buchanan and Johnson¹⁴⁴⁾. As well as transport systems that facilitate TNF-α crossing the BBB and influencing VFI directly, peripheral TNF-α also causes the secretion of leptin, possibly suppressing VFI indirectly⁽Reference Buchanan and Johnson¹⁴⁴⁾. Consistent with this, administration of leptin antisera reversed the anorexic effects of lipopolysaccharide infusion⁽Reference Harden, du Plessis and Poole¹⁵¹⁾. However, there are no data available on the effect of TNF-α on VFI in ruminant animals.

Vagus nerve

The afferent fibres of the vagus nerve are the major neuro-anatomic linkage between the alimentary tract and the hindbrain. Afferent input related to anorexigenic signals, from the GI tract, the liver and from secreted metabolites, monoamines and peptides are transmitted through the vagus nerve and sympathetic fibres to the NST in the hindbrain, where they integrate with descending hypothalamic input to produce ascending output regarding VFI to the hypothalamus⁽Reference Schwartz, Woods and Porte^34, Reference Date, Murakami and Toshinai¹⁶⁵⁾.

Vagal afferent fibres supplying the upper GI tract are sensitive to three classes of meal-related stimuli: mechanical distension of the lumen or gut contraction, chemical properties of luminal contents, and gut peptides and neurotransmitters, whose secretions have been elicited by the presence of meals in the duodenum. Schwartz et al. ⁽Reference Schwartz, McHugh and Moran¹⁶⁶⁾ demonstrated that combinations of gastric load and exogenous peptides excited gastric vagal mechanoreceptors to a greater degree than either stimulus alone. These data indicate that individual gut vagal afferents possess distinct transduction mechanisms for the different classes of meal-related negative feedback signals, and can simultaneously integrate these signals to send a coherent message regarding meal size to the intake-regulation centre in the brain.

In addition to stimulation by peptides, single vagal afferents from the ileum and jejunum are excited by lipids, especially linoleic and oleic acids, indicating a role for gut vagal afferents in the anorexigenic signal and VFI reductions elicited by lipids.

Cholecystokinin

CCK is the archetypal GI anorexigenic signal and is one of the oldest peptides identified as having an effect on VFI. First reported to elicit an anorexigenic effect in gastric-fistulated rats in the early 1970s⁽Reference Gibbs, Young and Smith¹⁶⁷⁾, it is found in the brain⁽Reference Beinfield and Palkovits¹⁶⁸⁾, acting as a neurotransmitter, and in the GI tract⁽Reference Larsson and Rehfeld¹⁶⁹⁾ in both secretory and neural tissue.

Although found widely along the GI tract, CCK is expressed in particular by enteroendocrine I cells in the duodenal and jejunal mucosa⁽Reference Stanley, Wynne and McGowan^39, Reference Moran and Kinzig^170, Reference Cummings and Overduin¹⁷¹⁾. The triangular shape of the I cell, with the apical microvilli immersed in the food-containing contents of the lumen⁽Reference Buchan, Polak and Solcia¹⁷²⁾ and the CCK secretory granules positioned at the base of the cell away from the lumen, as well as its distribution in the proximal GI tract, allow the cells to be stimulated by GI contents immediately following release from the stomach, and secrete CCK either into blood, in an endocrine fashion, or in a paracrine manner into surrounding tissue⁽Reference Moran and Kinzig¹⁷⁰⁾.

CCK is found in multiple forms⁽Reference Reeve, Eysselein and Ho¹⁷³⁾, but all are derived from a single gene by post-translational or extracellular processing⁽Reference Moran and Kinzig¹⁷⁰⁾. Preprocholecystokinin is a 115-amino acid polypeptide that succumbs to cleavage to first form pro-CCK and subsequently CCK-58, the most processed form of CCK in most tissues⁽Reference Eng, Li and Yalow¹⁷⁴⁾. All of the shorter forms of CCK are formed by monobasic or dibasic residues, and many of these smaller forms are found, together with CCK-58, in various tissues and in blood⁽Reference Little, Horowitz and Feinle-Bisset¹⁷⁵⁾.

CCK exerts a number of biological actions within the GI tract and beyond. Its release from the intestine is stimulated by the presence of digestive products in the GI lumen. Levels rise immediately, peaking within 30 min in cows⁽Reference Choi, Palmquist and Allen¹⁷⁶⁾, and can remain elevated for 3–5 h post-feeding⁽Reference Moran and Kinzig¹⁷⁰⁾. Dietary fat and protein appear to be the most potent stimulators of CCK release in single-stomached animals, although the abomasal infusion of a starch hydrolysate in steers increased the plasma concentration of CCK while the infusion of casein tended to reduce blood concentrations of the peptide⁽Reference Swanson, Benson and Matthews¹⁷⁷⁾. Physiologically relevant concentrations of CCK have been implicated in reduced gastric emptying, stimulation of gallbladder contractions⁽Reference Liddle, Goldfine and Rosen¹⁷⁸⁾ and the postprandial delivery of bile to the duodenum, pancreatic secretions, and stimulation of the vagus nerve. The presence of CCK receptors in the gall bladder of the cow⁽Reference Schjoldager, Molero and Miller¹⁷⁹⁾ indicates similar digestive effects of CCK in ruminant animals to those noted in single-stomached species.

In addition to its importance in the digestion of food, CCK has also been identified as an important anorexigenic peptide. Fulfilling all of the requirements of an anorexigenic stimulus, CCK rises with the presence of nutrients in the lumen of the GI tract and the pattern of feeding behaviour is altered by exogenous administration of physiologically relevant doses. CCK has now been shown to inhibit VFI across many species. When Gibbs et al. ⁽Reference Gibbs, Young and Smith¹⁶⁷⁾ injected rats peripherally with CCK before a meal, meal size and duration were reduced. In addition, exogenous CCK administration to unfed rats resulted in behaviours characteristic of satiation⁽Reference Antin, Gibbs and Smith¹⁸⁰⁾. The latter experiment highlights that the satiation actions of CCK are not only a result of delayed gastric emptying and subsequent gastric mechanoreceptor stimulation, although Moran & McHugh⁽Reference Moran and McHugh¹⁸¹⁾ provided evidence that this is one VFI-regulation mode of action of CCK.

CCK peptides bind with two receptors, CCK1R and CCK2R (formerly known as CCK_A and CCK_B, respectively). Both receptors are members of the seven transmembrane G protein-coupled receptor family⁽Reference Moran and Kinzig¹⁷⁰⁾ and the relative distribution of these receptors varies across species. CCK1R is found in the GI tract, the peripheral nervous system, and the brain, whilst CCK2R is primarily found in the brain⁽Reference Moran and Kinzig¹⁷⁰⁾.

CCK secreted by the proximal GI tract is proposed to work in a paracrine fashion, stimulating CCK1R receptors on the sensory fibres of the vagus nerve, thereby activating neurons in the NST in the hindbrain⁽Reference Moran and Kinzig^170, Reference Zittel, Glatzle and Kreis¹⁸²⁾. The signal initiates local reflexes and is relayed to the forebrain. This pathway is consistent with the reduction in the anorexigenic effects of CCK when the majority of the medial and commissural subnuclei of the NST as well as the area postrema are lesioned⁽Reference Edwards, Ladenheim and Ritter¹⁸³⁾, supporting the role of gastric afferent projections in the mediation of CCK-induced anorexigenic signals.

The distribution and biological activity of CCK has also been studied in ruminant species. Choi et al. ⁽Reference Choi, Palmquist and Allen¹⁷⁶⁾ reported that CCK mediates the depression in VFI in dairy cattle fed high-fat diets. Consistent with this effect, Simon-Assmann et al. ⁽Reference Simon-Assmann, Yazigi and Greeley¹⁸⁴⁾ reported that the distribution and biological activity of CCK is similar in rat and cow brains, suggesting similar effects of the peptide across the species. Farningham et al. ⁽Reference Farningham, Mercer and Lawrence¹⁸⁵⁾ examined the effect of propionate and CCK on VFI. Individual infusions of either CCK or propionate did not affect VFI, but a simultaneous infusion of CCK and propionate decreased VFI by 40 %. These data possibly implicate CCK in the termination of meals in ruminant livestock, but suggest an interaction with metabolites and nutrients of digestive processes.

Ghrelin

Ghrelin is a twenty-eight-amino acid (twenty-seven in the bovine) peptide produced predominantly in the oxyntic cells of the stomach (abomasum in ruminant animals). It was originally identified as the endogenous ligand for the growth hormone (GH) secretagogue receptor (GHS-R)⁽Reference Roche, Sheahan and Chagas¹⁵⁵⁾, mediating the release of pituitary GH through an alternative to the classical mechanisms of GH release mediated by the GH-releasing factor (GRF)⁽Reference Truett and Parks¹⁸⁶⁾. However, it quickly became evident that this hormone also has robust effects on VFI and metabolism⁽Reference Stein and Woods^164, Reference Nakazato, Murakami and Date¹⁵⁷⁾.

Extensive research since its discovery has identified the orexigenic effects of ghrelin in single-stomached animals⁽Reference Nakazato, Murakami and Date^157, Reference Wren, Seal and Cohen^158, Reference Neary, Small and Wren¹⁸⁷⁾, and more recently Wertz-Lutz et al. ⁽Reference Wertz-Lutz, Knight and Pritchard¹⁵⁹⁾ and Harrison et al. ⁽Reference Harrison, Miller and Findlay¹⁶⁰⁾ reported similar effects in sheep and cattle. Central and peripheral infusion of ghrelin stimulates NPY and AgRP neurons in the hypothalamus⁽Reference Kamegai, Tamura and Shimizu^188, Reference Shintani, Ogawa and Ebihara¹⁸⁹⁾, and immunohistochemical analyses indicate that ghrelin neuron fibres are in direct contact with NPY and AgRP neurons⁽Reference Cowley, Smith and Diano^190, Reference Kojima and Kangawa¹⁹¹⁾. These data indicate that ghrelin increases the sensation of orexigenic feelings, and presumably VFI, by stimulating NPY and AgRP neurons in the hypothalamus to secrete the orexigenic NPY and AgRP peptides, respectively⁽Reference Kojima and Kangawa¹⁹¹⁾.

Ghrelin secretion is pulsatile⁽Reference Bagnasco, Kalra and Kalra¹⁹²⁾. In sated rats, ghrelin secretory episodes consist of low-amplitude pulses discharged at a regular frequency of two episodes per h⁽Reference Kalra, Ueno and Kalra¹⁹³⁾. However, an apparent orexigenic drive, elicited by the negative energy balance following food deprivation, coincides with high-amplitude pulses at about three episodes per h⁽Reference Kalra, Ueno and Kalra¹⁹³⁾. Thus, when energy intake and expenditure are balanced, ghrelin secretion appears to be restrained⁽Reference Kalra, Ueno and Kalra¹⁹³⁾, but reduced energy resources rapidly curb this restraint to allow increased episodic ghrelin discharge⁽Reference Bagnasco, Kalra and Kalra¹⁹²⁾.

There are two forms of circulating ghrelin; an active (acylated) and inactive (des-acylated) form. Acylation of ghrelin is necessary for ghrelin to bind to the GHS-R and to cross the BBB⁽Reference Murphy and Bloom¹⁹⁴⁾, while the inactive (des-acylated) form of ghrelin is activated by the addition of an octanoyl group (eight-carbon fatty acid) to the serine residue at position three.

Synthesis and secretion of ghrelin appear to be regulated by nutritional state. Circulating ghrelin concentrations decrease postprandially in both single-stomached⁽Reference Nakazato, Murakami and Date¹⁵⁷⁾ and ruminant animals⁽Reference Sugino, Hasegawa and Kikkawa^154–Reference Roche, Sheahan and Chagas^156, Reference Hayashida, Murakami and Mogi¹⁹⁵⁾. Consistent with its role as an endocrine and not distension-mediated peptide, plasma ghrelin declines rapidly following the gastric infusion of glucose or fat, but not water⁽Reference Overduin, Frayo and Grill¹⁹⁶⁾, and following the intravenous infusion of glucose in human subjects⁽Reference Hotta, Ohwada and Hideki¹⁹⁷⁾, rodents⁽Reference McCowen, Maykel and Bistrian¹⁹⁸⁾ and ruminant animals⁽Reference Roche, Sheahan and Chagas¹⁹⁹⁾. Overduin et al. ⁽Reference Overduin, Frayo and Grill¹⁹⁶⁾ also reported an effect of feed type, with isoenergetic intestinal infusions of either glucose or amino acids suppressing ghrelin concentrations more rapidly and effectively than lipid infusions. Further evidence that the effect of ghrelin is not distension-mediated is that gastric glucose infusion, while blocking the pyloric exit from the stomch, did not affect plasma ghrelin levels⁽Reference Williams, Cummings and Grill²⁰⁰⁾.

Initial epidemiological studies in ruminant animals indicated a similar role for ghrelin in VFI regulation as was identified in single-stomached species. Roche et al. ⁽Reference Roche, Sheahan and Chagas¹⁵⁶⁾ reported a postprandial decline in VFI, a positive correlation between genetic selection for production and plasma ghrelin concentration, and for the first time provided a neuroendocrine basis for substitution rate in grazing ruminant animals (i.e. the phenomenon by which animals reduce their time spent grazing when fed a supplement; 12 min/kg supplement⁽Reference Bargo, Muller and Kolver¹⁹⁾). Consistent with these data, Sugino et al. ⁽Reference Sugino, Hasegawa and Kikkawa¹⁵⁴⁾ also reported the pre- and postprandial trends in ghrelin concentration in sheep, and identified effects of feeding regimen on the intensity of the ghrelin pulses; preprandial ghrelin pulses were greater in sheep fed twice daily than those fed four times daily, possibly reflecting a greater orexigenic sensation in animals fed less frequently. They also reported a temporal increase in plasma GH concentrations followed a single pulse in plasma ghrelin, suggesting that the increase in ghrelin stimulated the GH surge during feeding.

Studies where ghrelin was infused into ruminant animals are few and the results are inconsistent. Iqbal et al. ⁽Reference Iqbal, Kurose and Canny²⁰¹⁾ reported no effect of ghrelin, infused either intravenously or intraperitoneally, on VFI in sheep. However, Harrison et al. ⁽Reference Harrison, Miller and Findlay¹⁶⁰⁾ reported an interaction of ghrelin with photoperiod, with a two-fold increase in VFI for the hour post-ghrelin infusion on long-day photoperiod, but not short-day. In comparison, Wertz-Lutz et al. ⁽Reference Wertz-Lutz, Knight and Pritchard¹⁵⁹⁾ demonstrated an increase in VFI in beef cattle during the hour following a subcutaneous ghrelin infusion, but Roche et al. ⁽Reference Roche, Sheahan and Chagas¹⁹⁹⁾ reported no effect of continuously infused ghrelin on VFI in early lactation dairy cows. Further research is required to understand the effect of ghrelin on VFI in ruminant species, and the factors modifying that effect.

Ghrelin might also affect VFI indirectly via an effect on body tissue stores. Theander-Carrillo et al. ⁽Reference Theander-Carrillo, Wiedmer and Cettour-Rose²⁰²⁾ demonstrated that a central ghrelin infusion independently regulated adipocyte metabolism in rats, partitioning more nutrients toward fat storage by increasing lipogenesis and inhibiting lipid oxidation in white adipocytes. Interestingly though, when the same amount of ghrelin was administered peripherally, none of the central ghrelin affects was seen⁽Reference Theander-Carrillo, Wiedmer and Cettour-Rose²⁰²⁾. These results indicate that central ghrelin may ‘prime’ tissue to store energy as fat by altering adipocyte enzyme expression, and the authors have speculated that pre-feeding ghrelin peaks may be triggering meal preparation processes in the CNS, rather than actually initiating meals. Tissue-specific changes were also seen with changes in mitochondrial and lipid metabolism gene expression favouring TAG deposition in the liver over skeletal muscle⁽Reference Barazzoni, Bosutti and Stebel²⁰³⁾, suggesting that ghrelin could be involved in adaptive changes of lipid distribution and metabolism in the presence of energy restriction and loss of body fat⁽Reference Barazzoni, Bosutti and Stebel²⁰³⁾. In comparison, Roche et al. ⁽Reference Roche, Sheahan and Chagas¹⁹⁹⁾ continuously infused ghrelin subcutaneously for 8 weeks in lactating dairy cows and found increased BCS loss and plasma NEFA concentrations, and lower leptin concentrations, suggesting that the effect of ghrelin on adipocyte function may differ in dairy cows, particularly in early lactation when the mobilisation of body reserves is extensive.

The factors regulating ghrelin secretion remain unclear. Although ghrelin concentrations drop rapidly in response to glucose infusion⁽Reference Hotta, Ohwada and Hideki^197, Reference Roche, Sheahan and Chagas¹⁹⁹⁾, clamp studies in rodents have indicated that neither glucose nor insulin elicits the decline⁽Reference Schaller, Schmidt and Pleiner²⁰⁴⁾. Data from dairy cows⁽Reference Roche, Sheahan and Chagas¹⁹⁹⁾ identify a rapid drop in plasma ghrelin concentrations following glucose infusion, but the data could not discount a role of insulin in this process. Kalra et al. ⁽Reference Kalra, Ueno and Kalra¹⁹³⁾ propose that leptin was the factor that inhibited gastric secretion of ghrelin and the stimulation of feeding by ghrelin. Rhythmic fluctuations in circulating concentrations of leptin have been observed in response to shifts in energy balance⁽Reference Bagnasco, Kalra and Kalra¹⁹²⁾. When comparing pulse amplitude between ghrelin and leptin during energy deprivation, ghrelin is markedly increased whereas energy deprivation diminishes leptin pulse amplitude, thereby diminishing overall leptin output⁽Reference Bagnasco, Kalra and Kalra¹⁹²⁾. This reciprocal relationship is seen both pre- and post-feeding, with lower circulating levels of leptin corresponding to greater circulating concentrations of ghrelin pre-feeding, and a gradual rise in postprandial leptin secretion preceding the decline in ghrelin secretion⁽Reference Tschop, Wawarta and Riepl^205, Reference Crowley, Ramoz and Keefe²⁰⁶⁾.

Obestatin

Obestatin is a recently discovered twenty-three-amino acid peptide transcribed on the preproghrelin gene, with a flanking conserved glycine residue at the end C-terminus⁽Reference Zhang, Ren and Avsian-Kretchmer²⁰⁷⁾, and is secreted in a pulsatile manner⁽Reference Zizzari, Longchamps and Epelbaum²⁰⁸⁾. Obestatin, administered both centrally and peripherally, produces an anorexigenic response, and reduces gut motility, gastric emptying and body weight⁽Reference Zhang, Ren and Avsian-Kretchmer^207, Reference Green, Irwin and Flatt²⁰⁹⁾. Obestatin inhibited water imbibing in freely fed and watered rats and in food- and water-deprived rats⁽Reference Samson, White and Price²¹⁰⁾. The effects on water consumption preceded and were more pronounced than any effect on VFI, and Samson et al. ⁽Reference Samson, White and Price²¹⁰⁾ concluded that the effects of obestatin on VFI may be secondary to an action of the peptide on imbibing water.

Zhang et al. ⁽Reference Zhang, Ren and Avsian-Kretchmer²⁰⁷⁾ reported that the C-terminus required amidation for obestatin to be biologically active. First reports indicated that obestatin binds to the orphan receptor GPR39, which shows similarities with GHS-R1a⁽Reference Zhang, Ren and Avsian-Kretchmer²⁰⁷⁾. GPR39 mRNA was detected in the hypothalamus by RT-PCR, and ¹²⁵I-labelled obestatin binding sites were reported in the same region⁽Reference Green, Irwin and Flatt²⁰⁹⁾. However, more recent studies failed to confirm the presence of specific obestatin binding to GPR39, or activation of this receptor by obestatin⁽Reference Holst, Egerod and Schild^211, Reference Nogueiras, Pfluger and Tovar²¹²⁾. Furthermore, GPR39 expression has been detected in peripheral organs such as the jejunum, duodenum, stomach, ileum and liver, and to a lesser extent in the pancreas and kidney, but not in the pituitary or hypothalamus, which are presumed to be the central target organs for obestatin⁽Reference Nogueiras, Pfluger and Tovar²¹²⁾. It has also been reported that obestatin does not cross the BBB⁽Reference Pan, Tu and Kastin²¹³⁾, suggesting that its role in VFI regulation may be at a peripheral tissue level.

Obestatin immunoreactivity positively correlated with insulin concentrations, and since acylated (active) ghrelin, which is also found in the pancreas, inhibits insulin secretion, it has been suggested that obestatin may potentiate insulin release⁽Reference Chanoine, Wong and Barrios²¹⁴⁾. This was confirmed (JR Roche, JK Kay, AJ Sheahar, RC Boston and LM Chagas, unpublished results) in dairy cows, when obestatin-infused cows exhibited a two-fold increase in the area under the insulin curve following a glucose infusion, indicating a doubling of β-cell function. Similarly, glucose and insulin responses were lowered by 64 to 77 % and 39 to 41 %, respectively, in mice that received either the full or truncated obestatin via intraperitoneal administration 4 h before a 15 min period of feeding⁽Reference Green, Irwin and Flatt²⁰⁹⁾. This was accompanied by a 43 and 53 % reduction in VFI respectively, confounding the effect of VFI and obestatin on insulin secretion. Green et al. ⁽Reference Green, Irwin and Flatt²⁰⁹⁾ administered obestatin under basal and glucose challenges to determine whether effects were independent of changes in feeding. No alterations in glucose and insulin responses were evident, suggesting, at least in mice, that obestatin had no direct action on glucose or insulin secretion⁽Reference Green, Irwin and Flatt²⁰⁹⁾.

In addition, both in vitro and in vivo studies on the administration of exogenous obestatin could not stimulate GH release as seen with both peripheral and central administration of ghrelin⁽Reference Zizzari, Longchamps and Epelbaum^208, Reference Samson, White and Price²¹⁰⁾, thereby showing that exogenous obestatin does not act directly on GH. However, when obestatin and ghrelin are co-administered, the in vivo ghrelin-induced GH secretion was markedly reduced⁽Reference Zizzari, Longchamps and Epelbaum²⁰⁸⁾, implicating obestatin in an attenuation of ghrelin activity.

Clearly, as this is a newly discovered peptide and all work published to date is on rats and mice, more intensive studies need to be performed to validate the role of obestatin in maintaining energy balance, especially in the ruminant animal.

Peptide YY_3–36

Peptide YY is produced and secreted primarily from the enteroendocrine L cells in the distal end of the GI tract⁽Reference Kim, Carlson and Jang²¹⁵⁾. It was first isolated from porcine jejunal mucosa nearly 30 years ago⁽Reference Tatemoto and Mutt²¹⁶⁾, is structurally homologous to NPY and pancreatic polypeptide, exhibiting the pancreatic polypeptide-fold motif and requiring the characteristic carboxy-terminal amidation required for bioactivity⁽Reference Choi, Palmquist and Allen¹⁷⁶⁾, and is a known anorexigenic signal.

Cells that produce PYY are endocrine in nature and the peptide is secreted postprandially. The amount of the peptide secreted is partly in proportion to the energy content of the meal. However, it is also influenced by meal composition, with isoenergetic diets containing fat resulting in greater secretion⁽Reference Stanley, Wynne and Bloom²¹⁷⁾. Although concentrations rise within 30 min of eating, peak PYY does not occur for several hours⁽Reference Taylor²¹⁸⁾. Peripheral administration of PYY has an anorexic effect in mice⁽Reference Batterham, Cowley and Small^219, Reference Halatchev, Ellacot and Fan²²⁰⁾, significantly delaying gastric emptying, gastric and pancreatic secretion, and the cephalic phase of gallbladder emptying⁽Reference Stanley, Wynne and Bloom²¹⁷⁾. Consistent with this, circulating concentrations of PYY are less in obese patients⁽Reference le Roux, Batterham and Aylwin²²¹⁾, and this attenuation has been associated with a reduced feeling of satiety. Peptide YY is therefore associated with a reduced GI passage rate, making PYY a likely candidate for the chemical messenger invoking the ‘ileal brake’ phenomenon, controlling the transit of feed through the GI tract to optimise nutrient digestion and absorption⁽Reference Bird, Croom and Fan²²²⁾. In addition, PYY has been reported to increase active jejunal glucose transport in mice and dogs⁽Reference Bird, Croom and Fan^222, Reference Bilchik, Hines and Zinner²²³⁾. The reduced passage rate and the increase in glucose absorption would be expected to have anorexigenic effects.

Interestingly, central administration of PYY has orexigenic effects similar to NPY in mice⁽Reference Hagan²²⁴⁾ and sheep⁽Reference Miner, Della-Fera and Peterson²²⁵⁾, suggesting that PYY does not have broad access to Y receptors in the hypothalamus, but instead gains selective access to Y2 receptors, thereby blocking the orexigenic effects of NPY and AgRP, and allowing the expression of the anorexigenic melanocortin-producing cells⁽Reference Batterham, Cowley and Small²¹⁹⁾.

Despite the obvious anorexic effect of PYY, there is little information on PYY in ruminant animals. Onaga et al. ⁽Reference Onaga, Yoshida and Inoue²²⁶⁾ studied the distribution and function of PYY in sheep. Mucosal concentrations of PYY were much less in sheep compared with those in the rat, and the sheep showed little fluctuation in plasma concentrations of PYY over a 48 h period, leaving the authors to conclude that PYY is unlikely to play the same role in ruminant animals as has been reported in single-stomached species. However, the infusion of PYY in sheep shortened the second cycle of migrating myoelectric complexes and delayed duodenal emptying⁽Reference Onaga, Yoshida and Inoue²²⁶⁾, consistent with the reported effects in single-stomached animals. Further research is required to determine the effect of physiological state and diet on the circulating concentrations of this peptide, and whether its exogenous administration alters VFI patterns in production farm animals.

Cannabinoids

The first steps in the identification of the role that cannabinoids play in animal physiology date back thousands of years, when the recognised therapeutic and psychotropic actions of Cannabis sativa were first documented in India⁽Reference Pagotto, Marsicano and Cota²²⁷⁾. In addition to their psychotropic effects (ataxia, short-term memory loss, a sense of time dilation, euphoria⁽Reference Kirkham and Williams²²⁸⁾), both endogenous and exogenous cannabinoids can have multiple physiological effects, including a general inhibition of neuroendocrine function, reducing GH response to hypoglycaemia, and reducing the secretion of testosterone and luteinising hormone⁽Reference Pagotto, Marsicano and Cota²²⁷⁾.

Cannabinoids (CB) work through a family of G-protein-linked cell-surface receptors. To date two receptor subtypes have been identified (CB1 and CB2), with CB1 predominantly regarded as the prominent receptor of the CNS and some peripheral tissues and CB2, which is not expressed to any significant degree within the CNS⁽Reference Breivogel and Childers²²⁹⁾. According to Kirkham & Williams⁽Reference Kirkham and Williams²³⁰⁾, it is generally agreed that the behavioural effects of cannabinoids are mediated by CB1. This is consistent with the suppression of VFI in laboratory animals treated with a selective CB1 antagonist, SR141716⁽Reference Colombo, Agabio and Diaz^231, Reference Simiand, Keane and Keane²³²⁾.

Δ⁹-Tetrahydrocannabinol

Pagotto et al. ⁽Reference Pagotto, Marsicano and Cota²²⁷⁾ used two examples to highlight the importance of the endocannabinoid system in VFI regulation. The first was the discovery that there has been a high degree of evolutionary conservation in the endocannabinoid system, and the second being the recognition that high levels of endocannabinoids in maternal milk are critical for initiation of the suckling response in the neonate, at least in mice⁽Reference Fride, Ginzburg and Breuer²³³⁾. Consistent with this positive effect on VFI, Δ⁹-tetrahydrocannabinol (Δ⁹-THC), the primary active psychoactive constituent of marijuana, results in increased VFI when administered at low doses⁽Reference Pagotto, Marsicano and Cota²²⁷⁾. Williams et al. ⁽Reference Williams, Rogers and Kirkham²³⁴⁾ reported a four-fold increase in VFI following an oral dose of 1 mg Δ⁹-THC/kg body weight; doses greater than this did not result in hyperphagia, probably because of the sedative effects of Δ⁹-THC. This orexigenic effect of Δ⁹-THC has been shown in rodents and humans, with Δ⁹-THC now prescribed for numerous anorexic-type conditions (for example, AIDS, cancer treatment). However, there is as yet no information available on its effects in ruminant animals, although hempseed was regarded as a source of high-quality rumen-bypass protein for cows and sheep⁽Reference Mustafa, McKinnon and Christensen²³⁵⁾, with no detrimental effects on VFI reported when hemp meal was included at 20 % of the ration DM. This lack of effect on VFI may be as a result of low concentrations of Δ⁹-THC in industrial hemp.

Endocannabinoids

Although the effect of exogenously administered cannabinoids is interesting, and their possible role in manipulating VFI should be investigated further in ruminant animals, the primary interest in this system in relation to VFI regulation is in the endogenous lipid ligands, most notably palmitoylethanolamide, donoylethanolamide and oleoylethanolamide.

Endocannabinoids have been reported to have both orexigenic and anorexigenic effects. Donoylethanolamide, otherwise known as anandamide or donoylethanolamide, has been shown to increase VFI in rodents. Williams & Kirkham⁽Reference Williams and Kirkham²³⁶⁾ demonstrated a donoylethanolamide-induced, CB1-mediated hyperphagia, providing important evidence for the involvement of a central cannabinoid system in the normal control of eating.

The most widely researched from a VFI-regulation point of view is oleoylethanolamide. Oleoylethanolamide is a natural analogue of the endogenous cannabinoid, anandamide (arachidonoylethanolamide)⁽Reference Gaetani, Cuomo and Piomelli²³⁷⁾, but it does not activate the cannabinoid receptors⁽Reference Piomelli, Beltramo and Giuffrida²³⁸⁾. When administered intraperitoneally or orally, it has been shown to be a potent anorexigenic agent⁽Reference Julin Nielsen, Petersen and Astrup^239–Reference Wang, Miyares and Ahern²⁴¹⁾. This effect is due to a selective change in the onset and frequency of feeding, indicating that the endocannabinoid system may alter the appetite value of ingested substances. Pagotto et al. ⁽Reference Pagotto, Marsicano and Cota²²⁷⁾ suggested that this idea was consistent with the evidence in favour of a facilitatory function of the endocannabinoid system on brain reward circuits, bringing forward the onset of eating in satiated animals and increasing the incentive value of the feed eaten, regardless of the quality of the food.

Endocannabinoid regulation of VFI has been reported to be modulated by leptin. Di Marzo et al. ⁽Reference Di Marzo, Melck and Bisogno²⁴²⁾ reported that donoylethanolamide in the hypothalamus of mice was reduced with leptin infusion. Their data inferred that the leptin-induced anorexigenic effect may be, in part, endocannabinoid modulated, and a possible association between a hypothalamic overactivation of the endocannabinoid system and hyperphagia. Pagotto et al. ⁽Reference Pagotto, Marsicano and Cota²²⁷⁾ points out, however, that the intrahypothalamic amount of endocannabinoids during the development of obesity must be investigated before such a general conclusion can be drawn. There are no reports of the effect of endocannabinoids on VFI in ruminant livestock, but considering its apparent importance in single-stomached physiology, it is also likely to play some role in ruminant VFI regulation, and further research is required to determine effects.

Insulin

Insulin is a fifty-one-amino acid peptide hormone produced by the β-cells of the pancreatic islets of Langerhans. It plays a key role in energy homeostasis, reducing hepatic glucose production through its suppression of glucagon, and increasing glucose utilisation by peripheral tissues sensitive to its action. Basal insulin concentrations are generally proportional to body fat⁽Reference McCann, Bergman and Beermann^94, Reference Caldeira, Belo and Santos^95, Reference León, Hernandez-Ceron and Keisler²⁴⁹⁾, thereby providing a peripheral adiposity signal to the CNS for long-term regulation of body weight⁽Reference Schwartz, Woods and Porte^34, Reference Schwartz, Figlewicz and Baskin²⁴³⁾. This relationship is more complex in production animals that undergo periods of weight change⁽Reference León, Hernandez-Ceron and Keisler²⁴⁹⁾, with the relationship evident in ruminant animals during periods of weight gain, but not during periods of weight loss or weight maintenance. In addition, insulin's role in glucose disposal indicates that it may also play a role in the short-term regulation of VFI.

Insulin rises within minutes of feed ingestion⁽Reference Allen, Bradford and Harvatine²⁵⁰⁾, with cephalic-phase pancreatic β-cell secretion of insulin in ruminant animals stimulated by projections from the abomasum, pyloric and duodenal branches of the vagus nerves⁽Reference Herath, Reynolds and MacKenzie²⁵¹⁾. In contrast, postprandial insulin secretion in ruminant animals is mediated by the central histaminergic system, with enhanced neural histamine levels elevating plasma insulin concentration and reducing VFI⁽Reference Kurose and Terashima²⁵²⁾.

In many studies, the short-term effects of insulin on VFI have been confounded by the resultant induced hypoglycaemia, and associated compensatory factors that may affect a return to eating. However, icv administration of insulin in sheep reduced VFI, depressed body weight after 6 d, and halved peripheral serum insulin concentrations⁽Reference Foster, Ames and Emery²⁵³⁾, indicating a non-glucose-mediated insulin effect on VFI. Consistent with this, neuronal insulin receptor gene inactivation in mice increased VFI, obesity, insulin resistance and plasma insulin levels⁽Reference Brüning, Gautam and Burkes²⁵⁴⁾.

Peripheral administration of insulin in hyperinsulinaemic–euglycaemic clamp studies has also confirmed that short-term VFI in ruminant species is decreased with insulin infusion, without hypoglycaemia⁽Reference Bareille and Faverdin^255, Reference Faverdin, Bareille, van der Heide, Huisman, Kanis, Osse and Verstegen²⁵⁶⁾. Similarly, moderate level (6 mU/kg live weight) intra-jugular infusions of insulin, which elevated plasma insulin concentrations without depressing blood glucose, depressed VFI within 1 h of infusion, and over a 24 h period, in wether sheep fed roughage- or concentrate-based diets⁽Reference Deetz and Wangsness^257, Reference Deetz and Wangsness²⁵⁸⁾. However, aspects of insulin's short-term action on VFI remain unclear. Central infusion of insulin depressed VFI and body weight in rats fed a high-carbohydrate diet, but not those fed a high-fat diet⁽Reference Arase, Fisler and Shargill²⁵⁹⁾, suggesting insulin's effects may be modified by diet. To further complicate matters, the ruminal microbial fermentation of ingested carbohydrates and a reliance on hepatic gluconeogenesis suggests that insulin-mediated regulation of VFI in ruminant animals probably differs from single-stomached omnivores.

Most if not all of the insulin in the adult brain is of pancreatic origin⁽Reference Schwartz, Figlewicz and Baskin^243, Reference Finglewicz²⁶⁰⁾. Insulin rapidly crosses the BBB by means of saturable receptor-mediated uptake⁽Reference Baura, Schwartz and Foster²⁶¹⁾ in proportion to circulating concentrations⁽Reference Woods and Porte²⁶²⁾. Insulin receptors have been detected in the brain regions concerned with olfaction, the motivating and reward aspects of VFI driving orexigenic and anorexigenic signals, and the hypothalamic areas relating to energy metabolism and VFI⁽Reference León, Hernandez-Ceron and Keisler^249, Reference Finglewicz^260, Reference Werther, Hogg and Oldfield^263, Reference Archer, Rhind and Kyle²⁶⁴⁾. Given its high concentration of insulin receptors⁽Reference Archer, Rhind and Kyle²⁶⁴⁾, the ARC appears to be the primary site for integrating peripheral adiposity signals at a neuronal level⁽Reference Schwartz, Woods and Porte^34, Reference Porte, Baskin and Schwartz²⁶⁵⁾.

Insulin has a double-pronged mode of action in controlling VFI, reducing the expression of orexigenic signals while heightening the feeling of satiety. Central insulin infusion to fasted rats inhibited prepro-NPY mRNA expression in the ARC, reducing NPY concentrations in the paraventricular nucleus of the hypothalamus⁽Reference Schwartz, Sipols and Marks²⁶⁶⁾, while increasing POMC mRNA expression⁽Reference Benoit, Air and Coolen²⁶⁷⁾. Consistent with this mode of action, antagonists to melanocortin have been reported to block the anorectic action of insulin⁽Reference Benoit, Air and Coolen²⁶⁷⁾.

As well as a direct effect on the orexigenic and anorexigenic centres, it is likely that insulin acts indirectly on VFI by modulating the effect of leptin on these centres. Leptin and insulin share intracellular signalling pathways in hypothalamic neurons⁽Reference Baskin, Figlewicz Lattemann and Seeley^268–Reference Niswender and Schwartz²⁷⁰⁾, with insulin modulating the leptin signal transduction pathway in the hypothalamus of rats⁽Reference Carvalheira, Siloto and Ignacchitti²⁷¹⁾. Subcutaneous insulin injection of fasted rats increased ob mRNA levels to that of fed animals within 4 h, independent of insulin effects on glucose levels or the effects of re-feeding. These results indicate a role for insulin in mediating the effects of food intake on short-term leptin gene expression in rodents⁽Reference Saladin, De Vos and Guerre-Millo²⁷²⁾. Consistent with these data, plasma concentrations of insulin and leptin are positively correlated in lambs⁽Reference Tokuda, Kimura and Fujihara²⁷³⁾ and gestating beef cows⁽Reference Lents, Wettermann and White²⁷⁴⁾. Similarly, dairy cow studies using a hyperinsulinaemic–euglycaemic clamp reported that plasma leptin and adipose leptin mRNA levels were increased by hyperinsulinaemia, although the response was attenuated in early lactation cows⁽Reference Block, Rhoads and Bauman^275, Reference Leury, Baumgard and Block²⁷⁶⁾. Block et al. ⁽Reference Block, Rhoads and Bauman²⁷⁵⁾ concluded that insulin is a positive regulator of leptin synthesis in dairy cows during periods of positive energy balance. In comparison, central leptin infusion was associated with an increase in plasma insulin in fasted (60 h) but not fed beef cows, inferring that insulin secretion is heightened by leptin under restricted feed intake⁽Reference Amstalden, Garcia and Stanko²⁷⁷⁾. While it is evident that insulin and leptin are closely linked, research is required to elucidate further the role of this interaction in ruminant animals under different physiological states and energy balances.

Further indirect effects of insulin are probably mediated through its effect on other orexigenic and anorexigenic agents. Roche et al. ⁽Reference Roche, Sheahan and Chagas²⁷⁸⁾ reported a rapid decline in circulating ghrelin concentrations in dairy cows subjected to an intravenous glucose infusion, and a gradual rise in the orexigenic agent with the insulin-mediated reduction in blood glucose. Insulin down-regulates phosphoenolpyruvate carboxykinase mRNA expression, a rate-limiting enzyme of gluconeogenesis, and this effect has been shown to be partially reversed by ghrelin⁽Reference Murata, Okimura and Iida²⁷⁹⁾. Although plasma insulin levels were not affected when bovine ghrelin was injected into the jugular of steers fed once per d⁽Reference Batterham, Le Roux and Cohen¹⁶¹⁾ or 2, 3-diaminopropanoic acid-octanoylated human ghrelin was continuously infused in dairy cows⁽Reference Roche, Sheahan and Chagas¹⁹⁹⁾, intramuscular ghrelin injections for 10 d before lambing decreased serum insulin concentrations in peripartum ewes⁽Reference Melendez, Hofer and Donovan²⁸⁰⁾. In comparison, continuous subcutaneous infusion of the reputed anorexigenic agent, obestatin, doubled pancreatic β-cell function and resulted in double the insulin response to an intravenous glucose infusion in early lactating dairy cows (JR Roche, JK Kay, AJ Sheahan, RC Boston and LM Chagas, unpublished results).

Another hormone through which insulin exerts an anorexic effect could be CCK. Central insulin infusion in rats, at levels not affecting VFI, enhanced the anorexic effect of CCK and reduced meal size⁽Reference Riedy, Chavez and Figlewicz²⁸¹⁾. However, plasma insulin concentrations were not altered by intravenous injections of a CCK antagonist in dairy cows⁽Reference Choi, Palmquist and Allen¹⁷⁶⁾, indicating CCK does not influence insulin secretion. Further research is required to clarify the relationship between insulin and other peptides involved in the regulation of VFI.

Although it is generally accepted that insulin increases with adiposity⁽Reference McCann, Bergman and Beermann⁹⁴⁾, the relationship is not straightforward in production ruminant species. Weak correlations between plasma insulin concentration and BCS in mature lactating dairy cows led Bradford & Allen⁽Reference Bradford and Allen²⁸²⁾ to conclude that insulin is a poor adiposity signal for long-term VFI control in ruminant species. Similarly, Lents et al. ⁽Reference Lents, Wettermann and White²⁷⁴⁾ reported that BCS only accounted for 12 % of the variation in plasma insulin and leptin levels when gestating beef cows were grazed under similar pasture feeding conditions. However, there was a positive correlation between the variables when the same cows had differing nutrient intakes, indicating a possible interaction between chronic and acute energy balance status and insulin concentrations. This is consistent with data reported by Caldeira et al. ⁽Reference Caldeira, Belo and Santos⁹⁵⁾, who fed non-pregnant, non-lactating ewes at 30 or 200 % of maintenance energy requirements over a period of 60–72 weeks and found different serum insulin profiles across the same BCS range, depending on whether animals were increasing or decreasing in adiposity. In furthering our understanding of this interaction, León et al. ⁽Reference León, Hernandez-Ceron and Keisler²⁴⁹⁾ fed beef heifers to decline to, and then maintain, BCS at less than 2 (scale 1–9) for at least 25 d; they then fed them to gain 1 kg body weight/d until a BCS of 6 was reached. They reported no relationship between insulin concentrations and BCS during the period of negative energy balance, but positive correlations were seen during weight gain. As circulating insulin concentrations depend on peripheral tissue sensitivity⁽Reference Porte, Baskin and Schwartz²⁶⁵⁾, interpretation of peripheral insulin concentrations needs to account for both the direction of body-weight change and the animal's recent nutritional history, particularly when adiposity diverges from the physiological optimum.

Glucagon

Glucagon, a twenty-nine-amino acid peptide hormone, is secreted by the α-cells of the pancreas in response to hypoglycaemia, and is a primary promoter of hepatic glycogenolysis and gluconeogenesis to increase circulating glucose concentrations⁽Reference She, Hippen and Young^283, Reference Jiang and Zhang²⁸⁴⁾. Glucagon is a counter-regulatory hormone of insulin and the balanced action of these two hormones produces glucose homeostasis under the varying daily feeding events and exercise regimens of animals.

Glucagon is secreted immediately following food consumption and before nutrient absorption⁽Reference de Jong, Strubbe and Steffens²⁸⁵⁾ and reduces meal size in single-stomached animals⁽Reference Geary²⁸⁶⁾. This anorexigenic effect was confirmed by the intraperitoneal administration of pancreatic glucagon antibodies to feed-deprived Sprague–Dawley rats that resulted in increased meal size and duration⁽Reference Langhans, Zieger and Scharrer²⁸⁷⁾.

In rats, glucagon acts at receptor sites in the liver producing an anorexigenic signal transmitted via hepatic vagal afferents to the brain⁽Reference Martin, Novin and Vanderweele^288–Reference Geary, Le Sauter and Noh²⁹⁰⁾ and acts at the ventromedial hypothalamus⁽Reference de Jong, Strubbe and Steffens²⁸⁵⁾, area postrema and the NST⁽Reference Weatherford and Ritter²⁹¹⁾. In ruminant animals, absorbed propionate stimulates glucagon release, mainly via stimulation of adrenergic α-receptors, supporting the hypothesis that propionate is a major regulator of pancreatic endocrine secretion in ruminant animals⁽Reference Sano, Hattori and Todome²⁹²⁾. Amino acid infusions in sheep have also been shown to increase glucagon secretion⁽Reference Kuhara, Ikeda and Ohneda²⁹³⁾.

There has been limited research on the influence of glucagon on VFI in ruminant species; however, the available evidence indicates that its influence on short-term VFI is consistent with that seen in single-stomached animals. Deetz & Wangsness⁽Reference Deetz and Wangsness²⁵⁸⁾ infused glucagon intrajugularly (9 ng/kg live weight) at meal initiation to wethers fed ad libitum and demonstrated a 15·8 % reduction in 24 h VFI compared with controls. She et al. ⁽Reference She, Hippen and Young²⁸³⁾ reported that 14 d intravenous glucagon infusions reduced the normal increases in VFI of dairy cows post-partum. In contrast, a 24 h subcutaneous administration of glucagon (15 mg/d) to lactating dairy cows did not alter VFI, despite elevating blood glucagon levels⁽Reference Williams, Rodriguez and Beitz²⁹⁴⁾. Additionally, Caldeira et al. ⁽Reference Caldeira, Belo and Santos²⁹⁵⁾ concluded that circulating glucagon was not a strong indicator of energy status in mature ewes. These results indicate that although glucagon may act as a short-term anorexigenic factor, it is unlikely to be a major regulator of longer-term VFI in ruminant animals.

Amylin

Amylin, also called islet amyloid polypeptide, is a thirty-seven-amino acid polypeptide co-secreted with insulin from the β-cells of the pancreas following nutrient ingestion⁽Reference Little, Horowitz and Feinle-Bisset¹⁷⁵⁾. Amylin inhibits glucagon secretion⁽Reference Gedulin, Rink and Young^296, Reference Gedulin, Jodka and Herrmann²⁹⁷⁾ and gastric emptying in rats⁽Reference Gedulin, Jodka and Herrmann^297, Reference Young²⁹⁸⁾, indicative of a role in VFI regulation as a complementary hormone to insulin.

In rodents, both peripheral⁽Reference Morley, Flood and Horowitz^299–Reference Roth, Hughes and Kendall³⁰¹⁾ and central⁽Reference Morris and Nguyen^302–Reference Olsson, Herrington and Reidelberger³⁰³⁾ amylin action is to reduce acute VFI, through reduced meal size⁽Reference Lutz, Geary and Szabady³⁰⁴⁾. In obese rodents, this effect is accompanied by a reduction in fat mass and preservation of lean tissues, a halving of circulating insulin, and no change in energy expenditure⁽Reference Roth, Hughes and Kendall³⁰¹⁾. This meal-related anorexigenic effect is mediated through neurons in the area postrema of the hind-brain⁽Reference Reidiger, Schmid and Lutz^305, Reference Reidiger, Zuend and Becskei³⁰⁶⁾, possibly acting through an inhibition of the lateral hypothalamus pathways and the down-regulation of orexin expression⁽Reference Reidiger, Zuend and Becskei³⁰⁶⁾. Peripheral amylin administration reverses feed-deprivation activation of neurons in the lateral hypothalamus, and increases POMC and NPY mRNA expression in the ARC⁽Reference Roth, Hughes and Kendall³⁰¹⁾.

The actions of amylin on gastric emptying and the reduction in VFI appear to be pharmacologically distinct⁽Reference Young²⁹⁸⁾ and the effects on VFI operate independently of the vagus nerve, unlike the effect on gastric emptying⁽Reference Young^298, Reference Morley, Flood and Horowitz²⁹⁹⁾. Further argument for amylin's role in VFI regulation is that it circulates in proportion to adiposity⁽Reference Cooper^307, Reference Reda, Geliebter and Pi-Sunyer³⁰⁸⁾. There is some evidence that amylin interacts synergistically with insulin⁽Reference Rushing, Lutz and Seeley^300, Reference Osto, Weilinga and Alder³⁰⁹⁾ and leptin⁽Reference Osto, Weilinga and Alder³⁰⁹⁾ to reduce VFI and body weight in rodents. Central amylin may also play a role in longer-term VFI regulation in rodents as 14 d icv infusions of an amylin antagonist increased VFI and blood insulin concentrations, and elevated body fat by 30 %⁽Reference Rushing, Hagan and Seeley³¹⁰⁾. Central administration of ghrelin does not influence the anorexic effect of peripheral amylin⁽Reference Osto, Weilinga and Alder³⁰⁹⁾. Therefore, amylin appears to affect short-term VFI directly, through anorexic stimuli in the hypothalamus, and indirectly, through slowing gastric emptying, while also interacting with adiposity signals to influence longer-term VFI and body-weight regulation.

Research of the role of amylin in VFI regulation in ruminant animals is limited. One study in pygmy goats reported an anorexigenic effect of peripheral amylin (2 μg/kg body weight) infusion associated with reduced meal size⁽Reference del Prete, Schade and Reidiger³¹¹⁾, consistent with its action in single-stomached animals. When rat amylin was infused in lactating goats, milk yield was not affected, but milk protein concentrations were reduced, while circulating concentrations of glucose and NEFA were increased⁽Reference Min, Farr and Lee³¹²⁾. These data indicate a variety of actions of amylin in ruminant animals, but further research is required to clarify these effects.

Pancreatic polypeptide

The pancreatic polypeptide family of thirty-six-amino acid peptide hormones includes PP, PYY and NPY. PP is released biphasically from the pancreatic F-cells in response to nutrient ingestion, gastric distension and vagal tone⁽Reference Wynne, Stanley and Bloom³¹³⁾, and remains elevated in circulation in human subjects for at least 6 h postprandially⁽Reference Adrian, Bloom and Bryant³¹⁴⁾, potentially regulating inter-meal intervals⁽Reference Nogueiras and Tschop¹⁶³⁾. Peripheral infusions of PP in human subjects indicate a dose-dependent reduction in orexigenic signals (immediate), and acute (meal offered 2 h post-infusion) as well as cumulative energy intake over 24 h⁽Reference Nogueiras and Tschop^163, Reference Jesudason, Monteiro and McGowan³¹⁵⁾, but had no effect on plasma insulin, leptin, ghrelin, PYY or glucagon-like peptide-1, suggesting that the peripheral anorectic effect of PP is not mediated by these hormones⁽Reference Nogueiras and Tschop¹⁶³⁾. In mice, peripheral administration of PP or transgenic modification for the over-expression of PP reduced VFI and gastric emptying, decreased the expression of the orexigenic peptides NPY, orexins and ghrelin, and resulted in reduced weight gain and fat mass⁽Reference Ueno, Inui and Iwamoto^316, Reference Asakawa, Inui and Yuzuriha³¹⁷⁾. Furthermore, transgenic mice had greater circulating CCK concentrations, with the induced anorexia moderated by CCK-1 receptor antagonists⁽Reference Kojima, Ueno and Asakawa³¹⁸⁾. In fasting human subjects, peripheral ghrelin infusion produced an immediate and sustained elevation in circulating PP concentrations, and a bi-phasic elevation in circulating somatostatin⁽Reference Arosio, Ronchi and Gebbia³¹⁹⁾.

The area postrema has been implicated as the site activated by peripheral PP during the inhibition of VFI in rodents⁽Reference Dumont, Moyse and Fournier³²⁰⁾, although PP receptors are widely distributed in rodent brain tissues, including the ARC and the paraventricular nucleus of the hypothalamus, the forebrain and the NST⁽Reference Whitcomb, Puccio and Vigna³²¹⁾. Of the six types of receptors in the family, PP binds with greatest affinity to Y4 and Y5 receptors, although there are species differences in distribution of PP receptors amongst tissues and in their binding properties⁽Reference Larhammer³²²⁾.

In direct contrast to its anorexic actions when infused peripherally, central PP infusion increased VFI in mice for up to 4 h and promoted gastric emptying⁽Reference Nakajima, Inui and Teranishi³²³⁾. However, central infusion of PP (18 and 24 μg/h for 30 h) as a Y4 agonist did not affect VFI in ovariectomised ewes⁽Reference Clarke, Backholer and Tilbrook³²⁴⁾. The disparity in effects on VFI may be related to receptor expression or access at peripheral and central locations⁽Reference Cummings and Overduin^171, Reference Wynne, Stanley and Bloom³¹³⁾. Like other pancreatic hormones involved in VFI regulation, research into the effects of PP in ruminant animals is limited. Carter et al. ⁽Reference Carter, Grovum and Greenberg³²⁵⁾ reported a postprandial peak in PP within 5 min of eating in lucerne-fed sheep, with increased PP concentrations 16 min before eating, possibly a result of cephalic-vagal stimulation. Despite the expectation of a more gradual pattern of postprandial nutrient release in forage-fed ruminant animals, PP peaked approximately 1 h after feeding, and returned to pre-prandial concentrations within 3–6 h⁽Reference Choi and Palmquist³²⁶⁾. Postprandial PP concentrations increased linearly with supplemental fat in the diets of lactating dairy cows, coincident with declining VFI⁽Reference Choi and Palmquist³²⁶⁾. Furthermore, circulating PP and CCK levels were significantly correlated, consistent with the data in single-stomached animals.

Somatostatin

Somatostatin is a fourteen-amino acid peptide secreted in the D-cells of the endocrine pancreas, acting locally to inhibit the secretion of insulin⁽Reference Martin and Faulkner³²⁷⁾ and centrally to inhibit somatotropin production. It is also present in the brain and GI tract. In ruminant animals, somatostatin immunoreactive fibres are present in the hypothalamic paraventricular, ventromedial, and ARC, and the median eminence⁽Reference Leshin, Barb and Kiser^328, Reference Willoughby, Oliver and Fletcher³²⁹⁾, and are significantly co-localised with leptin receptors⁽Reference Iqbal, Pompolo and Murakami¹¹⁶⁾. In rats, central somatostatin counteracts the suppression in VFI mediated by leptin, reducing leptin receptor responsiveness⁽Reference Stepanyan, Kocharyan and Behrens³³⁰⁾. Leptin infusion reduced hypothalamic somatostatin release⁽Reference Watanobe and Habu³³¹⁾, and, in human subjects, systemic ghrelin injection produced a biphasic (15 and 120 min) rise in circulating somatostatin and an associated decrease in circulating insulin⁽Reference Arosio, Ronchi and Gebbia³¹⁹⁾. Hence, somatostatin probably plays a role in long-term energy homeostasis.

Circulating plasma somatostatin levels increase in response to feeding⁽Reference Matsunaga, Arakawa and Goka³³²⁾, acting to reduce VFI, with vagotomy and food deprivation removing its intake-suppressive effects⁽Reference Levine and Morley³³³⁾. Cattle immunised against somatostatin consumed more DM, had greater daily weight gain, and used feed more efficiently than control animals⁽Reference Ingvartsen and Sejrsen³³⁴⁾. In comparison, undernutrition in ewes was associated with reduced somatostatin in the paraventricular and ventromedial nuclei of the hypothalamus⁽Reference Henry, Rao and Tilbrook³³⁵⁾.