Deletion of GPR40 fatty acid receptor gene in mice blocks mercaptoacetate-induced feeding.

Both increased and decreased fatty acid (FA) availability contribute to control of food intake. For example, it is well documented that intestinal FA reduces feeding by triggering enterondocrine secretion of satietogenic peptides, such as cholecystokinin (CCK) and glucagon-like peptide-1 (GLP-1). In contrast, mechanisms by which decreased FA availability increase feeding are not well understood. Over the past three decades substantial research related to FA availability and increased feeding has involved use of the orexigenic compound mercaptoacetate (MA). Because MA reportedly inhibits FA oxidation, it has been assumed that reduced FA oxidation accounts for the orexigenic action of MA. Recently, however, we demonstrated that MA antagonizes G protein-coupled receptor 40 (GPR40), a membrane receptor for long and medium chain FA. We also demonstrated that, by antagonizing GPR40, MA inhibits GLP-1 secretion and attenuates vagal afferent activation by FA. Because both vagal afferent activation and GLP-1 inhibit food intake, we postulated that inhibition of GPR40 by MA might underlie the orexigenic action of MA. We tested this hypothesis using male and female GPR40 knockout (KO) and wild-type (WT) mice. Using several testing protocols, we found that MA increased feeding in WT, but not GPR40 KO mice, and that GPR40 KO mice gained more weight than WT on a high-fat diet. Metabolic monitoring after MA or saline injection in the absence of food did not reveal significant differences in respiratory quotient or energy expenditure between treatment groups or genotypes. These results support the hypothesis that MA stimulates food intake by blocking FA effects on GPR40.

Leptin-sensitive neurons in the arcuate nucleus integrate activity and temperature circadian rhythms and anticipatory responses to food restriction.

Previously, we investigated the role of neuropeptide Y and leptin-sensitive networks in the mediobasal hypothalamus in sleep and feeding and found profound homeostatic and circadian deficits with an intact suprachiasmatic nucleus. We propose that the arcuate nuclei (Arc) are required for the integration of homeostatic circadian systems, including temperature and activity. We tested this hypothesis using saporin toxin conjugated to leptin (Lep-SAP) injected into Arc in rats. Lep-SAP rats became obese and hyperphagic and progressed through a dynamic phase to a static phase of growth. Circadian rhythms were examined over 49 days during the static phase. Rats were maintained on a 12:12-h light-dark (LD) schedule for 13 days and, thereafter, maintained in continuous dark (DD). After the first 13 days of DD, food was restricted to 4 h/day for 10 days. We found that the activity of Lep-SAP rats was arrhythmic in DD, but that food anticipatory activity was, nevertheless, entrainable to the restricted feeding schedule, and the entrained rhythm persisted during the subsequent 3-day fast in DD. Thus, for activity, the circuitry for the light-entrainable oscillator, but not for the food-entrainable oscillator, was disabled by the Arc lesion. In contrast, temperature remained rhythmic in DD in the Lep-SAP rats and did not entrain to restricted feeding. We conclude that the leptin-sensitive network that includes the Arc is required for entrainment of activity by photic cues and entrainment of temperature by food, but is not required for entrainment of activity by food or temperature by photic cues.

Leptin-sensitive neurons in the arcuate nuclei contribute to endogenous feeding rhythms.

Neural sites that interact with the suprachiasmatic nuclei (SCN) to generate rhythms of unrestricted feeding remain unknown. We used the targeted toxin, leptin conjugated to saporin (Lep-SAP), to examine the importance of leptin receptor-B (LepR-B)-expressing neurons in the arcuate nucleus (Arc) for generation of circadian feeding rhythms. Rats given Arc Lep-SAP injections were initially hyperphagic and rapidly became obese (the "dynamic phase" of weight gain). During this phase, Lep-SAP rats were arrhythmic under 12:12-h light-dark (LD) conditions, consuming 59% of their total daily intake during the daytime, compared with 36% in blank-SAP (B-SAP) controls. Lep-SAP rats were also arrhythmic in continuous dark (DD), while significant circadian feeding rhythms were detected in all B-SAP controls. Approximately 8 wk after injection, Lep-SAP rats remained obese but transitioned into a "static phase" of weight gain marked by attenuation of their hyperphagia and rate of weight gain. In this phase, Arc Lep-SAP rats exhibited circadian feeding rhythms under LD conditions, but were arrhythmic in continuous light (LL) and DD. Lep-SAP injections into the ventromedial hypothalamic nucleus did not cause hyperphagia, obesity, or arrhythmic feeding in either LD or DD. Electrolytic lesion of the SCN produced feeding arrhythmia in DD but not hyperphagia or obesity. Results suggest that both Arc Lep-SAP neurons and SCN are required for generation of feeding rhythms entrained to photic cues, while also revealing an essential role for the Arc in maintaining circadian rhythms of ad libitum feeding independent of light entrainment.

Hindbrain catecholamine neurons control rapid switching of metabolic substrate use during glucoprivation in male rats.

Using the retrogradely transported immunotoxin, antidopamine ß-hydroxylase-saporin (DSAP), we showed previously that hindbrain catecholamine neurons innervating corticotropin-releasing hormone neurons in the paraventricular nucleus of the hypothalamus are required for glucoprivation-induced corticosterone secretion. Here, we examine the metabolic consequences of the DSAP lesion in male rats using indirect calorimetry. Rats injected into the paraventricular nucleus of the hypothalamus with DSAP or saporin (SAP) control did not differ in energy expenditure or locomotor activity under any test condition. However, DSAP rats had a persistently higher respiratory exchange ratio (RER) than SAPs under basal conditions. Systemic 2-deoxy-D-glucose did not alter RER in DSAP rats but rapidly decreased RER in SAP controls, indicating that this DSAP lesion impairs the ability to switch rapidly from carbohydrate to fat metabolism in response to glucoprivic challenge. In SAP controls, 2-deoxy-D-glucose-induced decrease in RER was abolished by adrenalectomy but not adrenal denervation. Furthermore, dexamethasone, a synthetic glucocorticoid, decreased RER in both SAP and DSAP rats. Thus, rapid switching of metabolic substrate use during glucoprivation appears to be due to impairment of the catecholamine-mediated increase in corticosterone secretion. Sustained elevation of basal RER in DSAP rats indicates that catecholamine neurons also influence metabolic functions that conserve glucose under basal conditions.

NPAS2 deletion impairs responses to restricted feeding but not to metabolic challenges.

Neuronal PAS domain protein 2 (Npas2) is a clock gene expressed widely in brain and peripheral tissues. NPAS2 is responsive to cellular metabolic state and mutation of this gene impairs adaptation to restricted feeding schedules, suggesting that NPAS2 is required for effective control of a food-entrainable oscillator. However, an alternative possibility, that NPAS2 is required for detection of metabolic cues signaling energy deficiency or for arousal of appropriate behavioral responses to such cues, as not been directly examined. Therefore, we examined the effect of targeted disruption of Npas2 on responses to several acute and chronic metabolic challenges. We found that under normal light-dark and ad libitum feeding conditions, Npas2 knockout (KO) mice did not differ from wild-type (WT) controls with respect to diurnal feeding or blood glucose levels, body weight or size or body composition. Furthermore, feeding responses to overnight food deprivation, insulin- or 2-deoxy-d-glucose (2DG)-induced glucoprivation, mercaptoacetate (MA)-induced blockade of fatty acid oxidation and cold exposure did not differ by genotype. However, KO mice lost more weight than WT during overnight food deprivation and when placed on a 4-h restricted feeding schedule, even though food intake did not differ between groups. Thus, it appears that NPAS2 is not required for detection of or behavioral responses to a variety of acute or chronic metabolic deficits, but is more likely to be involved in effective synchronization of feeding behavior with scheduled food availability.

The lipoprivic control of feeding is governed by fat metabolism, not by leptin or adipose depletion.

A lipoprivic control of feeding has been proposed based on the finding that appetite is stimulated by drugs such as beta-mercaptoacetate (MA) that reduce fatty acid oxidation. The adipose-derived hormone, leptin, has effects on feeding and fat oxidation that are opposite those produced by MA. However, effects of this hormone on MA-induced feeding are not known. Here we examined the effects of endogenous leptin levels and of acute central and peripheral leptin administration on MA-induced feeding. We also examined leptin-induced changes in feeding, body weight, and plasma fuels after capsaicin-induced deletion of the lipoprivic control. MA-induced feeding was not altered under any of these conditions, and leptin's effects were not altered by capsaicin. We then examined MA-induced feeding during chronic leptin treatment. Because chronic leptin produces several distinct metabolic states as body adiposity is reduced, we tested MA before, during, and after leptin treatment at times that coincided with these states. MA-induced feeding was unchanged on d 3 of leptin treatment when rats were in a lipolytic state and rapidly metabolizing body fat stores but reduced on d 10 when they were adipose deplete and their level of fat oxidation was reduced. Together results suggest that the lipoprivic control is normally less active in the fat deplete state than during states associated with fat availability. If so, its insensitivity to leptin would enable the lipoprivic control to operate when dietary fat, adiposity, and leptin levels are elevated. The role played by the lipoprivic control under such conditions remains uncertain.

Protein appetite is increased after central leptin-induced fat depletion.

Leptin reduces body fat selectively, sparing body protein. Accordingly, during chronic leptin administration, food intake is suppressed, and body weight is reduced until body fat is depleted. Body weight then stabilizes at this fat-depleted nadir, while food intake returns to normal caloric levels, presumably in defense of energy and nutritional homeostasis. This model of leptin treatment offers the opportunity to examine controls of food intake that are independent of leptin's actions, and provides a window for examining the nature of feeding controls in a "fatless" animal. Here we evaluate macronutrient selection during this fat-depleted phase of leptin treatment. Adult, male Sprague-Dawley rats were maintained on standard pelleted rodent chow and given daily lateral ventricular injections of leptin or vehicle solution until body weight reached the nadir point and food intake returned to normal levels. Injections were then continued for 8 days, during which rats self-selected their daily diet from separate sources of carbohydrate, protein, and fat. Macronutrient choice differed profoundly in leptin and control rats. Leptin rats exhibited a dramatic increase in protein intake, whereas controls exhibited a strong carbohydrate preference. Fat intake did not differ between groups at any time during the 8-day test. Despite these dramatic differences in macronutrient selection, total daily caloric intake did not differ between groups except on day 2. Thus controls of food intake related to ongoing metabolic and nutritional requirements may supersede the negative feedback signals related to body fat stores.