Circulating glucagon-like peptide-1 (GLP-1) inhibits eating in male rats by acting in the hindbrain and without inducing avoidance.

To address the neural mediation of the eating-inhibitory effect of circulating glucagon-like peptide-1 (GLP-1), we investigated the effects of 1) intra-fourth ventricular infusion of the GLP-1 receptor antagonist exendin-9 or 2) area postrema lesion on the eating-inhibitory effect of intrameal hepatic portal vein (HPV) GLP-1 infusion in adult male rats. To evaluate the physiological relevance of the observed effect we examined 3) the influence of GLP-1 on flavor acceptance in a 2-bottle conditioned flavor avoidance test, and 4) measured active GLP-1 in the HPV and vena cava (VC) in relation to a meal and in the VC after HPV GLP-1 infusion. Intrameal HPV GLP-1 infusion (1 nmol/kg body weight-5 min) specifically reduced ongoing meal size by almost 40% (P < .05). Intra-fourth ventricular exendin-9 (10 µg/rat) itself did not affect eating, but attenuated (P < .05) the satiating effect of HPV GLP-1. Area postrema lesion also blocked (P < .05) the eating-inhibitory effect of HPV GLP-1. Pairing consumption of flavored saccharin solutions with HPV GLP-1 infusion did not alter flavor acceptance, indicating that HPV GLP-1 can inhibit eating without inducing malaise. A regular chow meal transiently increased (P < .05) HPV, but not VC, plasma active GLP-1 levels, whereas HPV GLP-1 infusion caused a transient supraphysiological increase (P < .01) in VC GLP-1 concentration 3 minutes after infusion onset. The results implicate hindbrain GLP-1 receptors and the area postrema in the eating-inhibitory effect of circulating GLP-1, but question the physiological relevance of the eating-inhibitory effect of iv infused GLP-1 under our conditions.

GLP-1 antagonism with exendin (9-39) fails to increase spontaneous meal size in rats.

Intravenous and intraperitoneal (IP) administration of glucagon like peptide-1 (7-36)-amide (GLP-1) inhibits eating, but the physiological relevance of this satiating effect is not yet clear. We addressed this issue by testing the effects of the GLP-1 receptor antagonist exendin 9-39 (Ex (9-39)) on spontaneous eating and on the satiating effect of exogenous GLP-1. Adult, male Sprague-Dawley rats were equipped with chronic IP catheters and received intrameal infusions (0.2 ml/min, 2.5 min) that were remotely triggered 2-3 min after the onset of the first or the second spontaneous nocturnal meal. Infusions of 10, but not 5 or 2.5 nmol/kg body weight (BW) GLP-1 significantly reduced the size of the first spontaneous nocturnal meal compared to vehicle. The first intermeal interval, subsequent meal sizes and cumulative food intake were unchanged by 10 nmol/kg GLP-1. Infusions of 10 or 30 nmol/kg BW Ex (9-39) during the second spontaneous nocturnal meal did not affect the size of that meal and decreased rather than increased meal duration. Co-infusion of 30 nmol/kg BW Ex (9-39) prevented the satiating effect of 10 nmol/kg BW GLP-1 during the first spontaneous nocturnal meal, but again did not increase meal size by itself. That a dose of Ex (9-39) that is sufficient to block the satiating effect of exogenous GLP-1 failed to increase meal size when administered alone under comparable conditions suggests that endogenous intestinal GLP-1 is not required for the control of spontaneous meal size in rats under our conditions. The situations in which GLP-1 is of physiological relevance for satiation require further research.

Intrameal hepatic portal and intraperitoneal infusions of glucagon-like peptide-1 reduce spontaneous meal size in the rat via different mechanisms.

Peripheral administration of glucagon-like peptide (GLP)-1 reduces food intake in animals and humans, but the sites and mechanism of this effect and its physiological significance are not yet clear. To investigate these issues, we prepared rats with chronic catheters and infused GLP-1 (0.2 ml/min; 2.5 or 5.0 min) during the first spontaneous dark-phase meals. Infusions were remotely triggered 2-3 min after meal onset. Hepatic portal vein (HPV) infusion of 1.0 or 3.0 (but not 0.33) nmol/kg GLP-1 reduced the size of the ongoing meal compared with vehicle without affecting the subsequent intermeal interval, the size of subsequent meals, or cumulative food intake. In double-cannulated rats, HPV and vena cava infusions of 1.0 nmol/kg GLP-1 reduced meal size similarly. HPV GLP-1 infusions of 1.0 nmol/kg GLP-1 also reduced meal size similarly in rats with subdiaphragmatic vagal deafferentations and in sham-operated rats. Finally, HPV and ip infusions of 10 nmol/kg GLP-1 reduced meal size similarly in sham-operated rats, but only HPV GLP-1 reduced meal size in subdiaphragmatic vagal deafferentation rats. These data indicate that peripherally infused GLP-1 acutely and specifically reduces the size of ongoing meals in rats and that the satiating effect of ip, but not iv, GLP-1 requires vagal afferent signaling. The findings suggest that iv GLP-1 infusions do not inhibit eating via hepatic portal or hepatic GLP-1 receptors but may act directly on the brain.

Altered hippocampal expression of calbindin-D-28k and calretinin in GABA(B(1))-deficient mice.

Balb/c GABA(B(1))(-/-) mice develop complex epileptiform activity, including spontaneous and audiogenic generalized seizures, 6-8 weeks after birth. The neuronal systems involved in these epilepsies have not been identified yet. Because the hippocampus is critically involved in epileptiform activity, we now investigated whether this brain region exhibits seizure-related alterations. Using semi-quantitative immunohistochemistry, we studied the temporal and cellular hippocampal expression pattern of two seizure-sensitive calcium-binding proteins, calbindin-D-28k and calretinin, in GABA(B(1))(-/-) mice. One month after birth, before the onset of overt epileptiform activity, wild-type (WT) and GABA(B(1))(-/-) mice exhibit comparable expression profiles for the two calcium-binding proteins. Three months after birth, once the epileptic phenotype is established, we observe clear alterations in the expression of calcium-binding proteins in the dentate gyrus area. GABA(B(1))(-/-) mice exhibit a 50% decline in the staining intensity of calbindin-D-28k expressing neurons and a 70% increase in the number of calretinin-positive neurons when compared to WT littermates. Six months after birth, the down-regulation of calbindin-D-28k protein is even more pronounced, while the calretinin expression in GABA(B(1))(-/-) mice reverts to the pattern seen in WT littermates. Our data demonstrate that the absence of functional GABA(B) receptors causes epileptiform activity through a mechanism that crucially involves dentate gyrus granule cells, and that this pathological activity is accompanied by adaptive changes.